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- 0:17 Nubank's Strategic Acquisition of Daytomic: In 2020, Nubank acquired Cognitech and Daytomic, finding a deep alignment between Nubank's mission to simplify banking for Brazilians and Daytomic's philosophy of simplicity and software. This partnership has since led to significant growth in the Daytomic team.
- 1:06 Personal Experience of Nubank's Impact: The speaker recounts a challenging public transport experience in São Paulo where only Nubank's purple cards consistently worked at kiosks, illustrating the bank's profound and widespread impact on real people.
- 2:12 Unprecedented Growth and Efficiency: As of April 2025, Nubank serves 114.3 million users, an increase of over 20 million from 2023, sustaining an 83% activity rate. It boasts the lowest cost to serve globally among independent banks, adding nearly 13 million customers annually since 2015, with 80% of growth from word-of-mouth referrals.
- 3:24 Addressing Financial Exclusion: Nubank emerged in a Brazilian market characterized by high retail lending interest rates (often over 100% annually) and significant financial exclusion (45 million unbanked in 2017). For millions, Nubank provided their first credit card, savings account, or loan.
- 4:13 Massive Technical Scale: Nubank handles petabytes of data, operates over 3,000 Datomic databases (some with over 100 billion "datoms"), runs 4,000 microservices on Kubernetes, processes 72 billion daily Kafka events, and routinely manages millions of requests per second, all while adhering to strict banking compliance.
- 5:07 Nubank as a Tech Company: Recognized as more of a tech company than a bank, Nubank employs over 8,700 people, including 3,000+ engineers, across six countries.
- 6:27 Defining Scaling vs. Growth: The presentation differentiates between "growth" (increasing revenue by proportionally increasing resources) and "scaling" (increasing output while proportionally reducing resources), aligning with Nubank's value of "pursuing smart efficiency." Nubank's efficiency ratio is 29.9%, half the industry average.
- 8:00 Three Types of Scalability: Nubank focuses on:
- Architectural Scalability: Systems grow without redesign, staying performant under load.
- Performance Scalability: Increasing throughput without increasing latency or cost.
- People Process Scalability: Human problems don't hinder system development or deployment.
- 9:09 Datomic's Peer Model for Architectural Scalability: Unlike traditional databases that cluster/shard, Datomic employs a "peer model" where read operations are distributed among capable peer nodes. This allows for arbitrary horizontal scaling of reads and aggressive caching while maintaining consistency, reducing the load on a central monolithic server.
- 11:17 Performance Scalability with New Datomic Features:
- Transaction Stats and IO Stats: Built-in observability tools to measure and tune real-world performance.
- 15:36 Transactor Hints (First Implemented Oct 2024): This feature allows peers to speculatively determine and send necessary read requests to the transactor while transactions are queued, significantly reducing I/O on main threads and shortening latency (like curbside pickup for groceries).
- 17:15 Implicit Partitions (Released April 2023): Improves data locality by allowing applications to group entities, meaning queries can efficiently retrieve relevant data by reading fewer segments, leading to faster database performance (like a well-organized salad bar).
- 20:25 Conclusion: The Power of "Scaling Simplicity": Nubank's success, running on Closure and Datomic, is attributed to the alignment of its values (simplicity, smart efficiency, fanatical customer focus) with the underlying technology. This synergy enables thousands of engineers to ship safely, empowering millions with financial tools they previously lacked, with 74% of users reporting improved financial health.
- 23:40 Daytomic's Broader Impact and Resources: Daytomic operates as a product outside Nubank, serving other major clients like Netflix and HSBC. Resources for learning Datomic, including a YouTube playlist, free access, support, and monthly meetups, are highlighted.
- 0:05 British Reluctance, Series Focus: The video introduces the British cultural reluctance to discuss sex openly, setting the stage for a series that tackles the subject head-on, specifically focusing on "sex after porn obsession" in this episode.
- 0:25 Unrealistic Expectations from Pornography: Contributors discuss how pornography set "unrealistic expectations" for them regarding what sex should be, leading to disappointment in real-life experiences.
- 0:43 Porn as Self-Medication: One individual reveals using pornography to "medicate a lot of the emotions" related to childhood, social, educational, and familial pressures.
- 0:54 Inability to Stop: The feeling of being unable to stop watching porn, despite wanting to, signals a problematic dependency.
- 1:17 Increased Accessibility & Prevalence: Pornography, while ancient, is now more accessible than ever due to technology, with UK addiction treatment centers suggesting 8.8 million adults watch porn weekly.
- 1:40 Common Thread: Early Exposure: All interviewed participants started watching porn at a young age, influenced by factors like religious abstinence-only education, conservative cultural upbringings that avoided sex discussions, or coping with personal loss and puberty.
- 4:30 Research on Early Exposure: On average, children first see pornography at age 13, with 1 in 10 having seen it by age 9.
- 5:14 Progression to Dependency: What often starts as casual "exploration" can quickly escalate to a daily habit, leading to feelings of "dependency" rather than enjoyment.
- 6:36 Distorted Views of Sex and Relationships: Porn distorts views of sex, women, and real-life relationships, leading to complacency, the belief that "sex would solve most issues," and a lack of focus on deeper connection.
- 7:12 Disappointing First Experiences: Many shared experiences of disappointing first sexual encounters, as they didn't live up to the fantasies created by porn.
- 7:39 Porn's Impact on Behavior: Surveys suggest viewing online pornography can affect behavior, with potential correlations to aggression and coercion, and concerns about sexual violence depicted.
- 8:08 Unrealistic Portrayal of Sex: Participants initially believed porn was real, later realizing it's a performed, perfectly lit, and unrealistic depiction of sex that doesn't prioritize female orgasm.
- 9:19 Difficulty Being Present and Guilt: Long-term porn viewing can make it difficult to be present during real-life intimacy, leading to guilt, shame, and exhaustion.
- 9:50 Chasing a Constant High: The pursuit of a "constant high" from porn becomes uncontrollable, highlighting a deep-seated issue.
- 11:15 Porn Addiction Not a Formal Diagnosis: While not an official diagnosis, problematic porn use is treated by some practitioners as a compulsive sexual behavior disorder.
- 11:30 "Opposite of Addiction is Connection": Openly sharing struggles with porn with friends and trusted individuals can alleviate shame and secrecy, aiding in recovery.
- 12:41 The "Try to Stop" Test: A key indicator of unhealthy dependency is the inability to stop watching porn when one tries.
- 13:10 Redefining Sex and Intimacy: Some individuals chose abstinence journeys to reframe their understanding of sex, realizing sexual desire isn't always a "need" but sometimes a craving for other forms of connection or dopamine.
- 13:49 Rise of Celibacy: Voluntary celibacy is gaining traction, indicating a shift towards redefining sex and relationships on one's own terms, prioritizing safety, love, and intimacy over performance.
- 15:58 Impact on Relationships: Commitment and Cheating: Past porn use led to fear of commitment, treating partners as disposable objects, and prolific cheating without remorse for some.
- 16:36 Replaying Unhealthy Dynamics: Porn influenced choices in relationships, leading to patterns of engaging with "not very nice" partners and prioritizing performance over mutual enjoyment.
- 17:45 Possibility of a Healthy Relationship with Porn: Some studies suggest "romantic pornography" can improve sexual satisfaction. Re-engaging with porn differently, e.g., through sex toy reviews or audio porn, can aid in self-discovery without visual distortion.
- 18:45 Life and Sex After Obsession: Giving up problematic porn use improved connections, with participants agreeing that the negatives far outweigh the positives.
- 19:15 Importance of Open Conversations: Openly discussing porn can reduce guilt and shame, leading to support for those who want to stop and a better understanding for everyone.
- 19:48 Advice for Struggling Individuals: Find something "bigger than yourself" (partner, kids, changing life) to motivate stopping.
- 20:01 Support Resources: For those affected, help and support details are available at bbc.co.uk/actionline.
- 0:11:54 - Major Observatory Announcement: The live stream centers around an anticipated "huge announcement" from the National Science Foundation (NSF) and the Vera C. Rubin Observatory regarding its first images.
- 0:13:31 - Transformative Mission: The host emphasizes the observatory's upcoming decade-long mission as potentially one of the most important in recent years, capable of producing high-quality images and vast amounts of data.
- 0:15:13 - 20-Year Development & Scale: The Vera C. Rubin Observatory project took approximately 20 years to finalize and is described as having one of the world's largest telescopes and the most sensitive camera.
- 0:16:31 - Honoring Vera Rubin: The observatory is named after Vera Rubin, a pioneering astrophysicist who, by observing galactic rotation curves, provided crucial evidence for the existence of dark matter.
- 0:18:01 - Prime Location: Located on El Peñón Peak (2700m/9000ft) in Chile's Atacama desert, the observatory benefits from some of the best, clearest, and driest night skies globally.
- 0:22:17 - Wide Field of View: Unlike most telescopes, Rubin is uniquely designed to combine a wide field of view with high sensitivity, enabling it to scan vast areas of the sky rapidly without laser auto-correction.
- 0:24:05 - Core Scientific Pillars: The observatory's main scientific missions include:
- Studying dark matter through weak gravitational lensing.
- Investigating dark energy and the universe's expansion.
- Detecting transient events like novae and supernovae.
- Discovering and tracking millions of near-Earth asteroids and comets, critical for planetary defense.
- Mapping the distribution of stars and dark matter within the Milky Way, complementing missions like Gaia.
- 0:40:58 - Immense Data Generation: The telescope captures an image every 30 seconds, generating 10-20 terabytes of data each night. A single Rubin image is so massive it would require 400 4K HDTVs to display its full detail.
- 0:54:18 - LSST Camera - World Record Holder: The Department of Energy (DOE) led the construction of the LSST Cam, the largest digital camera ever built for astronomy, boasting 3200 megapixels and a Guinness World Record.
- 1:10:04 - First Images & Detail: The initial images, such as a partial view of the Virgo cluster, demonstrate unprecedented detail, revealing countless faint objects never before seen by humans.
- 1:21:01 - "Greatest Movie of All Time": Over its 10-year survey (Legacy Survey of Space and Time - LSST), Rubin will image each of its estimated 40 billion celestial objects approximately 800 times, creating a dynamic, digital color movie of the night sky.
- 1:24:52 - Asteroid Detection Prowess: Early tests from just a few nights of data yielded 2,000 new asteroid discoveries, including 7 near-Earth objects. The project projects finding 5 million new asteroids in the coming years, surpassing all previous discoveries in the last two centuries combined.
- 1:27:07 - Variable Star Mapping: Rubin's ability to precisely detect changes in brightness of variable stars (e.g., RLI stars, Cepheid variables) is crucial for accurately measuring cosmic distances and mapping dark matter distribution.
- 1:47:30 - Open Data & Citizen Science: The immense data will be accessible to researchers via a cloud-based Rubin Science Platform, and to the public through citizen science projects, fostering global participation in astronomical discovery.
- 2:02:51 - Anticipated Surprises: Beyond predicted discoveries like millions of asteroids and precise cosmological measurements, scientists anticipate finding "unknown unknowns," including potentially 10-20 new interstellar objects per year and even Planet 9 (if it exists in the southern sky).
- 2:10:41 - Oumuamua and Interstellar Objects: The discussion touched on the interstellar object Oumuamua, with the humorous remark that if it were to return, it would suggest an artificial origin. Rubin's observations are expected to provide a much larger sample of such objects for statistical study.
- 2:46:41 - Visual Superiority: A visual comparison of the Triffid Nebula strikingly illustrates the new Rubin image's incomparably higher quality and detail compared to previous observations.
- 2:51:32 - The Search for Extraterrestrial Life: While not a primary mission, the host, from a microbiology background, expresses skepticism about widespread alien life due to the biochemical complexity required, though acknowledges if found, it would most likely be on Mars or Jupiter/Saturn's icy moons.
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https://www.youtube.com/watch?v=9kiuwsfCDFIinclude_comments: None
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*Abstract:* This presentation explores how Nubank, the world's largest independent digital bank, achieves unprecedented scale and efficiency by leveraging Datomic and Closure. Beginning with the 2020 acquisition of Cognitech and Daytomic, the speaker highlights the foundational alignment between Nubank's mission to simplify banking and Daytomic's philosophy of simplicity. The talk details Nubank's rapid growth, serving over 114 million users with an exceptionally low cost-to-serve, largely driven by word-of-mouth referrals due to its impact on financial inclusion in Brazil. Technically, Nubank manages petabytes of data across thousands of Datomic databases and microservices, processing billions of daily events. The core of "scaling simplicity" is broken down into architectural, performance, and people-process scalability. Architectural scalability is exemplified by Datomic's peer model, which distributes read loads horizontally. Performance enhancements are demonstrated through new Datomic features like "transactor hints" and "implicit partitions," which reduce I/O and improve data locality. The presentation concludes by reinforcing the synergy between Nubank's values and Daytomic's design, enabling safe development by thousands of engineers and empowering millions financially. *Scaling Simplicity: How Nubank Achieves Massive Scale with Datomic and Closure* * *0:17 Nubank's Strategic Acquisition of Daytomic:* In 2020, Nubank acquired Cognitech and Daytomic, finding a deep alignment between Nubank's mission to simplify banking for Brazilians and Daytomic's philosophy of simplicity and software. This partnership has since led to significant growth in the Daytomic team. * *1:06 Personal Experience of Nubank's Impact:* The speaker recounts a challenging public transport experience in São Paulo where only Nubank's purple cards consistently worked at kiosks, illustrating the bank's profound and widespread impact on real people. * *2:12 Unprecedented Growth and Efficiency:* As of April 2025, Nubank serves 114.3 million users, an increase of over 20 million from 2023, sustaining an 83% activity rate. It boasts the lowest cost to serve globally among independent banks, adding nearly 13 million customers annually since 2015, with 80% of growth from word-of-mouth referrals. * *3:24 Addressing Financial Exclusion:* Nubank emerged in a Brazilian market characterized by high retail lending interest rates (often over 100% annually) and significant financial exclusion (45 million unbanked in 2017). For millions, Nubank provided their first credit card, savings account, or loan. * *4:13 Massive Technical Scale:* Nubank handles petabytes of data, operates over 3,000 Datomic databases (some with over 100 billion "datoms"), runs 4,000 microservices on Kubernetes, processes 72 billion daily Kafka events, and routinely manages millions of requests per second, all while adhering to strict banking compliance. * *5:07 Nubank as a Tech Company:* Recognized as more of a tech company than a bank, Nubank employs over 8,700 people, including 3,000+ engineers, across six countries. * *6:27 Defining Scaling vs. Growth:* The presentation differentiates between "growth" (increasing revenue by proportionally increasing resources) and "scaling" (increasing output while proportionally *reducing* resources), aligning with Nubank's value of "pursuing smart efficiency." Nubank's efficiency ratio is 29.9%, half the industry average. * *8:00 Three Types of Scalability:* Nubank focuses on: * *Architectural Scalability:* Systems grow without redesign, staying performant under load. * *Performance Scalability:* Increasing throughput without increasing latency or cost. * *People Process Scalability:* Human problems don't hinder system development or deployment. * *9:09 Datomic's Peer Model for Architectural Scalability:* Unlike traditional databases that cluster/shard, Datomic employs a "peer model" where read operations are distributed among capable peer nodes. This allows for arbitrary horizontal scaling of reads and aggressive caching while maintaining consistency, reducing the load on a central monolithic server. * *11:17 Performance Scalability with New Datomic Features:* * *Transaction Stats and IO Stats:* Built-in observability tools to measure and tune real-world performance. * *15:36 Transactor Hints (First Implemented Oct 2024):* This feature allows peers to speculatively determine and send necessary read requests to the transactor while transactions are queued, significantly reducing I/O on main threads and shortening latency (like curbside pickup for groceries). * *17:15 Implicit Partitions (Released April 2023):* Improves data locality by allowing applications to group entities, meaning queries can efficiently retrieve relevant data by reading fewer segments, leading to faster database performance (like a well-organized salad bar). * *20:25 Conclusion: The Power of "Scaling Simplicity":* Nubank's success, running on Closure and Datomic, is attributed to the alignment of its values (simplicity, smart efficiency, fanatical customer focus) with the underlying technology. This synergy enables thousands of engineers to ship safely, empowering millions with financial tools they previously lacked, with 74% of users reporting improved financial health. * *23:40 Daytomic's Broader Impact and Resources:* Daytomic operates as a product outside Nubank, serving other major clients like Netflix and HSBC. Resources for learning Datomic, including a YouTube playlist, free access, support, and monthly meetups, are highlighted. I used gemini-2.5-flash-preview-05-20| input-price: 0.15 output-price: 3.5 max-context-length: 128_000 on rocketrecap dot com to summarize the transcript. Cost (if I didn't use the free tier): $0.0075 Input tokens: 20834 Output tokens: 1249
Abstract:
This presentation explores how Nubank, the world's largest independent digital bank, achieves unprecedented scale and efficiency by leveraging Datomic and Closure. Beginning with the 2020 acquisition of Cognitech and Daytomic, the speaker highlights the foundational alignment between Nubank's mission to simplify banking and Daytomic's philosophy of simplicity. The talk details Nubank's rapid growth, serving over 114 million users with an exceptionally low cost-to-serve, largely driven by word-of-mouth referrals due to its impact on financial inclusion in Brazil. Technically, Nubank manages petabytes of data across thousands of Datomic databases and microservices, processing billions of daily events. The core of "scaling simplicity" is broken down into architectural, performance, and people-process scalability. Architectural scalability is exemplified by Datomic's peer model, which distributes read loads horizontally. Performance enhancements are demonstrated through new Datomic features like "transactor hints" and "implicit partitions," which reduce I/O and improve data locality. The presentation concludes by reinforcing the synergy between Nubank's values and Daytomic's design, enabling safe development by thousands of engineers and empowering millions financially.
Scaling Simplicity: How Nubank Achieves Massive Scale with Datomic and Closure
Below, I will provide input for an example video (comprising of title, description, and transcript, in this order) and the corresponding abstract and summary I expect. Afterward, I will provide a new transcript that I want you to summarize in the same format. **Please give an abstract of the transcript and then summarize the transcript in a self-contained bullet list format.** Include starting timestamps, important details and key takeaways. Example Input: Fluidigm Polaris Part 2- illuminator and camera mikeselectricstuff 131K subscribers Subscribed 369 Share Download Clip Save 5,857 views Aug 26, 2024 Fluidigm Polaris part 1 : • Fluidigm Polaris (Part 1) - Biotech g... Ebay listings: https://www.ebay.co.uk/usr/mikeselect... Merch https://mikeselectricstuff.creator-sp... Transcript Follow along using the transcript. Show transcript mikeselectricstuff 131K subscribers Videos About Support on Patreon 40 Comments @robertwatsonbath 6 hours ago Thanks Mike. Ooof! - with the level of bodgery going on around 15:48 I think shame would have made me do a board re spin, out of my own pocket if I had to. 1 Reply @Muonium1 9 hours ago The green LED looks different from the others and uses phosphor conversion because of the "green gap" problem where green InGaN emitters suffer efficiency droop at high currents. Phosphide based emitters don't start becoming efficient until around 600nm so also can't be used for high power green emitters. See the paper and plot by Matthias Auf der Maur in his 2015 paper on alloy fluctuations in InGaN as the cause of reduced external quantum efficiency at longer (green) wavelengths. 4 Reply 1 reply @tafsirnahian669 10 hours ago (edited) Can this be used as an astrophotography camera? Reply mikeselectricstuff · 1 reply @mikeselectricstuff 6 hours ago Yes, but may need a shutter to avoid light during readout Reply @2010craggy 11 hours ago Narrowband filters we use in Astronomy (Astrophotography) are sided- they work best passing light in one direction so I guess the arrows on the filter frames indicate which way round to install them in the filter wheel. 1 Reply @vitukz 12 hours ago A mate with Channel @extractions&ire could use it 2 Reply @RobertGallop 19 hours ago That LED module says it can go up to 28 amps!!! 21 amps for 100%. You should see what it does at 20 amps! Reply @Prophes0r 19 hours ago I had an "Oh SHIT!" moment when I realized that the weird trapezoidal shape of that light guide was for keystone correction of the light source. Very clever. 6 Reply @OneBiOzZ 20 hours ago given the cost of the CCD you think they could have run another PCB for it 9 Reply @tekvax01 21 hours ago $20 thousand dollars per minute of run time! 1 Reply @tekvax01 22 hours ago "We spared no expense!" John Hammond Jurassic Park. *(that's why this thing costs the same as a 50-seat Greyhound Bus coach!) Reply @florianf4257 22 hours ago The smearing on the image could be due to the fact that you don't use a shutter, so you see brighter stripes under bright areas of the image as you still iluminate these pixels while the sensor data ist shifted out towards the top. I experienced this effect back at university with a LN-Cooled CCD for Spectroscopy. The stripes disapeared as soon as you used the shutter instead of disabling it in the open position (but fokussing at 100ms integration time and continuous readout with a focal plane shutter isn't much fun). 12 Reply mikeselectricstuff · 1 reply @mikeselectricstuff 12 hours ago I didn't think of that, but makes sense 2 Reply @douro20 22 hours ago (edited) The red LED reminds me of one from Roithner Lasertechnik. I have a Symbol 2D scanner which uses two very bright LEDs from that company, one red and one red-orange. The red-orange is behind a lens which focuses it into an extremely narrow beam. 1 Reply @RicoElectrico 23 hours ago PFG is Pulse Flush Gate according to the datasheet. Reply @dcallan812 23 hours ago Very interesting. 2x Reply @littleboot_ 1 day ago Cool interesting device Reply @dav1dbone 1 day ago I've stripped large projectors, looks similar, wonder if some of those castings are a magnesium alloy? Reply @kevywevvy8833 1 day ago ironic that some of those Phlatlight modules are used in some of the cheapest disco lights. 1 Reply 1 reply @bill6255 1 day ago Great vid - gets right into subject in title, its packed with information, wraps up quickly. Should get a YT award! imho 3 Reply @JAKOB1977 1 day ago (edited) The whole sensor module incl. a 5 grand 50mpix sensor for 49 £.. highest bid atm Though also a limited CCD sensor, but for the right buyer its a steal at these relative low sums. Architecture Full Frame CCD (Square Pixels) Total Number of Pixels 8304 (H) × 6220 (V) = 51.6 Mp Number of Effective Pixels 8208 (H) × 6164 (V) = 50.5 Mp Number of Active Pixels 8176 (H) × 6132 (V) = 50.1 Mp Pixel Size 6.0 m (H) × 6.0 m (V) Active Image Size 49.1 mm (H) × 36.8 mm (V) 61.3 mm (Diagonal), 645 1.1x Optical Format Aspect Ratio 4:3 Horizontal Outputs 4 Saturation Signal 40.3 ke− Output Sensitivity 31 V/e− Quantum Efficiency KAF−50100−CAA KAF−50100−AAA KAF−50100−ABA (with Lens) 22%, 22%, 16% (Peak R, G, B) 25% 62% Read Noise (f = 18 MHz) 12.5 e− Dark Signal (T = 60°C) 42 pA/cm2 Dark Current Doubling Temperature 5.7°C Dynamic Range (f = 18 MHz) 70.2 dB Estimated Linear Dynamic Range (f = 18 MHz) 69.3 dB Charge Transfer Efficiency Horizontal Vertical 0.999995 0.999999 Blooming Protection (4 ms Exposure Time) 800X Saturation Exposure Maximum Date Rate 18 MHz Package Ceramic PGA Cover Glass MAR Coated, 2 Sides or Clear Glass Features • TRUESENSE Transparent Gate Electrode for High Sensitivity • Ultra-High Resolution • Board Dynamic Range • Low Noise Architecture • Large Active Imaging Area Applications • Digitization • Mapping/Aerial • Photography • Scientific Thx for the tear down Mike, always a joy Reply @martinalooksatthings 1 day ago 15:49 that is some great bodging on of caps, they really didn't want to respin that PCB huh 8 Reply @RhythmGamer 1 day ago Was depressed today and then a new mike video dropped and now I’m genuinely happy to get my tear down fix 1 Reply @dine9093 1 day ago (edited) Did you transfrom into Mr Blobby for a moment there? 2 Reply @NickNorton 1 day ago Thanks Mike. Your videos are always interesting. 5 Reply @KeritechElectronics 1 day ago Heavy optics indeed... Spare no expense, cost no object. Splendid build quality. The CCD is a thing of beauty! 1 Reply @YSoreil 1 day ago The pricing on that sensor is about right, I looked in to these many years ago when they were still in production since it's the only large sensor you could actually buy. Really cool to see one in the wild. 2 Reply @snik2pl 1 day ago That leds look like from led projector Reply @vincei4252 1 day ago TDI = Time Domain Integration ? 1 Reply @wolpumba4099 1 day ago (edited) Maybe the camera should not be illuminated during readout. From the datasheet of the sensor (Onsemi): saturation 40300 electrons, read noise 12.5 electrons per pixel @ 18MHz (quite bad). quantum efficiency 62% (if it has micro lenses), frame rate 1 Hz. lateral overflow drain to prevent blooming protects against 800x (factor increases linearly with exposure time) saturation exposure (32e6 electrons per pixel at 4ms exposure time), microlens has +/- 20 degree acceptance angle i guess it would be good for astrophotography 4 Reply @txm100 1 day ago (edited) Babe wake up a new mikeselectricstuff has dropped! 9 Reply @vincei4252 1 day ago That looks like a finger-lakes filter wheel, however, for astronomy they'd never use such a large stepper. 1 Reply @MRooodddvvv 1 day ago yaaaaay ! more overcomplicated optical stuff ! 4 Reply 1 reply @NoPegs 1 day ago He lives! 11 Reply 1 reply Transcript 0:00 so I've stripped all the bits of the 0:01 optical system so basically we've got 0:03 the uh the camera 0:05 itself which is mounted on this uh very 0:09 complex 0:10 adjustment thing which obviously to set 0:13 you the various tilt and uh alignment 0:15 stuff then there's two of these massive 0:18 lenses I've taken one of these apart I 0:20 think there's something like about eight 0:22 or nine Optical elements in here these 0:25 don't seem to do a great deal in terms 0:26 of electr magnification they're obiously 0:28 just about getting the image to where it 0:29 uh where it needs to be just so that 0:33 goes like that then this Optical block I 0:36 originally thought this was made of some 0:37 s crazy heavy material but it's just 0:39 really the sum of all these Optical bits 0:41 are just ridiculously heavy those lenses 0:43 are about 4 kilos each and then there's 0:45 this very heavy very solid um piece that 0:47 goes in the middle and this is so this 0:49 is the filter wheel assembly with a 0:51 hilariously oversized steper 0:53 motor driving this wheel with these very 0:57 large narrow band filters so we've got 1:00 various different shades of uh 1:03 filters there five Al together that 1:06 one's actually just showing up a silver 1:07 that's actually a a red but fairly low 1:10 transmission orangey red blue green 1:15 there's an excess cover on this side so 1:16 the filters can be accessed and changed 1:19 without taking anything else apart even 1:21 this is like ridiculous it's like solid 1:23 aluminium this is just basically a cover 1:25 the actual wavelengths of these are um 1:27 488 525 570 630 and 700 NM not sure what 1:32 the suffix on that perhaps that's the uh 1:34 the width of the spectral line say these 1:37 are very narrow band filters most of 1:39 them are you very little light through 1:41 so it's still very tight narrow band to 1:43 match the um fluoresence of the dies 1:45 they're using in the biochemical process 1:48 and obviously to reject the light that's 1:49 being fired at it from that Illuminator 1:51 box and then there's a there's a second 1:53 one of these lenses then the actual sort 1:55 of samples below that so uh very serious 1:58 amount of very uh chunky heavy Optics 2:01 okay let's take a look at this light 2:02 source made by company Lumen Dynamics 2:04 who are now part of 2:06 excelitas self-contained unit power 2:08 connector USB and this which one of the 2:11 Cable Bundle said was a TTL interface 2:14 USB wasn't used in uh the fluid 2:17 application output here and I think this 2:19 is an input for um light feedback I 2:21 don't if it's regulated or just a measur 2:23 measurement facility and the uh fiber 2:27 assembly 2:29 Square Inlet there and then there's two 2:32 outputs which have uh lens assemblies 2:35 and this small one which goes back into 2:37 that small Port just Loops out of here 2:40 straight back in So on this side we've 2:42 got the electronics which look pretty 2:44 straightforward we've got a bit of power 2:45 supply stuff over here and we've got 2:48 separate drivers for each wavelength now 2:50 interesting this is clearly been very 2:52 specifically made for this application 2:54 you I was half expecting like say some 2:56 generic drivers that could be used for a 2:58 number of different things but actually 3:00 literally specified the exact wavelength 3:02 on the PCB there is provision here for 3:04 385 NM which isn't populated but this is 3:07 clearly been designed very specifically 3:09 so these four drivers look the same but 3:10 then there's two higher power ones for 3:12 575 and 3:14 520 a slightly bigger heat sink on this 3:16 575 section there a p 24 which is 3:20 providing USB interface USB isolator the 3:23 USB interface just presents as a comport 3:26 I did have a quick look but I didn't 3:27 actually get anything sensible um I did 3:29 dump the Pi code out and there's a few 3:31 you a few sort of commands that you 3:32 could see in text but I didn't actually 3:34 manage to get it working properly I 3:36 found some software for related version 3:38 but it didn't seem to want to talk to it 3:39 but um I say that wasn't used for the 3:41 original application it might be quite 3:42 interesting to get try and get the Run 3:44 hours count out of it and the TTL 3:46 interface looks fairly straightforward 3:48 we've got positions for six opto 3:50 isolators but only five five are 3:52 installed so that corresponds with the 3:54 unused thing so I think this hopefully 3:56 should be as simple as just providing a 3:57 ttrl signal for each color to uh enable 4:00 it a big heat sink here which is there I 4:03 think there's like a big S of metal 4:04 plate through the middle of this that 4:05 all the leads are mounted on the other 4:07 side so this is heat sinking it with a 4:09 air flow from a uh just a fan in here 4:13 obviously don't have the air flow 4:14 anywhere near the Optics so conduction 4:17 cool through to this plate that's then 4:18 uh air cooled got some pots which are 4:21 presumably power 4:22 adjustments okay let's take a look at 4:24 the other side which is uh much more 4:27 interesting see we've got some uh very 4:31 uh neatly Twisted cable assemblies there 4:35 a bunch of leads so we've got one here 4:37 475 up here 430 NM 630 575 and 520 4:44 filters and dcro mirrors a quick way to 4:48 see what's white is if we just shine 4:49 some white light through 4:51 here not sure how it is is to see on the 4:54 camera but shining white light we do 4:55 actually get a bit of red a bit of blue 4:57 some yellow here so the obstacle path 5:00 575 it goes sort of here bounces off 5:03 this mirror and goes out the 520 goes 5:07 sort of down here across here and up 5:09 there 630 goes basically straight 5:13 through 5:15 430 goes across there down there along 5:17 there and the 475 goes down here and 5:20 left this is the light sensing thing 5:22 think here there's just a um I think 5:24 there a photo diode or other sensor 5:26 haven't actually taken that off and 5:28 everything's fixed down to this chunk of 5:31 aluminium which acts as the heat 5:32 spreader that then conducts the heat to 5:33 the back side for the heat 5:35 sink and the actual lead packages all 5:38 look fairly similar except for this one 5:41 on the 575 which looks quite a bit more 5:44 substantial big spay 5:46 Terminals and the interface for this 5:48 turned out to be extremely simple it's 5:50 literally a 5V TTL level to enable each 5:54 color doesn't seem to be any tensity 5:56 control but there are some additional 5:58 pins on that connector that weren't used 5:59 in the through time thing so maybe 6:01 there's some extra lines that control 6:02 that I couldn't find any data on this uh 6:05 unit and the um their current product 6:07 range is quite significantly different 6:09 so we've got the uh blue these 6:13 might may well be saturating the camera 6:16 so they might look a bit weird so that's 6:17 the 430 6:18 blue the 575 6:24 yellow uh 6:26 475 light blue 6:29 the uh 520 6:31 green and the uh 630 red now one 6:36 interesting thing I noticed for the 6:39 575 it's actually it's actually using a 6:42 white lead and then filtering it rather 6:44 than using all the other ones are using 6:46 leads which are the fundamental colors 6:47 but uh this is actually doing white and 6:50 it's a combination of this filter and 6:52 the dichroic mirrors that are turning to 6:55 Yellow if we take the filter out and a 6:57 lot of the a lot of the um blue content 7:00 is going this way the red is going 7:02 straight through these two mirrors so 7:05 this is clearly not reflecting much of 7:08 that so we end up with the yellow coming 7:10 out of uh out of there which is a fairly 7:14 light yellow color which you don't 7:16 really see from high intensity leads so 7:19 that's clearly why they've used the 7:20 white to uh do this power consumption of 7:23 the white is pretty high so going up to 7:25 about 2 and 1 half amps on that color 7:27 whereas most of the other colors are 7:28 only drawing half an amp or so at 24 7:30 volts the uh the green is up to about 7:32 1.2 but say this thing is uh much 7:35 brighter and if you actually run all the 7:38 colors at the same time you get a fairly 7:41 reasonable um looking white coming out 7:43 of it and one thing you might just be 7:45 out to notice is there is some sort 7:46 color banding around here that's not 7:49 getting uh everything s completely 7:51 concentric and I think that's where this 7:53 fiber optic thing comes 7:58 in I'll 8:00 get a couple of Fairly accurately shaped 8:04 very sort of uniform color and looking 8:06 at What's um inside here we've basically 8:09 just got this Square Rod so this is 8:12 clearly yeah the lights just bouncing 8:13 off all the all the various sides to um 8:16 get a nice uniform illumination uh this 8:19 back bit looks like it's all potted so 8:21 nothing I really do to get in there I 8:24 think this is fiber so I have come 8:26 across um cables like this which are 8:27 liquid fill but just looking through the 8:30 end of this it's probably a bit hard to 8:31 see it does look like there fiber ends 8:34 going going on there and so there's this 8:36 feedback thing which is just obviously 8:39 compensating for the any light losses 8:41 through here to get an accurate 8:43 representation of uh the light that's 8:45 been launched out of these two 8:47 fibers and you see uh 8:49 these have got this sort of trapezium 8:54 shape light guides again it's like a 8:56 sort of acrylic or glass light guide 9:00 guess projected just to make the right 9:03 rectangular 9:04 shape and look at this Center assembly 9:07 um the light output doesn't uh change 9:10 whether you feed this in or not so it's 9:11 clear not doing any internal Clos Loop 9:14 control obviously there may well be some 9:16 facility for it to do that but it's not 9:17 being used in this 9:19 application and so this output just 9:21 produces a voltage on the uh outle 9:24 connector proportional to the amount of 9:26 light that's present so there's a little 9:28 diffuser in the back there 9:30 and then there's just some kind of uh 9:33 Optical sensor looks like a 9:35 chip looking at the lead it's a very 9:37 small package on the PCB with this lens 9:40 assembly over the top and these look 9:43 like they're actually on a copper 9:44 Metalized PCB for maximum thermal 9:47 performance and yeah it's a very small 9:49 package looks like it's a ceramic 9:51 package and there's a thermister there 9:53 for temperature monitoring this is the 9:56 475 blue one this is the 520 need to 9:59 Green which is uh rather different OB 10:02 it's a much bigger D with lots of bond 10:04 wise but also this looks like it's using 10:05 a phosphor if I shine a blue light at it 10:08 lights up green so this is actually a 10:10 phosphor conversion green lead which 10:12 I've I've come across before they want 10:15 that specific wavelength so they may be 10:17 easier to tune a phosphor than tune the 10:20 um semiconductor material to get the uh 10:23 right right wavelength from the lead 10:24 directly uh red 630 similar size to the 10:28 blue one or does seem to have a uh a 10:31 lens on top of it there is a sort of red 10:33 coloring to 10:35 the die but that doesn't appear to be 10:38 fluorescent as far as I can 10:39 tell and the white one again a little 10:41 bit different sort of much higher 10:43 current 10:46 connectors a makeer name on that 10:48 connector flot light not sure if that's 10:52 the connector or the lead 10:54 itself and obviously with the phosphor 10:56 and I'd imagine that phosphor may well 10:58 be tuned to get the maximum to the uh 5 11:01 cenm and actually this white one looks 11:04 like a St fairly standard product I just 11:06 found it in Mouse made by luminous 11:09 devices in fact actually I think all 11:11 these are based on various luminous 11:13 devices modules and they're you take 11:17 looks like they taking the nearest 11:18 wavelength and then just using these 11:19 filters to clean it up to get a precise 11:22 uh spectral line out of it so quite a 11:25 nice neat and um extreme 11:30 bright light source uh sure I've got any 11:33 particular use for it so I think this 11:35 might end up on 11:36 eBay but uh very pretty to look out and 11:40 without the uh risk of burning your eyes 11:43 out like you do with lasers so I thought 11:45 it would be interesting to try and 11:46 figure out the runtime of this things 11:48 like this we usually keep some sort 11:49 record of runtime cuz leads degrade over 11:51 time I couldn't get any software to work 11:52 through the USB face but then had a 11:54 thought probably going to be writing the 11:55 runtime periodically to the e s prom so 11:58 I just just scope up that and noticed it 12:00 was doing right every 5 minutes so I 12:02 just ran it for a while periodically 12:04 reading the E squ I just held the pick 12:05 in in reset and um put clip over to read 12:07 the square prom and found it was writing 12:10 one location per color every 5 minutes 12:12 so if one color was on it would write 12:14 that location every 5 minutes and just 12:16 increment it by one so after doing a few 12:18 tests with different colors of different 12:19 time periods it looked extremely 12:21 straightforward it's like a four bite 12:22 count for each color looking at the 12:24 original data that was in it all the 12:26 colors apart from Green were reading 12:28 zero and the green was reading four 12:30 indicating a total 20 minutes run time 12:32 ever if it was turned on run for a short 12:34 time then turned off that might not have 12:36 been counted but even so indicates this 12:37 thing wasn't used a great deal the whole 12:40 s process of doing a run can be several 12:42 hours but it'll only be doing probably 12:43 the Imaging at the end of that so you 12:46 wouldn't expect to be running for a long 12:47 time but say a single color for 20 12:50 minutes over its whole lifetime does 12:52 seem a little bit on the low side okay 12:55 let's look at the camera un fortunately 12:57 I managed to not record any sound when I 12:58 did this it's also a couple of months 13:00 ago so there's going to be a few details 13:02 that I've forgotten so I'm just going to 13:04 dub this over the original footage so um 13:07 take the lid off see this massive great 13:10 heat sink so this is a pel cool camera 13:12 we've got this blower fan producing a 13:14 fair amount of air flow through 13:16 it the connector here there's the ccds 13:19 mounted on the board on the 13:24 right this unplugs so we've got a bit of 13:27 power supply stuff on here 13:29 USB interface I think that's the Cyprus 13:32 microcontroller High speeded USB 13:34 interface there's a zyink spon fpga some 13:40 RAM and there's a couple of ATD 13:42 converters can't quite read what those 13:45 those are but anal 13:47 devices um little bit of bodgery around 13:51 here extra decoupling obviously they 13:53 have having some noise issues this is 13:55 around the ram chip quite a lot of extra 13:57 capacitors been added there 13:59 uh there's a couple of amplifiers prior 14:01 to the HD converter buffers or Andor 14:05 amplifiers taking the CCD 14:08 signal um bit more power spy stuff here 14:11 this is probably all to do with 14:12 generating the various CCD bias voltages 14:14 they uh need quite a lot of exotic 14:18 voltages next board down is just a 14:20 shield and an interconnect 14:24 boardly shielding the power supply stuff 14:26 from some the more sensitive an log 14:28 stuff 14:31 and this is the bottom board which is 14:32 just all power supply 14:34 stuff as you can see tons of capacitors 14:37 or Transformer in 14:42 there and this is the CCD which is a uh 14:47 very impressive thing this is a kf50 100 14:50 originally by true sense then codec 14:53 there ON 14:54 Semiconductor it's 50 megapixels uh the 14:58 only price I could find was this one 15:00 5,000 bucks and the architecture you can 15:03 see there actually two separate halves 15:04 which explains the Dual AZ converters 15:06 and two amplifiers it's literally split 15:08 down the middle and duplicated so it's 15:10 outputting two streams in parallel just 15:13 to keep the bandwidth sensible and it's 15:15 got this amazing um diffraction effects 15:18 it's got micro lenses over the pixel so 15:20 there's there's a bit more Optics going 15:22 on than on a normal 15:25 sensor few more bodges on the CCD board 15:28 including this wire which isn't really 15:29 tacked down very well which is a bit uh 15:32 bit of a mess quite a few bits around 15:34 this board where they've uh tacked 15:36 various bits on which is not super 15:38 impressive looks like CCD drivers on the 15:40 left with those 3 ohm um damping 15:43 resistors on the 15:47 output get a few more little bodges 15:50 around here some of 15:52 the and there's this separator the 15:54 silica gel to keep the moisture down but 15:56 there's this separator that actually 15:58 appears to be cut from piece of 15:59 antistatic 16:04 bag and this sort of thermal block on 16:06 top of this stack of three pel Cola 16:12 modules so as with any Stacks they get 16:16 um larger as they go back towards the 16:18 heat sink because each P's got to not 16:20 only take the heat from the previous but 16:21 also the waste heat which is quite 16:27 significant you see a little temperature 16:29 sensor here that copper block which 16:32 makes contact with the back of the 16:37 CCD and this's the back of the 16:40 pelas this then contacts the heat sink 16:44 on the uh rear there a few thermal pads 16:46 as well for some of the other power 16:47 components on this 16:51 PCB okay I've connected this uh camera 16:54 up I found some drivers on the disc that 16:56 seem to work under Windows 7 couldn't 16:58 get to install under Windows 11 though 17:01 um in the absence of any sort of lens or 17:03 being bothered to the proper amount I've 17:04 just put some f over it and put a little 17:06 pin in there to make a pinhole lens and 17:08 software gives a few options I'm not 17:11 entirely sure what all these are there's 17:12 obviously a clock frequency 22 MHz low 17:15 gain and with PFG no idea what that is 17:19 something something game programmable 17:20 Something game perhaps ver exposure 17:23 types I think focus is just like a 17:25 continuous grab until you tell it to 17:27 stop not entirely sure all these options 17:30 are obviously exposure time uh triggers 17:33 there ex external hardware trigger inut 17:35 you just trigger using a um thing on 17:37 screen so the resolution is 8176 by 17:40 6132 and you can actually bin those 17:42 where you combine multiple pixels to get 17:46 increased gain at the expense of lower 17:48 resolution down this is a 10sec exposure 17:51 obviously of the pin hole it's very uh 17:53 intensitive so we just stand still now 17:56 downloading it there's the uh exposure 17:59 so when it's 18:01 um there's a little status thing down 18:03 here so that tells you the um exposure 18:07 [Applause] 18:09 time it's this is just it 18:15 downloading um it is quite I'm seeing 18:18 quite a lot like smearing I think that I 18:20 don't know whether that's just due to 18:21 pixels overloading or something else I 18:24 mean yeah it's not it's not um out of 18:26 the question that there's something not 18:27 totally right about this camera 18:28 certainly was bodge wise on there um I 18:31 don't I'd imagine a camera like this 18:32 it's got a fairly narrow range of 18:34 intensities that it's happy with I'm not 18:36 going to spend a great deal of time on 18:38 this if you're interested in this camera 18:40 maybe for astronomy or something and 18:42 happy to sort of take the risk of it may 18:44 not be uh perfect I'll um I think I'll 18:47 stick this on eBay along with the 18:48 Illuminator I'll put a link down in the 18:50 description to the listing take your 18:52 chances to grab a bargain so for example 18:54 here we see this vertical streaking so 18:56 I'm not sure how normal that is this is 18:58 on fairly bright scene looking out the 19:02 window if I cut the exposure time down 19:04 on that it's now 1 second 19:07 exposure again most of the image 19:09 disappears again this is looks like it's 19:11 possibly over still overloading here go 19:14 that go down to say say quarter a 19:16 second so again I think there might be 19:19 some Auto gain control going on here um 19:21 this is with the PFG option let's try 19:23 turning that off and see what 19:25 happens so I'm not sure this is actually 19:27 more streaking or which just it's 19:29 cranked up the gain all the dis display 19:31 gray scale to show what um you know the 19:33 range of things that it's captured 19:36 there's one of one of 12 things in the 19:38 software there's um you can see of you 19:40 can't seem to read out the temperature 19:42 of the pelta cooler but you can set the 19:44 temperature and if you said it's a 19:46 different temperature you see the power 19:48 consumption jump up running the cooler 19:50 to get the temperature you requested but 19:52 I can't see anything anywhere that tells 19:54 you whether the cool is at the at the 19:56 temperature other than the power 19:57 consumption going down and there's no 19:59 temperature read out 20:03 here and just some yeah this is just 20:05 sort of very basic software I'm sure 20:07 there's like an API for more 20:09 sophisticated 20:10 applications but so if you know anything 20:12 more about these cameras please um stick 20:14 in the 20:15 comments um incidentally when I was 20:18 editing I didn't notice there was a bent 20:19 pin on the um CCD but I did fix that 20:22 before doing these tests and also 20:24 reactivated the um silica gel desicant 20:26 cuz I noticed it was uh I was getting 20:28 bit of condensation on the window but um 20:31 yeah so a couple of uh interesting but 20:34 maybe not particularly uh useful pieces 20:37 of Kit except for someone that's got a 20:38 very specific use so um I'll stick a 20:42 I'll stick these on eBay put a link in 20:44 the description and say hopefully 20:45 someone could actually make some uh good 20:47 use of these things Example Output: **Abstract:** This video presents Part 2 of a teardown focusing on the optical components of a Fluidigm Polaris biotechnology instrument, specifically the multi-wavelength illuminator and the high-resolution CCD camera. The Lumen Dynamics illuminator unit is examined in detail, revealing its construction using multiple high-power LEDs (430nm, 475nm, 520nm, 575nm, 630nm) combined via dichroic mirrors and filters. A square fiber optic rod is used to homogenize the light. A notable finding is the use of a phosphor-converted white LED filtered to achieve the 575nm output. The unit features simple TTL activation for each color, conduction cooling, and internal homogenization optics. Analysis of its EEPROM suggests extremely low operational runtime. The camera module teardown showcases a 50 Megapixel ON Semiconductor KAF-50100 CCD sensor with micro-lenses, cooled by a multi-stage Peltier stack. The control electronics include an FPGA and a USB interface. Significant post-manufacturing modifications ("bodges") are observed on the camera's circuit boards. Basic functional testing using vendor software and a pinhole lens confirms image capture but reveals prominent vertical streaking artifacts, the cause of which remains uncertain (potential overload, readout artifact, or fault). **Exploring the Fluidigm Polaris: A Detailed Look at its High-End Optics and Camera System** * **0:00 High-End Optics:** The system utilizes heavy, high-quality lenses and mirrors for precise imaging, weighing around 4 kilos each. * **0:49 Narrow Band Filters:** A filter wheel with five narrow band filters (488, 525, 570, 630, and 700 nm) ensures accurate fluorescence detection and rejection of excitation light. * **2:01 Customizable Illumination:** The Lumen Dynamics light source offers five individually controllable LED wavelengths (430, 475, 520, 575, 630 nm) with varying power outputs. The 575nm yellow LED is uniquely achieved using a white LED with filtering. * **3:45 TTL Control:** The light source is controlled via a simple TTL interface, enabling easy on/off switching for each LED color. * **12:55 Sophisticated Camera:** The system includes a 50-megapixel Kodak KAI-50100 CCD camera with a Peltier cooling system for reduced noise. * **14:54 High-Speed Data Transfer:** The camera features dual analog-to-digital converters to manage the high data throughput of the 50-megapixel sensor, which is effectively two 25-megapixel sensors operating in parallel. * **18:11 Possible Issues:** The video creator noted some potential issues with the camera, including image smearing. * **18:11 Limited Dynamic Range:** The camera's sensor has a limited dynamic range, making it potentially challenging to capture scenes with a wide range of brightness levels. * **11:45 Low Runtime:** Internal data suggests the system has seen minimal usage, with only 20 minutes of recorded runtime for the green LED. * **20:38 Availability on eBay:** Both the illuminator and camera are expected to be listed for sale on eBay. Here is the real transcript. Please summarize it: 00:00:17 [Music] 00:00:17 So once upon a time as you all know Papa 00:00:21 New Bank acquired Cognitech and Daytomic 00:00:23 in 2020. Acquisitions can carry some 00:00:26 baggage, concerns about control, 00:00:29 direction, and values. But in this case, 00:00:31 there was something deeper. There was 00:00:33 actually 00:00:34 alignment. New bank had this mission to 00:00:37 simplify banking for Brazilians. And 00:00:39 that resonated with Donic's philosophy 00:00:41 of simplicity and software. It's a 00:00:44 shared commitment to reducing complexity 00:00:45 that made the partnership not only 00:00:47 workable, but powerful and 00:00:50 beneficial. So, since then, we've grown 00:00:52 the Dayic team considerably. 00:00:54 showing New Bake's commitment to the 00:00:56 product. That's me. I'm on the day talk 00:00:58 team now. 00:01:06 Yay. So last October I visited New 00:01:06 Bank's headquarters in Brazil for our 00:01:09 storage and databases all hands. Now I 00:01:12 am a seasoned traveler and one of my 00:01:15 personal values is independence. So 00:01:17 instead of sitting in Salo traffic, 00:01:20 which is the worst, just so bad, so bad, 00:01:25 I decided I wanted to take public 00:01:27 transport. You know, all my time in 00:01:28 Europe taught me 00:01:30 well. It was a terrible 00:01:33 idea. No one spoke English. We were 00:01:36 underground and my translation app 00:01:38 didn't work. I couldn't even read the 00:01:40 kiosk instructions. So I thought I was I 00:01:44 would try the classic strategy. I would 00:01:45 just notice what other and copy the 00:01:47 locals, see what they were doing. So I 00:01:49 posted up next to a kiosk so I could 00:01:51 study what buttons they were hitting and 00:01:53 copy the pattern. And I watched person 00:01:55 after person and some succeeded, some 00:01:58 failed, but the common denominator was 00:02:01 that every card with that iconic new 00:02:04 bank purple just worked. 00:02:12 And that may be anecdotal, but that was 00:02:12 the first time that I realized how 00:02:15 deeply we're impacting real people and 00:02:19 not just a few. As of April 2025, New 00:02:23 Bank serves 114.3 million users. We've 00:02:28 grown from 93.9 million customers in 00:02:31 2023 to 00:02:33 114.3, adding over 20 million users. We 00:02:37 ha we sustain an 83% activity 00:02:40 rate and despite rising total customer 00:02:43 base and sustained active customer base 00:02:45 we have some of the lowest cost to serve 00:02:48 as a bank 00:02:49 globally the lowest cost to serve 00:02:53 globally and we are an independent 00:02:56 bank. One of New Bank's values is 00:02:58 creating fanatical customers and this 00:03:01 customer- centric approach is what's 00:03:02 helped them become the biggest 00:03:04 independent bank in the world. 00:03:06 So since 2015, we've added nearly 13 00:03:09 million customers every year on average. 00:03:12 But here's what's 00:03:14 amazing is that 80% of that growth came 00:03:17 from word of mouth referrals 00:03:24 alone. Because before New Bank entered 00:03:24 the scene, retail lending in Brazil was 00:03:27 a game rigged against the average 00:03:29 individual. Interest rates on personal 00:03:31 loans of opt often topped 100% per year. 00:03:36 There was very low financial inclusion. 00:03:37 As recently as 2017, about 45 million of 00:03:41 Brazilians were 00:03:43 unbanked, under the grid, underbanked. 00:03:46 And before new bank credit access, 00:03:49 before new bank credit access was either 00:03:52 non-existent or just so prohibitively 00:03:56 expensive that so a most people just 00:03:58 didn't have it. And so for millions of 00:04:01 people, New Bank was their first credit 00:04:04 card, their first savings account, their 00:04:07 first 00:04:14 loan. What does that translate to in 00:04:14 technical terms 00:04:16 though? So we handle pabytes of 00:04:19 data. We have over 3,000 datomic 00:04:23 databases, some with a over a 100red 00:04:25 billion days. We have 4,000 00:04:28 microservices with Kubernetes. We 00:04:30 process 72 billion daily events via 00:04:34 Kafka and we routinely handle millions 00:04:37 of requests per second. And that's all 00:04:40 within complex baking compliance 00:04:41 regulations where the consequence of 00:04:43 getting it wrong isn't just a bad 00:04:45 performance review. The consequence is 00:04:47 going to jail. 00:04:58 So last week I was in Norway at NDC Oslo 00:04:58 and I met some folks from another 00:05:01 database that were really really excited 00:05:02 to talk to me and talk to the team and 00:05:04 they said that they were just last night 00:05:06 talking about New Bank and admiring how 00:05:08 we're really more of a tech company than 00:05:11 we were a bank and that's an astute 00:05:15 observation. We have as of there's a 00:05:18 recent report that dropped over 8,700 00:05:22 employees spread across six countries 00:05:25 and over 3,000 00:05:33 engineers. So let's talk for a second 00:05:33 about scalability and what that even 00:05:36 means because we are at a closure 00:05:37 conference. Here is the obligate Latin 00:05:43 root and we can see that means a ladder 00:05:46 used in 00:05:48 sieges. So scalability is the ability to 00:05:52 climb or ascend a ladder. 00:05:55 Okay. The thing is the definition of 00:05:58 scalability has evolved since 00:06:01 Latin. So much so there's even recently 00:06:03 been a scientific paper on it. This 00:06:05 paper looked to harmonize all the 00:06:07 definitions of scalability as a company 00:06:10 in scaling and scaling up and it looked 00:06:14 at 57 different articles to try and 00:06:16 define what scaling actually 00:06:19 means. So I was consuming all of the 00:06:23 literature on this and there was 00:06:24 something that stuck out this 00:06:27 distinction between growth and 00:06:30 scaling. Because growth is increasing 00:06:33 revenue, but at what cost? Well, any 00:06:36 cost. So, you're getting bigger, but 00:06:38 you're also proportionately increasing 00:06:39 your 00:06:40 resources. Growth is like walking on an 00:06:43 escalator in the wrong 00:06:45 direction. You may seem like you're 00:06:47 moving, but you're not actually 00:06:49 progressing very 00:06:50 far. Scaling, on the other hand, is 00:06:53 increasing your output, but 00:06:55 proportionally reducing your 00:06:57 resources. Scaling is riding the 00:06:59 escalator in the right direction. 00:07:03 And funny enough, that matches another 00:07:04 one of New Bank's 00:07:06 values, pursuing smart 00:07:13 efficiency. So, an efficiency ratio is a 00:07:13 financial metric that assesses how 00:07:15 effectively a company utilizes its 00:07:17 resources to generate revenue and 00:07:19 profits. It measures the ability of a 00:07:22 company to convert assets into income. 00:07:25 and it indicates how well they're 00:07:27 managing their operations and managing 00:07:29 maximizing their profitability. So, new 00:07:34 bank does amazing this 00:07:36 metric. In a recent report, they have a 00:07:40 29.9 efficiency rating when the industry 00:07:43 average is almost twice that. 00:07:49 So, how is New Bank keeping their cost 00:07:49 to serve down and operating so 00:07:53 efficiently, so 00:07:54 efficiently? 00:07:56 Well, I'm not qualified to speak on 00:07:58 much, but what I am qualified to speak 00:08:00 on is the different types of scalability 00:08:03 in the context of a fintech software 00:08:06 company because scalability isn't just 00:08:09 handling more new handling more users. 00:08:11 At 00:08:12 Newbank, we think about architectural 00:08:15 scalability, asking questions like, can 00:08:17 our systems grow without a complete 00:08:19 redesign? Does the architecture stay 00:08:21 performant under load? Which leads us to 00:08:23 performance 00:08:24 scalability? Can we increase the 00:08:26 throughput without increasing latency or 00:08:30 cost? And then we have our people 00:08:32 process scalability. Do human problems 00:08:34 cause your system to break or prevent 00:08:35 you from moving forward and you from 00:08:37 shipping? 00:08:46 That's just a cool slide I 00:08:46 made. That might be a new t-shirt. We'll 00:08:50 see. Okay. First, we're going to talk 00:08:52 about architectural 00:08:58 scalability. Oh, I didn't center the 00:08:58 div. Oh, 00:09:01 man. Okay. Traditional databases cluster 00:09:04 or shard to handle load, which 00:09:07 introduces coordination complexity. 00:09:09 Daytomic takes a completely different 00:09:10 approach. It does the peer 00:09:12 model. So in datomic the heavy lifting 00:09:16 of doing reads moves out and is 00:09:18 distributed among 00:09:19 peers. Peers are distributed application 00:09:23 nodes that can do things like run 00:09:25 queries, cache data locally, read 00:09:28 directly from storage, and submit 00:09:30 transactions to a central 00:09:33 transactor. So it flips the model where 00:09:35 the brain isn't the server anymore. each 00:09:38 peer is is capable. This model lets us 00:09:42 scale reads horizontally and cache 00:09:44 aggressively without breaking 00:09:47 consistency. So the goal of this model 00:09:49 is to reduce the load on a single 00:09:51 monolithic server and transfer the 00:09:53 burden of getting all the answers to all 00:09:56 the peer to a distributed peer model. So 00:10:00 imagine a big box store on Black 00:10:04 Friday. It's chaos. Hundreds of people 00:10:07 fighting over the same checkout lane. 00:10:09 That's like a monolithic system under 00:10:11 load. Now picture small bit small 00:10:14 business 00:10:16 Saturday. Dozens of independent shops 00:10:18 each handling their own customers. 00:10:20 That's the peer model. The work is 00:10:23 distributed and so the load is man the 00:10:25 load is manageable. 00:10:27 The peer model architecture is 00:10:29 arbitrarily horizontally 00:10:32 scalable. And I'm not going to talk much 00:10:35 about our storage layer today, but 00:10:38 something I found interesting in our 00:10:41 architecture is when I was first 00:10:43 learning programming, one of the cheat 00:10:45 codes that I would use to reason 00:10:47 something out was when in doubt, 00:10:49 abstract it out. And that's exactly what 00:10:51 we do with our storage layer. This means 00:10:54 we can integrate and sit on top of most 00:10:56 other storage layers. SQL, Postgress 00:10:59 were built with AWS in mind and that's 00:11:01 what Dubank uses. But you can use any 00:11:04 relational 00:11:05 database, anything with a key value 00:11:07 store that we can store segments 00:11:17 in. So in the pure model, you can 00:11:17 improve the performance of your system 00:11:19 by improving the performance of your 00:11:20 transactions. And there are several 00:11:23 features added to datomic in the last 00:11:25 year or so that improve the 00:11:27 observability and performance of 00:11:30 transactions. So the first is 00:11:32 transaction stats and IO stats and I 00:11:36 have colleagues that have a really 00:11:38 wonderful talk on this. Um there'll be a 00:11:41 link at the end the day most watch 00:11:43 mustwatch playlist. 00:11:46 Um but really this just provides 00:11:48 observability and it's how we can 00:11:51 demonstrate the value of the next two 00:12:00 features. Uh we have transactor hints 00:12:00 and implicit partitions. Transactor 00:12:02 hints improve read speed by 00:12:04 speculatively determining the reads 00:12:06 necessary for the transaction and then 00:12:08 sending that to the transactor. It 00:12:10 sounds complicated. It is not. Well, 00:12:12 maybe it is, but we'll make it simple. 00:12:16 Implicit partitions improve data 00:12:19 locality improving read performance for 00:12:21 operations that do reads like queries 00:12:23 and 00:12:25 transactions. And so now we had talked 00:12:28 about the peer architecture model. We 00:12:30 talked about peers 00:12:31 um and now we're going to have to talk 00:12:33 about transactors. 00:12:35 And I have to do this because when I 00:12:37 talk about performance scalability which 00:12:38 is the next part some of the techniques 00:12:40 improve performance by shortening the 00:12:43 latency of the 00:12:49 transactions. So this is my own personal 00:12:49 interpretation of our 00:13:04 We have our cool guy 00:13:04 transactor and we have our storage 00:13:06 later. Even looks like it's partitioned. 00:13:09 Well, huh. 00:13:12 Huh. So, we can see that the peers can 00:13:16 read from storage and we see the peers 00:13:18 write the 00:13:20 storage. So, we'll do a little bit of a 00:13:24 peer 00:13:25 review. Okay. 00:13:27 Each pier is a service node and every 00:13:30 pier has an address that points at a 00:13:39 transactor. There's only ever one cool 00:13:39 guy active transactor role per day 00:13:41 datomic instance. There's only one 00:13:45 machine being that guy. I mean, look at 00:13:47 that guy. There's one one of that guy. 00:13:49 Well, except when you have an optional 00:13:52 high availability backup. 00:14:00 So we're also we'll review storage real 00:14:00 quick. Storage pick your poison any key 00:14:02 value store. So okay when a peer in a 00:14:06 transactor connection is established the 00:14:08 transactor tells the peers yo here's 00:14:11 your 00:14:16 storage and the peers can read data 00:14:16 directly out of storage and then write 00:14:17 them to a cache such as green cache. And 00:14:20 this is done sequentially. First the 00:14:22 peer is like hey do I have 00:14:25 this and if it's not there then it's 00:14:28 going to pull it from storage and write 00:14:29 it to the cache. So the next time it's 00:14:31 in the cache for 00:14:33 us. Peers establish connections to 00:14:36 storage directly as directed by the 00:14:39 transactor and they pull information 00:14:42 from 00:14:48 storage. Pairs also submit transactions 00:14:48 to the transactor. A transactor's entire 00:14:51 purpose in life's entire goal in life is 00:14:54 to accept transaction data, commit valid 00:14:58 commit valid transaction data and tell 00:15:01 the peers what transaction data it has 00:15:03 committed. Now this is really overly 00:15:07 simplified 00:15:09 um because I just needed the context to 00:15:11 be able to describe to you Dayic hints. 00:15:16 Now, if you want a deeper dive, that 00:15:18 dayic mustwatch playlist contains a uh 00:15:22 talk by my colleague Joe Lane where he 00:15:25 that's a nitty-gritty deep talk for so 00:15:28 many boxes, so many architecture models. 00:15:29 You'll love it. It'll be great. 00:15:36 So in 00:15:36 October 2024 or the first implementation 00:15:40 of daytom kense appeared. It is a 00:15:42 scalable approach to identifying work 00:15:44 that needs to be done inside of these 00:15:47 transactions. This allows a system to 00:15:50 begin performing the IO for the 00:15:51 transaction while it's cued and that 00:15:55 takes advantage of otherwise wasted 00:15:57 time. 00:15:59 So we are reducing IO inside of our main 00:16:02 threads. So our utilization can reduce 00:16:06 dramatically which increases our 00:16:10 throughput. 00:16:17 So all you have to do is put in return 00:16:17 hints 00:16:19 true 00:16:25 and that will get attached to the 00:16:25 transactor. 00:16:27 So, if each service pier is a grocery 00:16:29 store, you can think of it like curbside 00:16:32 pickup or click and collect for the 00:16:36 transactor. And just like you can save 00:16:38 time by doing your grocery order ahead 00:16:40 of time and then having the grocery 00:16:42 store person do all, you know, they have 00:16:44 the shopping list and they do all the 00:16:46 shopping. All you have to do is pull up 00:16:48 and everything's ready and they put into 00:16:50 your car. By including return hints true 00:16:52 and getting the 00:16:54 hint, you're passing and passing it to 00:16:57 the transactor, giving them the shopping 00:16:59 list, you're placing your online order. 00:17:01 So all the transactor has to do is pull 00:17:04 up and it's 00:17:09 ready. Pretty 00:17:09 cool. Like I said, watch Joe's talk. 00:17:12 It's 00:17:13 nitty-gritty. So the next feature we're 00:17:15 going to talk about is implicit 00:17:18 partitions. 00:17:20 Oh, it was released on 420. That's nice. 00:17:23 Okay. 00:17:28 2023. 00:17:29 So, in 00:17:31 Daytomic 00:17:33 partitions allow applications to group 00:17:35 entities and gain control over data 00:17:47 locality. Data locality is how data is 00:17:47 physically distributed. Because when 00:17:48 you're looking for data, it's in a 00:17:50 physical 00:17:50 location. And if an application's data 00:17:54 is all over the place, um you know, it's 00:17:58 all mixed together. A query may struggle 00:18:00 to find results per storage read since 00:18:02 Dayic will have to read more segments. 00:18:04 It'll have to go into different aisles 00:18:06 of the store to find 00:18:08 things. On the other hand, if you've 00:18:10 used implicit partitions, queries can 00:18:13 efficiently retrieve relevant data. So 00:18:15 it can only pull it can pull a couple of 00:18:18 segments because all the information 00:18:20 that it wants is going to be kind of in 00:18:22 the same 00:18:23 area. So each implicit partition 00:18:25 corresponds to an entity ID and they 00:18:28 don't require a transaction to 00:18:31 create. And so if we return to our 00:18:35 grocery store 00:18:37 example, if you're doing your shopping 00:18:39 and you wanted to get you wanted a salad 00:18:42 because you're you're healthy, you've 00:18:44 turned over a new 00:18:45 leaf. And so you can go to the produce 00:18:50 aisle and get some lettuce. And then you 00:18:52 can go to the dressing aisle and get 00:18:54 some 00:18:54 lettuce. Get some lettuce. And then you 00:18:57 can go to the cheese aisle and get some 00:19:00 cheese. Or if you ever seen a nice salad 00:19:03 bar set up, that is what it's like 00:19:06 having implicit partitions. All you have 00:19:08 all the stuff that you want for your 00:19:10 salad is in one place because you've 00:19:12 said, "Hey, keep track of this. 00:19:20 So with implicit partitions when you 00:19:20 transact something new requery for data 00:19:22 datomic will pull fewer segments 00:19:25 reducing latency in leading to a much 00:19:28 faster 00:19:33 database. 00:19:33 So both of these both of these 00:19:37 features you can uh look out for you 00:19:40 know in the next the next six months in 00:19:44 closure camp we're having monthly doing 00:19:46 daytomic meetups we're doing mob 00:19:48 programming and we're probably going to 00:19:51 play around um with these features in 00:19:54 the next six months. So watch out for 00:19:56 that if you want to get your hands 00:20:02 dirty. 00:20:02 Okay. So Closure and Atomic are running 00:20:05 reliably on systems bigger than they've 00:20:08 ever have 00:20:10 before. And these systems are inherently 00:20:12 complex due 00:20:15 to banking compliance, 00:20:17 regulation. People are complex. Millions 00:20:21 of people trust us with their 00:20:23 hard-earned money. 00:20:25 And we're helping millions of people be 00:20:27 empowered with their 00:20:29 money. Like I said, New Bank is the 00:20:31 biggest independent bank in the world 00:20:33 and it runs on Closure and 00:20:40 Dayic. Recently, Daytomic added a couple 00:20:40 of new features. We talked about 00:20:42 transactor hints where the peers 00:20:46 speculate what segments a transaction 00:20:48 will need so the transactor can fetch 00:20:50 them 00:20:51 early which means less IO on the main 00:20:54 thread which is shorten lat shorter 00:20:57 latency and implicit 00:21:00 partitions which are autodistributed ID 00:21:03 ranges that improve data 00:21:06 locality kind of like going to the salad 00:21:09 bar um instead of going down every aisle 00:21:12 to find the ingredients so you don't 00:21:13 have to search the entire 00:21:15 store. How we recognize that these 00:21:18 features do improve performance is with 00:21:21 IO stats and transaction stats. These 00:21:24 are built-in observability tools to 00:21:26 validate, measure and tune real world 00:21:29 real world performance. So you can do 00:21:33 the scientific method as as recommended. 00:21:35 You can you can poke, you can prod, you 00:21:37 can experiment and you can see 00:21:40 um the effects 00:21:41 of your queries, your 00:21:48 transactions. So what does scaling 00:21:48 simplicity actually mean? 00:21:51 Well, in this 00:21:53 talk where we've talked about 00:21:55 architectural scalability and datomic 00:21:58 peer model and how it distributes a load 00:22:00 intelligently kind of like a town full 00:22:03 of wellorganized small 00:22:06 businesses kind of like 00:22:09 Germany instead of a single chaotic mega 00:22:12 store. 00:22:14 And our our architectural scalability in 00:22:17 the peer model enables services to grow 00:22:19 without creating new bottlenecks. So we 00:22:22 don't it's infinitely arbitrarily 00:22:26 horizontally scalable. Beautiful. 00:22:29 We also talk about performance 00:22:31 scalability and those features that I 00:22:33 just mentioned transaction hints and 00:22:34 implicit 00:22:36 partitions reduce I/IO and improve data 00:22:39 locality letting us hen letting us 00:22:41 handle billions of datoms, millions of 00:22:44 requests per second and 00:22:46 still reduce our cost to serve our cost 00:22:51 per 00:22:53 user. And then we have our people 00:22:55 process 00:22:57 scalability. New banks values 00:22:59 simplicity, smart efficiency and 00:23:01 fanatical customer focus. That aligns 00:23:04 perfectly with the philosophy behind 00:23:06 atomic enclosure and cognit. And that 00:23:10 alignment is part of what's made us so 00:23:13 successful together. That alignment 00:23:14 helps over 3,000 engineers ship safely. 00:23:17 and it helps millions of people access 00:23:19 financial tools that they never had 00:23:23 access to 00:23:24 before. In a poll, uh over 74% said that 00:23:29 new bank uh helped the helped their 00:23:32 financial 00:23:33 health. And so Papa New Bank signs the 00:23:38 paycheck, but Daytomic is still a 00:23:42 product outside of New Bank. New Bank is 00:23:44 one of our clients and we have other 00:23:47 clients from Netflix to the rare cancer 00:23:50 research center to other banks like 00:23:55 HSBC. Daytomic is scaling and new bank 00:23:59 is 00:24:00 scaling. And if you're curious how 00:24:02 Daytomic can help you scale too, we'd 00:24:05 love to help. 00:24:15 Um, well, clap. Yay. Done. I'm going to 00:24:15 do some more slides. That was the end of 00:24:17 [Applause] 00:24:24 the 00:24:26 Okay, the the rest of things um you 00:24:30 know, I'm just going to do some some 00:24:31 things to know, things to remember. So, 00:24:34 this is that dayic mustwatch YouTube 00:24:36 playlist. I'll get that up there. 00:24:38 Um, it's on my Lambda YouTube where I've 00:24:41 compiled all the greatest hits. Um, I 00:24:44 just want to remind you that Daytomic is 00:24:47 free to 00:24:48 use and we have a really, really good 00:24:51 support story. We have a ticketing 00:24:54 system that gets addressed for bugs. We 00:24:56 are, you know, working on developing 00:24:58 workshops and content to help people 00:25:01 experience success at Atomic. So, you 00:25:04 know, we'd love to talk to you all 00:25:06 about, you know, do taking these 00:25:08 educational opportunities with you or 00:25:11 your company or even your group of 00:25:12 friends if you want. Um, just talk to 00:25:15 me, talk to Robert in the yellow 00:25:18 here. 00:25:20 Um, we have the monthly mob programming 00:25:23 meetups in closure camp. um which I 00:25:27 facilitate the intro to closure on the 00:25:29 first Tuesday of every month and the 00:25:31 doing daytomic on the fourth Thursday or 00:25:36 last Thursday. Still 00:25:39 deciding. Um and I 00:25:43 would like to take a moment to thank um 00:25:47 the best banana manager ever, 00:25:51 Robert. He always wears yellow. 00:25:54 um a super badass leader, Cat Swatell. 00:25:59 It's so awesome having amazing 00:26:01 leadership. Her and Justin are great. 00:26:04 And most of all, I'd like to thank my 00:26:07 um my 00:26:10 teammates who wrote and explained a lot 00:26:12 of these resources. A lot, you know, 00:26:14 they empowered me to be able to learn 00:26:17 this so I can communicate it to you. And 00:26:19 that's the beautiful thing about being 00:26:21 on a team. Um Aldo who's over there in 00:26:24 the room in the green shirt. He's been 00:26:25 at New Bank for over five years, worked 00:26:27 with so many of the systems and um we've 00:26:30 been creating a lot of this workshop 00:26:32 content together. Um so if you have any 00:26:34 like more technical questions, Dr. Aldo, 00:26:36 raise your hand. There's Aldo. Haha, 00:26:38 you're on the spot 00:26:40 now. Um I'd also like to thank uh Darlay 00:26:44 who has written a lot around implicit 00:26:46 partitions. 00:26:48 Uh Joe Lane, Alex Readington, and Gotti 00:26:52 all, you know, helped me when I said, 00:26:54 "Oh god, what what have y'all done in 00:26:55 the last year?" I made a lot of promises 00:26:57 in that 00:26:58 abstract without knowing the answer to 00:27:01 that yet. Um so 00:27:05 yeah, thank and thank you all 00:27:09 for supporting me through the journey. 00:27:11 I've been friends with you all for a 00:27:13 while now, so the comeup has been fun, 00:27:15 right? Um, and I'm so excited I get to 00:27:18 actually enjoy the conference 00:27:20 now and it's going to be great. 00:27:24 Um, and so yeah, talk we have a 00:27:27 sponsorship table over there. Uh, we 00:27:29 want to know some things. Are you using 00:27:30 Daytomic? Why or why not? It's a 00:27:33 product. We're still developing it. I 00:27:34 have a product manager asking questions 00:27:37 that I need to like tell her the answer 00:27:40 to. So, give me the stuff I need to keep 00:27:43 coming back to these things. Okay. 00:27:46 Um, okay. I think I'm really done now, 00:27:48 unless anybody wants to do any more
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*Abstract:* This video explores the profound impact of pornography consumption on individuals' lives and relationships, featuring personal testimonies from people who began watching porn at a young age. It delves into how early, often unsupervised, exposure to pornography can distort perceptions of sex, relationships, and self-worth, leading to unrealistic expectations, feelings of shame, and even addictive behaviors. Participants share their experiences with problematic use, including using porn as a coping mechanism and the resulting struggles with intimacy, commitment, and genuine connection in real-life relationships. The discussion also touches upon avenues for recovery, such as open communication, abstinence, and redefining personal values regarding sex and intimacy, highlighting that a healthier relationship with sex, or even chosen celibacy, is possible after navigating the challenges of porn obsession. *Sex After Porn Obsession: Exploring the Impacts and Recovery* * *0:05 British Reluctance, Series Focus:* The video introduces the British cultural reluctance to discuss sex openly, setting the stage for a series that tackles the subject head-on, specifically focusing on "sex after porn obsession" in this episode. * *0:25 Unrealistic Expectations from Pornography:* Contributors discuss how pornography set "unrealistic expectations" for them regarding what sex should be, leading to disappointment in real-life experiences. * *0:43 Porn as Self-Medication:* One individual reveals using pornography to "medicate a lot of the emotions" related to childhood, social, educational, and familial pressures. * *0:54 Inability to Stop:* The feeling of being unable to stop watching porn, despite wanting to, signals a problematic dependency. * *1:17 Increased Accessibility & Prevalence:* Pornography, while ancient, is now more accessible than ever due to technology, with UK addiction treatment centers suggesting 8.8 million adults watch porn weekly. * *1:40 Common Thread: Early Exposure:* All interviewed participants started watching porn at a young age, influenced by factors like religious abstinence-only education, conservative cultural upbringings that avoided sex discussions, or coping with personal loss and puberty. * *4:30 Research on Early Exposure:* On average, children first see pornography at age 13, with 1 in 10 having seen it by age 9. * *5:14 Progression to Dependency:* What often starts as casual "exploration" can quickly escalate to a daily habit, leading to feelings of "dependency" rather than enjoyment. * *6:36 Distorted Views of Sex and Relationships:* Porn distorts views of sex, women, and real-life relationships, leading to complacency, the belief that "sex would solve most issues," and a lack of focus on deeper connection. * *7:12 Disappointing First Experiences:* Many shared experiences of disappointing first sexual encounters, as they didn't live up to the fantasies created by porn. * *7:39 Porn's Impact on Behavior:* Surveys suggest viewing online pornography can affect behavior, with potential correlations to aggression and coercion, and concerns about sexual violence depicted. * *8:08 Unrealistic Portrayal of Sex:* Participants initially believed porn was real, later realizing it's a performed, perfectly lit, and unrealistic depiction of sex that doesn't prioritize female orgasm. * *9:19 Difficulty Being Present and Guilt:* Long-term porn viewing can make it difficult to be present during real-life intimacy, leading to guilt, shame, and exhaustion. * *9:50 Chasing a Constant High:* The pursuit of a "constant high" from porn becomes uncontrollable, highlighting a deep-seated issue. * *11:15 Porn Addiction Not a Formal Diagnosis:* While not an official diagnosis, problematic porn use is treated by some practitioners as a compulsive sexual behavior disorder. * *11:30 "Opposite of Addiction is Connection":* Openly sharing struggles with porn with friends and trusted individuals can alleviate shame and secrecy, aiding in recovery. * *12:41 The "Try to Stop" Test:* A key indicator of unhealthy dependency is the inability to stop watching porn when one tries. * *13:10 Redefining Sex and Intimacy:* Some individuals chose abstinence journeys to reframe their understanding of sex, realizing sexual desire isn't always a "need" but sometimes a craving for other forms of connection or dopamine. * *13:49 Rise of Celibacy:* Voluntary celibacy is gaining traction, indicating a shift towards redefining sex and relationships on one's own terms, prioritizing safety, love, and intimacy over performance. * *15:58 Impact on Relationships: Commitment and Cheating:* Past porn use led to fear of commitment, treating partners as disposable objects, and prolific cheating without remorse for some. * *16:36 Replaying Unhealthy Dynamics:* Porn influenced choices in relationships, leading to patterns of engaging with "not very nice" partners and prioritizing performance over mutual enjoyment. * *17:45 Possibility of a Healthy Relationship with Porn:* Some studies suggest "romantic pornography" can improve sexual satisfaction. Re-engaging with porn differently, e.g., through sex toy reviews or audio porn, can aid in self-discovery without visual distortion. * *18:45 Life and Sex After Obsession:* Giving up problematic porn use improved connections, with participants agreeing that the negatives far outweigh the positives. * *19:15 Importance of Open Conversations:* Openly discussing porn can reduce guilt and shame, leading to support for those who want to stop and a better understanding for everyone. * *19:48 Advice for Struggling Individuals:* Find something "bigger than yourself" (partner, kids, changing life) to motivate stopping. * *20:01 Support Resources:* For those affected, help and support details are available at bbc-dot-co.uk/actionline. I used gemini-2.5-flash-preview-05-20| input-price: 0.15 output-price: 3.5 max-context-length: 128_000 on rocketrecap dot com to summarize the transcript. Cost (if I didn't use the free tier): $0.0074 Input tokens: 19987 Output tokens: 1267
Abstract:
This video explores the profound impact of pornography consumption on individuals' lives and relationships, featuring personal testimonies from people who began watching porn at a young age. It delves into how early, often unsupervised, exposure to pornography can distort perceptions of sex, relationships, and self-worth, leading to unrealistic expectations, feelings of shame, and even addictive behaviors. Participants share their experiences with problematic use, including using porn as a coping mechanism and the resulting struggles with intimacy, commitment, and genuine connection in real-life relationships. The discussion also touches upon avenues for recovery, such as open communication, abstinence, and redefining personal values regarding sex and intimacy, highlighting that a healthier relationship with sex, or even chosen celibacy, is possible after navigating the challenges of porn obsession.
Sex After Porn Obsession: Exploring the Impacts and Recovery
Below, I will provide input for an example video (comprising of title, description, and transcript, in this order) and the corresponding abstract and summary I expect. Afterward, I will provide a new transcript that I want you to summarize in the same format. **Please give an abstract of the transcript and then summarize the transcript in a self-contained bullet list format.** Include starting timestamps, important details and key takeaways. Example Input: Fluidigm Polaris Part 2- illuminator and camera mikeselectricstuff 131K subscribers Subscribed 369 Share Download Clip Save 5,857 views Aug 26, 2024 Fluidigm Polaris part 1 : • Fluidigm Polaris (Part 1) - Biotech g... Ebay listings: https://www.ebay.co.uk/usr/mikeselect... Merch https://mikeselectricstuff.creator-sp... Transcript Follow along using the transcript. Show transcript mikeselectricstuff 131K subscribers Videos About Support on Patreon 40 Comments @robertwatsonbath 6 hours ago Thanks Mike. Ooof! - with the level of bodgery going on around 15:48 I think shame would have made me do a board re spin, out of my own pocket if I had to. 1 Reply @Muonium1 9 hours ago The green LED looks different from the others and uses phosphor conversion because of the "green gap" problem where green InGaN emitters suffer efficiency droop at high currents. Phosphide based emitters don't start becoming efficient until around 600nm so also can't be used for high power green emitters. See the paper and plot by Matthias Auf der Maur in his 2015 paper on alloy fluctuations in InGaN as the cause of reduced external quantum efficiency at longer (green) wavelengths. 4 Reply 1 reply @tafsirnahian669 10 hours ago (edited) Can this be used as an astrophotography camera? Reply mikeselectricstuff · 1 reply @mikeselectricstuff 6 hours ago Yes, but may need a shutter to avoid light during readout Reply @2010craggy 11 hours ago Narrowband filters we use in Astronomy (Astrophotography) are sided- they work best passing light in one direction so I guess the arrows on the filter frames indicate which way round to install them in the filter wheel. 1 Reply @vitukz 12 hours ago A mate with Channel @extractions&ire could use it 2 Reply @RobertGallop 19 hours ago That LED module says it can go up to 28 amps!!! 21 amps for 100%. You should see what it does at 20 amps! Reply @Prophes0r 19 hours ago I had an "Oh SHIT!" moment when I realized that the weird trapezoidal shape of that light guide was for keystone correction of the light source. Very clever. 6 Reply @OneBiOzZ 20 hours ago given the cost of the CCD you think they could have run another PCB for it 9 Reply @tekvax01 21 hours ago $20 thousand dollars per minute of run time! 1 Reply @tekvax01 22 hours ago "We spared no expense!" John Hammond Jurassic Park. *(that's why this thing costs the same as a 50-seat Greyhound Bus coach!) Reply @florianf4257 22 hours ago The smearing on the image could be due to the fact that you don't use a shutter, so you see brighter stripes under bright areas of the image as you still iluminate these pixels while the sensor data ist shifted out towards the top. I experienced this effect back at university with a LN-Cooled CCD for Spectroscopy. The stripes disapeared as soon as you used the shutter instead of disabling it in the open position (but fokussing at 100ms integration time and continuous readout with a focal plane shutter isn't much fun). 12 Reply mikeselectricstuff · 1 reply @mikeselectricstuff 12 hours ago I didn't think of that, but makes sense 2 Reply @douro20 22 hours ago (edited) The red LED reminds me of one from Roithner Lasertechnik. I have a Symbol 2D scanner which uses two very bright LEDs from that company, one red and one red-orange. The red-orange is behind a lens which focuses it into an extremely narrow beam. 1 Reply @RicoElectrico 23 hours ago PFG is Pulse Flush Gate according to the datasheet. Reply @dcallan812 23 hours ago Very interesting. 2x Reply @littleboot_ 1 day ago Cool interesting device Reply @dav1dbone 1 day ago I've stripped large projectors, looks similar, wonder if some of those castings are a magnesium alloy? Reply @kevywevvy8833 1 day ago ironic that some of those Phlatlight modules are used in some of the cheapest disco lights. 1 Reply 1 reply @bill6255 1 day ago Great vid - gets right into subject in title, its packed with information, wraps up quickly. Should get a YT award! imho 3 Reply @JAKOB1977 1 day ago (edited) The whole sensor module incl. a 5 grand 50mpix sensor for 49 £.. highest bid atm Though also a limited CCD sensor, but for the right buyer its a steal at these relative low sums. Architecture Full Frame CCD (Square Pixels) Total Number of Pixels 8304 (H) × 6220 (V) = 51.6 Mp Number of Effective Pixels 8208 (H) × 6164 (V) = 50.5 Mp Number of Active Pixels 8176 (H) × 6132 (V) = 50.1 Mp Pixel Size 6.0 m (H) × 6.0 m (V) Active Image Size 49.1 mm (H) × 36.8 mm (V) 61.3 mm (Diagonal), 645 1.1x Optical Format Aspect Ratio 4:3 Horizontal Outputs 4 Saturation Signal 40.3 ke− Output Sensitivity 31 V/e− Quantum Efficiency KAF−50100−CAA KAF−50100−AAA KAF−50100−ABA (with Lens) 22%, 22%, 16% (Peak R, G, B) 25% 62% Read Noise (f = 18 MHz) 12.5 e− Dark Signal (T = 60°C) 42 pA/cm2 Dark Current Doubling Temperature 5.7°C Dynamic Range (f = 18 MHz) 70.2 dB Estimated Linear Dynamic Range (f = 18 MHz) 69.3 dB Charge Transfer Efficiency Horizontal Vertical 0.999995 0.999999 Blooming Protection (4 ms Exposure Time) 800X Saturation Exposure Maximum Date Rate 18 MHz Package Ceramic PGA Cover Glass MAR Coated, 2 Sides or Clear Glass Features • TRUESENSE Transparent Gate Electrode for High Sensitivity • Ultra-High Resolution • Board Dynamic Range • Low Noise Architecture • Large Active Imaging Area Applications • Digitization • Mapping/Aerial • Photography • Scientific Thx for the tear down Mike, always a joy Reply @martinalooksatthings 1 day ago 15:49 that is some great bodging on of caps, they really didn't want to respin that PCB huh 8 Reply @RhythmGamer 1 day ago Was depressed today and then a new mike video dropped and now I’m genuinely happy to get my tear down fix 1 Reply @dine9093 1 day ago (edited) Did you transfrom into Mr Blobby for a moment there? 2 Reply @NickNorton 1 day ago Thanks Mike. Your videos are always interesting. 5 Reply @KeritechElectronics 1 day ago Heavy optics indeed... Spare no expense, cost no object. Splendid build quality. The CCD is a thing of beauty! 1 Reply @YSoreil 1 day ago The pricing on that sensor is about right, I looked in to these many years ago when they were still in production since it's the only large sensor you could actually buy. Really cool to see one in the wild. 2 Reply @snik2pl 1 day ago That leds look like from led projector Reply @vincei4252 1 day ago TDI = Time Domain Integration ? 1 Reply @wolpumba4099 1 day ago (edited) Maybe the camera should not be illuminated during readout. From the datasheet of the sensor (Onsemi): saturation 40300 electrons, read noise 12.5 electrons per pixel @ 18MHz (quite bad). quantum efficiency 62% (if it has micro lenses), frame rate 1 Hz. lateral overflow drain to prevent blooming protects against 800x (factor increases linearly with exposure time) saturation exposure (32e6 electrons per pixel at 4ms exposure time), microlens has +/- 20 degree acceptance angle i guess it would be good for astrophotography 4 Reply @txm100 1 day ago (edited) Babe wake up a new mikeselectricstuff has dropped! 9 Reply @vincei4252 1 day ago That looks like a finger-lakes filter wheel, however, for astronomy they'd never use such a large stepper. 1 Reply @MRooodddvvv 1 day ago yaaaaay ! more overcomplicated optical stuff ! 4 Reply 1 reply @NoPegs 1 day ago He lives! 11 Reply 1 reply Transcript 0:00 so I've stripped all the bits of the 0:01 optical system so basically we've got 0:03 the uh the camera 0:05 itself which is mounted on this uh very 0:09 complex 0:10 adjustment thing which obviously to set 0:13 you the various tilt and uh alignment 0:15 stuff then there's two of these massive 0:18 lenses I've taken one of these apart I 0:20 think there's something like about eight 0:22 or nine Optical elements in here these 0:25 don't seem to do a great deal in terms 0:26 of electr magnification they're obiously 0:28 just about getting the image to where it 0:29 uh where it needs to be just so that 0:33 goes like that then this Optical block I 0:36 originally thought this was made of some 0:37 s crazy heavy material but it's just 0:39 really the sum of all these Optical bits 0:41 are just ridiculously heavy those lenses 0:43 are about 4 kilos each and then there's 0:45 this very heavy very solid um piece that 0:47 goes in the middle and this is so this 0:49 is the filter wheel assembly with a 0:51 hilariously oversized steper 0:53 motor driving this wheel with these very 0:57 large narrow band filters so we've got 1:00 various different shades of uh 1:03 filters there five Al together that 1:06 one's actually just showing up a silver 1:07 that's actually a a red but fairly low 1:10 transmission orangey red blue green 1:15 there's an excess cover on this side so 1:16 the filters can be accessed and changed 1:19 without taking anything else apart even 1:21 this is like ridiculous it's like solid 1:23 aluminium this is just basically a cover 1:25 the actual wavelengths of these are um 1:27 488 525 570 630 and 700 NM not sure what 1:32 the suffix on that perhaps that's the uh 1:34 the width of the spectral line say these 1:37 are very narrow band filters most of 1:39 them are you very little light through 1:41 so it's still very tight narrow band to 1:43 match the um fluoresence of the dies 1:45 they're using in the biochemical process 1:48 and obviously to reject the light that's 1:49 being fired at it from that Illuminator 1:51 box and then there's a there's a second 1:53 one of these lenses then the actual sort 1:55 of samples below that so uh very serious 1:58 amount of very uh chunky heavy Optics 2:01 okay let's take a look at this light 2:02 source made by company Lumen Dynamics 2:04 who are now part of 2:06 excelitas self-contained unit power 2:08 connector USB and this which one of the 2:11 Cable Bundle said was a TTL interface 2:14 USB wasn't used in uh the fluid 2:17 application output here and I think this 2:19 is an input for um light feedback I 2:21 don't if it's regulated or just a measur 2:23 measurement facility and the uh fiber 2:27 assembly 2:29 Square Inlet there and then there's two 2:32 outputs which have uh lens assemblies 2:35 and this small one which goes back into 2:37 that small Port just Loops out of here 2:40 straight back in So on this side we've 2:42 got the electronics which look pretty 2:44 straightforward we've got a bit of power 2:45 supply stuff over here and we've got 2:48 separate drivers for each wavelength now 2:50 interesting this is clearly been very 2:52 specifically made for this application 2:54 you I was half expecting like say some 2:56 generic drivers that could be used for a 2:58 number of different things but actually 3:00 literally specified the exact wavelength 3:02 on the PCB there is provision here for 3:04 385 NM which isn't populated but this is 3:07 clearly been designed very specifically 3:09 so these four drivers look the same but 3:10 then there's two higher power ones for 3:12 575 and 3:14 520 a slightly bigger heat sink on this 3:16 575 section there a p 24 which is 3:20 providing USB interface USB isolator the 3:23 USB interface just presents as a comport 3:26 I did have a quick look but I didn't 3:27 actually get anything sensible um I did 3:29 dump the Pi code out and there's a few 3:31 you a few sort of commands that you 3:32 could see in text but I didn't actually 3:34 manage to get it working properly I 3:36 found some software for related version 3:38 but it didn't seem to want to talk to it 3:39 but um I say that wasn't used for the 3:41 original application it might be quite 3:42 interesting to get try and get the Run 3:44 hours count out of it and the TTL 3:46 interface looks fairly straightforward 3:48 we've got positions for six opto 3:50 isolators but only five five are 3:52 installed so that corresponds with the 3:54 unused thing so I think this hopefully 3:56 should be as simple as just providing a 3:57 ttrl signal for each color to uh enable 4:00 it a big heat sink here which is there I 4:03 think there's like a big S of metal 4:04 plate through the middle of this that 4:05 all the leads are mounted on the other 4:07 side so this is heat sinking it with a 4:09 air flow from a uh just a fan in here 4:13 obviously don't have the air flow 4:14 anywhere near the Optics so conduction 4:17 cool through to this plate that's then 4:18 uh air cooled got some pots which are 4:21 presumably power 4:22 adjustments okay let's take a look at 4:24 the other side which is uh much more 4:27 interesting see we've got some uh very 4:31 uh neatly Twisted cable assemblies there 4:35 a bunch of leads so we've got one here 4:37 475 up here 430 NM 630 575 and 520 4:44 filters and dcro mirrors a quick way to 4:48 see what's white is if we just shine 4:49 some white light through 4:51 here not sure how it is is to see on the 4:54 camera but shining white light we do 4:55 actually get a bit of red a bit of blue 4:57 some yellow here so the obstacle path 5:00 575 it goes sort of here bounces off 5:03 this mirror and goes out the 520 goes 5:07 sort of down here across here and up 5:09 there 630 goes basically straight 5:13 through 5:15 430 goes across there down there along 5:17 there and the 475 goes down here and 5:20 left this is the light sensing thing 5:22 think here there's just a um I think 5:24 there a photo diode or other sensor 5:26 haven't actually taken that off and 5:28 everything's fixed down to this chunk of 5:31 aluminium which acts as the heat 5:32 spreader that then conducts the heat to 5:33 the back side for the heat 5:35 sink and the actual lead packages all 5:38 look fairly similar except for this one 5:41 on the 575 which looks quite a bit more 5:44 substantial big spay 5:46 Terminals and the interface for this 5:48 turned out to be extremely simple it's 5:50 literally a 5V TTL level to enable each 5:54 color doesn't seem to be any tensity 5:56 control but there are some additional 5:58 pins on that connector that weren't used 5:59 in the through time thing so maybe 6:01 there's some extra lines that control 6:02 that I couldn't find any data on this uh 6:05 unit and the um their current product 6:07 range is quite significantly different 6:09 so we've got the uh blue these 6:13 might may well be saturating the camera 6:16 so they might look a bit weird so that's 6:17 the 430 6:18 blue the 575 6:24 yellow uh 6:26 475 light blue 6:29 the uh 520 6:31 green and the uh 630 red now one 6:36 interesting thing I noticed for the 6:39 575 it's actually it's actually using a 6:42 white lead and then filtering it rather 6:44 than using all the other ones are using 6:46 leads which are the fundamental colors 6:47 but uh this is actually doing white and 6:50 it's a combination of this filter and 6:52 the dichroic mirrors that are turning to 6:55 Yellow if we take the filter out and a 6:57 lot of the a lot of the um blue content 7:00 is going this way the red is going 7:02 straight through these two mirrors so 7:05 this is clearly not reflecting much of 7:08 that so we end up with the yellow coming 7:10 out of uh out of there which is a fairly 7:14 light yellow color which you don't 7:16 really see from high intensity leads so 7:19 that's clearly why they've used the 7:20 white to uh do this power consumption of 7:23 the white is pretty high so going up to 7:25 about 2 and 1 half amps on that color 7:27 whereas most of the other colors are 7:28 only drawing half an amp or so at 24 7:30 volts the uh the green is up to about 7:32 1.2 but say this thing is uh much 7:35 brighter and if you actually run all the 7:38 colors at the same time you get a fairly 7:41 reasonable um looking white coming out 7:43 of it and one thing you might just be 7:45 out to notice is there is some sort 7:46 color banding around here that's not 7:49 getting uh everything s completely 7:51 concentric and I think that's where this 7:53 fiber optic thing comes 7:58 in I'll 8:00 get a couple of Fairly accurately shaped 8:04 very sort of uniform color and looking 8:06 at What's um inside here we've basically 8:09 just got this Square Rod so this is 8:12 clearly yeah the lights just bouncing 8:13 off all the all the various sides to um 8:16 get a nice uniform illumination uh this 8:19 back bit looks like it's all potted so 8:21 nothing I really do to get in there I 8:24 think this is fiber so I have come 8:26 across um cables like this which are 8:27 liquid fill but just looking through the 8:30 end of this it's probably a bit hard to 8:31 see it does look like there fiber ends 8:34 going going on there and so there's this 8:36 feedback thing which is just obviously 8:39 compensating for the any light losses 8:41 through here to get an accurate 8:43 representation of uh the light that's 8:45 been launched out of these two 8:47 fibers and you see uh 8:49 these have got this sort of trapezium 8:54 shape light guides again it's like a 8:56 sort of acrylic or glass light guide 9:00 guess projected just to make the right 9:03 rectangular 9:04 shape and look at this Center assembly 9:07 um the light output doesn't uh change 9:10 whether you feed this in or not so it's 9:11 clear not doing any internal Clos Loop 9:14 control obviously there may well be some 9:16 facility for it to do that but it's not 9:17 being used in this 9:19 application and so this output just 9:21 produces a voltage on the uh outle 9:24 connector proportional to the amount of 9:26 light that's present so there's a little 9:28 diffuser in the back there 9:30 and then there's just some kind of uh 9:33 Optical sensor looks like a 9:35 chip looking at the lead it's a very 9:37 small package on the PCB with this lens 9:40 assembly over the top and these look 9:43 like they're actually on a copper 9:44 Metalized PCB for maximum thermal 9:47 performance and yeah it's a very small 9:49 package looks like it's a ceramic 9:51 package and there's a thermister there 9:53 for temperature monitoring this is the 9:56 475 blue one this is the 520 need to 9:59 Green which is uh rather different OB 10:02 it's a much bigger D with lots of bond 10:04 wise but also this looks like it's using 10:05 a phosphor if I shine a blue light at it 10:08 lights up green so this is actually a 10:10 phosphor conversion green lead which 10:12 I've I've come across before they want 10:15 that specific wavelength so they may be 10:17 easier to tune a phosphor than tune the 10:20 um semiconductor material to get the uh 10:23 right right wavelength from the lead 10:24 directly uh red 630 similar size to the 10:28 blue one or does seem to have a uh a 10:31 lens on top of it there is a sort of red 10:33 coloring to 10:35 the die but that doesn't appear to be 10:38 fluorescent as far as I can 10:39 tell and the white one again a little 10:41 bit different sort of much higher 10:43 current 10:46 connectors a makeer name on that 10:48 connector flot light not sure if that's 10:52 the connector or the lead 10:54 itself and obviously with the phosphor 10:56 and I'd imagine that phosphor may well 10:58 be tuned to get the maximum to the uh 5 11:01 cenm and actually this white one looks 11:04 like a St fairly standard product I just 11:06 found it in Mouse made by luminous 11:09 devices in fact actually I think all 11:11 these are based on various luminous 11:13 devices modules and they're you take 11:17 looks like they taking the nearest 11:18 wavelength and then just using these 11:19 filters to clean it up to get a precise 11:22 uh spectral line out of it so quite a 11:25 nice neat and um extreme 11:30 bright light source uh sure I've got any 11:33 particular use for it so I think this 11:35 might end up on 11:36 eBay but uh very pretty to look out and 11:40 without the uh risk of burning your eyes 11:43 out like you do with lasers so I thought 11:45 it would be interesting to try and 11:46 figure out the runtime of this things 11:48 like this we usually keep some sort 11:49 record of runtime cuz leads degrade over 11:51 time I couldn't get any software to work 11:52 through the USB face but then had a 11:54 thought probably going to be writing the 11:55 runtime periodically to the e s prom so 11:58 I just just scope up that and noticed it 12:00 was doing right every 5 minutes so I 12:02 just ran it for a while periodically 12:04 reading the E squ I just held the pick 12:05 in in reset and um put clip over to read 12:07 the square prom and found it was writing 12:10 one location per color every 5 minutes 12:12 so if one color was on it would write 12:14 that location every 5 minutes and just 12:16 increment it by one so after doing a few 12:18 tests with different colors of different 12:19 time periods it looked extremely 12:21 straightforward it's like a four bite 12:22 count for each color looking at the 12:24 original data that was in it all the 12:26 colors apart from Green were reading 12:28 zero and the green was reading four 12:30 indicating a total 20 minutes run time 12:32 ever if it was turned on run for a short 12:34 time then turned off that might not have 12:36 been counted but even so indicates this 12:37 thing wasn't used a great deal the whole 12:40 s process of doing a run can be several 12:42 hours but it'll only be doing probably 12:43 the Imaging at the end of that so you 12:46 wouldn't expect to be running for a long 12:47 time but say a single color for 20 12:50 minutes over its whole lifetime does 12:52 seem a little bit on the low side okay 12:55 let's look at the camera un fortunately 12:57 I managed to not record any sound when I 12:58 did this it's also a couple of months 13:00 ago so there's going to be a few details 13:02 that I've forgotten so I'm just going to 13:04 dub this over the original footage so um 13:07 take the lid off see this massive great 13:10 heat sink so this is a pel cool camera 13:12 we've got this blower fan producing a 13:14 fair amount of air flow through 13:16 it the connector here there's the ccds 13:19 mounted on the board on the 13:24 right this unplugs so we've got a bit of 13:27 power supply stuff on here 13:29 USB interface I think that's the Cyprus 13:32 microcontroller High speeded USB 13:34 interface there's a zyink spon fpga some 13:40 RAM and there's a couple of ATD 13:42 converters can't quite read what those 13:45 those are but anal 13:47 devices um little bit of bodgery around 13:51 here extra decoupling obviously they 13:53 have having some noise issues this is 13:55 around the ram chip quite a lot of extra 13:57 capacitors been added there 13:59 uh there's a couple of amplifiers prior 14:01 to the HD converter buffers or Andor 14:05 amplifiers taking the CCD 14:08 signal um bit more power spy stuff here 14:11 this is probably all to do with 14:12 generating the various CCD bias voltages 14:14 they uh need quite a lot of exotic 14:18 voltages next board down is just a 14:20 shield and an interconnect 14:24 boardly shielding the power supply stuff 14:26 from some the more sensitive an log 14:28 stuff 14:31 and this is the bottom board which is 14:32 just all power supply 14:34 stuff as you can see tons of capacitors 14:37 or Transformer in 14:42 there and this is the CCD which is a uh 14:47 very impressive thing this is a kf50 100 14:50 originally by true sense then codec 14:53 there ON 14:54 Semiconductor it's 50 megapixels uh the 14:58 only price I could find was this one 15:00 5,000 bucks and the architecture you can 15:03 see there actually two separate halves 15:04 which explains the Dual AZ converters 15:06 and two amplifiers it's literally split 15:08 down the middle and duplicated so it's 15:10 outputting two streams in parallel just 15:13 to keep the bandwidth sensible and it's 15:15 got this amazing um diffraction effects 15:18 it's got micro lenses over the pixel so 15:20 there's there's a bit more Optics going 15:22 on than on a normal 15:25 sensor few more bodges on the CCD board 15:28 including this wire which isn't really 15:29 tacked down very well which is a bit uh 15:32 bit of a mess quite a few bits around 15:34 this board where they've uh tacked 15:36 various bits on which is not super 15:38 impressive looks like CCD drivers on the 15:40 left with those 3 ohm um damping 15:43 resistors on the 15:47 output get a few more little bodges 15:50 around here some of 15:52 the and there's this separator the 15:54 silica gel to keep the moisture down but 15:56 there's this separator that actually 15:58 appears to be cut from piece of 15:59 antistatic 16:04 bag and this sort of thermal block on 16:06 top of this stack of three pel Cola 16:12 modules so as with any Stacks they get 16:16 um larger as they go back towards the 16:18 heat sink because each P's got to not 16:20 only take the heat from the previous but 16:21 also the waste heat which is quite 16:27 significant you see a little temperature 16:29 sensor here that copper block which 16:32 makes contact with the back of the 16:37 CCD and this's the back of the 16:40 pelas this then contacts the heat sink 16:44 on the uh rear there a few thermal pads 16:46 as well for some of the other power 16:47 components on this 16:51 PCB okay I've connected this uh camera 16:54 up I found some drivers on the disc that 16:56 seem to work under Windows 7 couldn't 16:58 get to install under Windows 11 though 17:01 um in the absence of any sort of lens or 17:03 being bothered to the proper amount I've 17:04 just put some f over it and put a little 17:06 pin in there to make a pinhole lens and 17:08 software gives a few options I'm not 17:11 entirely sure what all these are there's 17:12 obviously a clock frequency 22 MHz low 17:15 gain and with PFG no idea what that is 17:19 something something game programmable 17:20 Something game perhaps ver exposure 17:23 types I think focus is just like a 17:25 continuous grab until you tell it to 17:27 stop not entirely sure all these options 17:30 are obviously exposure time uh triggers 17:33 there ex external hardware trigger inut 17:35 you just trigger using a um thing on 17:37 screen so the resolution is 8176 by 17:40 6132 and you can actually bin those 17:42 where you combine multiple pixels to get 17:46 increased gain at the expense of lower 17:48 resolution down this is a 10sec exposure 17:51 obviously of the pin hole it's very uh 17:53 intensitive so we just stand still now 17:56 downloading it there's the uh exposure 17:59 so when it's 18:01 um there's a little status thing down 18:03 here so that tells you the um exposure 18:07 [Applause] 18:09 time it's this is just it 18:15 downloading um it is quite I'm seeing 18:18 quite a lot like smearing I think that I 18:20 don't know whether that's just due to 18:21 pixels overloading or something else I 18:24 mean yeah it's not it's not um out of 18:26 the question that there's something not 18:27 totally right about this camera 18:28 certainly was bodge wise on there um I 18:31 don't I'd imagine a camera like this 18:32 it's got a fairly narrow range of 18:34 intensities that it's happy with I'm not 18:36 going to spend a great deal of time on 18:38 this if you're interested in this camera 18:40 maybe for astronomy or something and 18:42 happy to sort of take the risk of it may 18:44 not be uh perfect I'll um I think I'll 18:47 stick this on eBay along with the 18:48 Illuminator I'll put a link down in the 18:50 description to the listing take your 18:52 chances to grab a bargain so for example 18:54 here we see this vertical streaking so 18:56 I'm not sure how normal that is this is 18:58 on fairly bright scene looking out the 19:02 window if I cut the exposure time down 19:04 on that it's now 1 second 19:07 exposure again most of the image 19:09 disappears again this is looks like it's 19:11 possibly over still overloading here go 19:14 that go down to say say quarter a 19:16 second so again I think there might be 19:19 some Auto gain control going on here um 19:21 this is with the PFG option let's try 19:23 turning that off and see what 19:25 happens so I'm not sure this is actually 19:27 more streaking or which just it's 19:29 cranked up the gain all the dis display 19:31 gray scale to show what um you know the 19:33 range of things that it's captured 19:36 there's one of one of 12 things in the 19:38 software there's um you can see of you 19:40 can't seem to read out the temperature 19:42 of the pelta cooler but you can set the 19:44 temperature and if you said it's a 19:46 different temperature you see the power 19:48 consumption jump up running the cooler 19:50 to get the temperature you requested but 19:52 I can't see anything anywhere that tells 19:54 you whether the cool is at the at the 19:56 temperature other than the power 19:57 consumption going down and there's no 19:59 temperature read out 20:03 here and just some yeah this is just 20:05 sort of very basic software I'm sure 20:07 there's like an API for more 20:09 sophisticated 20:10 applications but so if you know anything 20:12 more about these cameras please um stick 20:14 in the 20:15 comments um incidentally when I was 20:18 editing I didn't notice there was a bent 20:19 pin on the um CCD but I did fix that 20:22 before doing these tests and also 20:24 reactivated the um silica gel desicant 20:26 cuz I noticed it was uh I was getting 20:28 bit of condensation on the window but um 20:31 yeah so a couple of uh interesting but 20:34 maybe not particularly uh useful pieces 20:37 of Kit except for someone that's got a 20:38 very specific use so um I'll stick a 20:42 I'll stick these on eBay put a link in 20:44 the description and say hopefully 20:45 someone could actually make some uh good 20:47 use of these things Example Output: **Abstract:** This video presents Part 2 of a teardown focusing on the optical components of a Fluidigm Polaris biotechnology instrument, specifically the multi-wavelength illuminator and the high-resolution CCD camera. The Lumen Dynamics illuminator unit is examined in detail, revealing its construction using multiple high-power LEDs (430nm, 475nm, 520nm, 575nm, 630nm) combined via dichroic mirrors and filters. A square fiber optic rod is used to homogenize the light. A notable finding is the use of a phosphor-converted white LED filtered to achieve the 575nm output. The unit features simple TTL activation for each color, conduction cooling, and internal homogenization optics. Analysis of its EEPROM suggests extremely low operational runtime. The camera module teardown showcases a 50 Megapixel ON Semiconductor KAF-50100 CCD sensor with micro-lenses, cooled by a multi-stage Peltier stack. The control electronics include an FPGA and a USB interface. Significant post-manufacturing modifications ("bodges") are observed on the camera's circuit boards. Basic functional testing using vendor software and a pinhole lens confirms image capture but reveals prominent vertical streaking artifacts, the cause of which remains uncertain (potential overload, readout artifact, or fault). **Exploring the Fluidigm Polaris: A Detailed Look at its High-End Optics and Camera System** * **0:00 High-End Optics:** The system utilizes heavy, high-quality lenses and mirrors for precise imaging, weighing around 4 kilos each. * **0:49 Narrow Band Filters:** A filter wheel with five narrow band filters (488, 525, 570, 630, and 700 nm) ensures accurate fluorescence detection and rejection of excitation light. * **2:01 Customizable Illumination:** The Lumen Dynamics light source offers five individually controllable LED wavelengths (430, 475, 520, 575, 630 nm) with varying power outputs. The 575nm yellow LED is uniquely achieved using a white LED with filtering. * **3:45 TTL Control:** The light source is controlled via a simple TTL interface, enabling easy on/off switching for each LED color. * **12:55 Sophisticated Camera:** The system includes a 50-megapixel Kodak KAI-50100 CCD camera with a Peltier cooling system for reduced noise. * **14:54 High-Speed Data Transfer:** The camera features dual analog-to-digital converters to manage the high data throughput of the 50-megapixel sensor, which is effectively two 25-megapixel sensors operating in parallel. * **18:11 Possible Issues:** The video creator noted some potential issues with the camera, including image smearing. * **18:11 Limited Dynamic Range:** The camera's sensor has a limited dynamic range, making it potentially challenging to capture scenes with a wide range of brightness levels. * **11:45 Low Runtime:** Internal data suggests the system has seen minimal usage, with only 20 minutes of recorded runtime for the green LED. * **20:38 Availability on eBay:** Both the illuminator and camera are expected to be listed for sale on eBay. Here is the real transcript. Please summarize it: 00:00:05 Sex. It's everywhere you look. It's a 00:00:05 huge part of our culture, but us Brits 00:00:08 tend to be tight lipped when it comes to 00:00:10 opening up about our personal sex lives. 00:00:13 Until now. I ended up masturbating from 00:00:15 like the age of 15. I just thought sex 00:00:18 would solve most issues. It did for a 00:00:20 while until you realize people want way 00:00:22 more than just sex. In this series, 00:00:25 we're tackling the subject head on. I 00:00:27 think pornography had set a lot of 00:00:29 unrealistic expectations for me of what 00:00:32 sex was. Hugh Hefner used to call it 00:00:34 like tits on a stick and I'm not really 00:00:36 built like that. In this episode, we're 00:00:39 confronting the impact that watching 00:00:41 pornography has had on some people's 00:00:43 lives. I used pornography to really 00:00:47 medicate a lot of the emotions that I 00:00:49 had towards my childhood, towards the 00:00:51 pressures that I was feeling at the 00:00:53 time. No matter what I tried to do, I 00:00:55 could not stop watching it. That's when 00:00:57 I knew there was something up. Nothing 00:00:59 is off limits. When I used to watch it 00:01:01 morning, noon, and night pretty much to 00:01:04 the point where um I was just exhausted. 00:01:08 This is sex after porn obsession. 00:01:12 [Music] 00:01:17 From the ancient Egyptians to the 00:01:17 Victorians, from lads mags to online sex 00:01:21 platforms, people have been viewing porn 00:01:23 for centuries. It's nothing new, but 00:01:26 technology means that porn is now more 00:01:29 accessible than ever. Research by UK 00:01:32 addiction treatment centers suggest that 00:01:34 8.8 million adults could be watching 00:01:37 porn on a weekly basis. 00:01:40 These people might look very different, 00:01:42 but they all have one thing in common. 00:01:44 They all started watching porn from a 00:01:46 young age. We've brought them together 00:01:48 to discuss how their porn viewing habits 00:01:50 developed and how it's impacted their 00:01:52 relationships. So tell us more about 00:01:54 your childhood in North Carolina. It's 00:01:57 interesting I guess because like America 00:01:59 and the South in general is very like 00:02:01 religious and I grew up in like a very 00:02:03 religious 00:02:05 sort of like area and that kind of 00:02:07 upbringing. So that's kind of like what 00:02:10 brought me around to like finding porn 00:02:12 and stuff like that was because I was 00:02:13 just taught like abstinence and stuff. 00:02:16 So that's kind of what brought me into 00:02:18 it. It was a Baptist church. My uncle 00:02:21 was the youth pastor there. It was very, 00:02:25 you know, women have their sort of role. 00:02:27 I didn't really grow up necessarily like 00:02:29 looking forward to my life. It was like 00:02:32 growing up looking forward to my 00:02:33 wedding. And I never really wanted to 00:02:36 get married. So, I didn't really know 00:02:37 what else was for me. Um, but it was 00:02:40 very much like very strict gender gender 00:02:44 roles that we were sort of expected to 00:02:46 live up to. I wasn't raised in like a 00:02:50 really strictly religious environment. 00:02:52 Um, but similarly, I guess culturally, 00:02:54 you don't really talk about sex like in 00:02:57 church with your family. You don't 00:02:58 really do that. My parents are Ghanian. 00:03:00 They are very traditional, very 00:03:02 cultural. Um, and it's quite a 00:03:04 conservative culture as well, so you 00:03:05 don't really talk about sex and things 00:03:07 like that. So, liking boys was something 00:03:09 that was kind of like you're feeling it, 00:03:11 but you don't really talk about it. You 00:03:13 definitely don't talk to your parents 00:03:14 about it. I am a child of West African 00:03:18 immigrants, Ghanian immigrants. So you 00:03:19 don't really talk about mom, I have a 00:03:21 crush on a boy at 11. Read your books 00:03:24 basically would be the answer. Life for 00:03:26 me was quite interesting. So my father 00:03:29 died on Christmas day when I was 6 years 00:03:31 old. And I think I never understood what 00:03:34 the loss did for my life at the time. So 00:03:37 when I hit puberty, I didn't understand 00:03:39 the things that were happening within my 00:03:40 body. I started to have a lot of 00:03:41 questions for sure. I think as any young 00:03:43 boy does, the changes that were 00:03:45 happening in my body, um the girls that 00:03:48 I liked at the time or just what it 00:03:50 meant to be a a boy slash becoming a man 00:03:54 coming of age in some ways. I went to an 00:03:57 all boy school, so you could only 00:03:58 imagine what it was like. Um I'll never 00:04:00 forget one of our old one of the guys in 00:04:03 my class actually he um showed us porn 00:04:05 on you know PSP. Yeah. downloaded it 00:04:07 onto it and I remember we were watching 00:04:09 in the back of class and I think we were 00:04:11 just all quite fascinated but a lot of 00:04:13 the boys were having sex way before me 00:04:15 anyway. Oh wow. So I was pretty much 00:04:17 quite a late bloomer. I was quite a shy 00:04:19 introverted kid. And I remember 00:04:22 for years it was um I used to watch on 00:04:24 my computer made sure before my mom got 00:04:26 home wiped the internet history. 00:04:31 And this law aren't alone. In a world 00:04:33 where it's increasingly available, some 00:04:35 kids have seen porn at younger ages than 00:04:38 you might expect. On average, children 00:04:41 first see pornography aged 13, according 00:04:43 to research. And one in 10 of those 00:04:46 surveyed have seen porn by the age of 00:04:49 nine. I was 11 years old when I first 00:04:51 started watching porn. I was introduced 00:04:53 to it by a friend of mine I used to walk 00:04:55 to school with every single morning and 00:04:58 it was fascinating. I was almost hooked 00:05:00 immediately to this idea or the sounds 00:05:03 that people sound like they're just 00:05:05 having fun. It looks like, wow, what is 00:05:06 this that people are doing where they 00:05:08 look like they're just having a time of 00:05:09 their lives? So, I first started 00:05:11 watching pornography when I was around 9 00:05:13 or 10. I was still in primary school. 00:05:15 So, it started off being like maybe on 00:05:18 the weekends or sometimes before school 00:05:21 and then it turned into almost every day 00:05:24 like in summertimes. And that was when I 00:05:28 started to realize this is having a 00:05:29 negative effect on me because I'm doing 00:05:31 this way too often. Like way too often. 00:05:34 And I would say that realization really 00:05:36 came when I was about 13 14 where I was 00:05:39 like, "Oh, this doesn't feel like 00:05:41 exploration anymore. This feels like 00:05:43 dependency." I think for me it was just 00:05:45 like more casual like exploration. I 00:05:49 didn't like have any certain like go-to 00:05:52 things. I was just like curious what 00:05:55 people was doing and the more weird 00:05:57 stuff you find the more weird stuff you 00:05:58 find. Absolutely. So it was kind of like 00:06:00 that. Um but I sort of like dipped in 00:06:03 and out. I was probably starting to 00:06:05 question things at the age of like 12, 00:06:07 13 and really starting to look more into 00:06:11 what actually was sex. Obviously, we 00:06:13 know what porn is now, but even at that 00:06:15 time, I think it was like a little bit 00:06:17 different. And I think the beauty 00:06:19 standards 00:06:21 were very specific about thinness. It's 00:06:24 like I think Hugh Hefner used to call it 00:06:25 like tits on a stick. And I'm not really 00:06:28 built like that. And so it was a lot of 00:06:31 comparison and that kind of stuff, but 00:06:33 then it was all it's all a performance, 00:06:34 but you don't know that. Then porn 00:06:37 distorts your image of sex, of women, of 00:06:40 real life relationships. So, I think I 00:06:42 became very complacent. I just thought 00:06:44 sex would solve most issues. It did for 00:06:47 a while until you realize people want 00:06:49 way more than just sex. It's not enough 00:06:51 to sustain a relationship. I didn't have 00:06:54 my first like sexual experience, well, 00:06:56 proper sexual experience until I was 00:06:58 about 14, 15, and then I like lost my 00:07:01 virginity when I was 18. And that like 00:07:03 losing my virginity your first time 00:07:05 that's like so romanticized was so 00:07:07 terrible, like so so disappointing. 00:07:12 It never felt like real life matched up 00:07:14 to the height that I got or the 00:07:16 satisfaction that I got from watching 00:07:18 pornography or masturbating. I think 00:07:21 pornography had set a lot of unrealistic 00:07:23 expectations for me of what sex was. And 00:07:27 it didn't live up to the fantasy I'd 00:07:30 created in my mind. My first time's 00:07:31 going to be like this and it's going to 00:07:33 feel like this and I'm going to be 00:07:34 screaming like this and I'm going to be 00:07:36 flipping like it was nothing like that. 00:07:39 Like over half of the young people who 00:07:42 responded to a survey agree that viewing 00:07:45 online pornography could affect 00:07:48 behavior. The research correlates porn 00:07:50 use with the potential for real life 00:07:52 aggression and coercion. When the 00:07:55 research was published, the children's 00:07:56 commissioner for England said that she 00:07:58 was deeply concerned about sexual 00:08:00 violence in porn. So did you think it 00:08:03 was real too then? Like cuz when I first 00:08:05 find found porn you're like a kid like 00:08:08 this is what it is. answers the 00:08:09 question. This is what everyone is 00:08:11 doing. This is the thing. Yes. Yes. Yes. 00:08:13 Yeah. And I think when you're a young 00:08:14 mind, that's just what you think. You 00:08:16 think you're very impressionable. Yeah. 00:08:18 And you just think this it, like you 00:08:20 said, this is what it is. And then you 00:08:22 get older and you're like, no, it's not 00:08:24 like it's not as perfectly lit. It's not 00:08:26 as cute. It's not as seamless. It's not 00:08:29 as neat. It's he's not going to last for 00:08:31 so long. He's not going to last for so 00:08:33 long. I 00:08:36 expected sex to not be about me that I 00:08:40 expected it to be about like my partner, 00:08:42 probably like a man. I didn't expect it 00:08:45 to feel good. You know, porn doesn't end 00:08:48 in a female orgasm. It ends in a male 00:08:50 orgasm. And I just was like, "Oh, well, 00:08:55 that's what it is." It I think it did 00:08:57 play out in my first sexual experience 00:08:58 because I wasn't there. I wasn't 00:09:02 enjoying it. I was worried about what I 00:09:05 look like, what I was supposed to be 00:09:07 doing, and am I any good cuz I don't 00:09:11 know. And then it just I just felt 00:09:13 really sad and sort of empty that I I 00:09:16 must have missed something, but I didn't 00:09:17 know what I had missed. One thing I 00:09:19 don't know whether you found this, but 00:09:21 when you watch porn for such a long 00:09:23 time, it's hard to be present. Sometimes 00:09:25 your mind can just start escaping into 00:09:27 other things, and you really have to 00:09:28 teach your brain to come back into the 00:09:30 moment. When I was watching it, as I 00:09:33 watching porn throughout for the whole 00:09:35 day, I realized there was an issue and I 00:09:37 had no energy to do anything. I didn't 00:09:40 want to play football and I just wanted 00:09:41 to be inside and but there was the guilt 00:09:43 and the shame that came with it. And no 00:09:45 matter what I wanted to do or no matter 00:09:47 what I tried to do, I could not stop 00:09:49 watching it. That's when I knew there 00:09:50 was something up. I knew there was 00:09:52 something up when I kept chasing this 00:09:54 constant high over and over and over 00:09:57 again. But as I became older, I 00:09:58 realized, wait, there's something 00:10:01 actually wrong here. It's almost in some 00:10:04 if in some ways it felt like it was 00:10:05 beyond my control. I used pornography to 00:10:10 really medicate a lot of the emotions 00:10:12 that I had towards my childhood, towards 00:10:14 the pressures that I was feeling at the 00:10:15 time, social pressures, educational 00:10:18 pressures, familial pressures. I had a 00:10:20 conversation with a friend actually who 00:10:22 was like, you know, masturbation is 00:10:24 actually really good for you. Like 00:10:25 orgasms are good. they relieve a lot of 00:10:27 stress. And so that was then my entry 00:10:30 point into, okay, cool. I need something 00:10:31 to relieve that stress. And I ended up 00:10:34 masturbating from like the ages of 15. 00:10:37 If you're looking for sexual 00:10:38 empowerment, which I think every person, 00:10:40 especially women, need to have where you 00:10:42 can say, "This is what I like. This is 00:10:44 what I want. This is how I want to be 00:10:45 satisfied. I do actually want to 00:10:47 experience sexual pleasure." I don't 00:10:49 think that education and that power 00:10:52 completely comes from pornography. And I 00:10:55 think sometimes it's sold sold to us 00:10:57 that way. I used to watch it morning, 00:11:00 noon, and night pretty much to the point 00:11:02 where um I was just exhausted as you 00:11:05 could imagine why. Yeah. Yeah. But yeah, 00:11:08 that's when I realized it was actually 00:11:10 an addiction. But also when I spoke to 00:11:12 my friends about it, we all spoke about 00:11:14 how we wanted to quit. Not everyone who 00:11:16 uses porn habitually would describe 00:11:18 themselves as addicted. And porn 00:11:21 addiction is not officially recognized 00:11:22 as a formal diagnosis. Some mental 00:11:25 health practitioners treat problematic 00:11:27 porn use as a compulsive sexual behavior 00:11:29 disorder. I always say the opposite of 00:11:32 addiction is connection. Yeah, that is 00:11:34 so good. I'm going to steal that. I 00:11:36 don't know that I was necessarily 00:11:38 necessarily like ever addicted to 00:11:40 pornography. I don't know if I would 00:11:42 ever say that cuz I just have sort of 00:11:43 like dipped in and out and dribbs and 00:11:45 drobs throughout my life. So, and I can 00:11:47 see that I'm doing this stuff and then 00:11:48 sort of pull myself out of it. And it it 00:11:51 really is just as simple as like sharing 00:11:53 it a lot of the time, isn't it? And just 00:11:55 like letting somebody know because then 00:11:57 it just takes the shame and the self 00:11:59 judgment right out of it. Cuz I think a 00:12:01 lot of it actually is the shame and the 00:12:03 secrecy and oh my gosh, no one else does 00:12:05 this. This is so embarrassing. What are 00:12:06 people going to think of me? No one 00:12:07 would ever think that I would do 00:12:09 something like this. And so it was just 00:12:11 I turned to my best friend and was like, 00:12:13 you know, got a confession. like I watch 00:12:16 pornography. I really want to stop. And 00:12:18 it opened up this whole kind of worms 00:12:20 with different people around like, oh my 00:12:21 gosh, me too. And sometime and I was 00:12:23 like, wait, we all have the same secret. 00:12:25 That's crazy. I realized I had an 00:12:28 addiction when I got to university and I 00:12:30 tried to take a step back from 00:12:31 pornography. I realized that this wasn't 00:12:34 something that I wanted to do anymore, 00:12:36 that it had become an unhealthy 00:12:38 dependency. And I always tell people if 00:12:41 you want to know whether porn is just 00:12:43 something you do for recreational time 00:12:45 or whether you are you have an unhealthy 00:12:47 dependency on it, try to stop. I would 00:12:49 always find myself fighting like there 00:12:51 was this internal battle, internal 00:12:53 conflict around whether I could actually 00:12:56 stop and whether I wanted to. And it 00:12:58 would literally just leave me feeling so 00:13:01 powerless. For me personally, I stopped 00:13:04 watching pornography 00:13:06 um when I was about 19, 20. And then 00:13:09 yeah, ended up just going on like an 00:13:11 abstinence journey and was just like I 00:13:13 need to really reframe how I see sex. We 00:13:16 all can start to think that when you 00:13:19 watch pornography so much, you can start 00:13:21 to think that like sex is just this need 00:13:23 that always needs to be satisfied. This 00:13:25 your sexual desire and that urge is what 00:13:28 you were saying about the surfing the 00:13:30 urge or urge surfing. Some people say 00:13:32 you're not horny. You're just you need 00:13:33 you need a hug. Yeah. Yeah. Or like you 00:13:36 just need some other kind of dopamine 00:13:38 kick. Like go to the gym, go for a run, 00:13:40 go and talk to people. But then when you 00:13:41 go to the gym, you get more horny. 00:13:49 Interest in voluntary or intentional 00:13:49 celibacy, which is when you choose to 00:13:51 abstain from sex, could be on the rise. 00:13:53 The celibacy hashtag has gained more 00:13:55 than 195 million views and counting on 00:13:58 Tik Tok. Sex is great. It really is. And 00:14:02 it's special. And for me, I have to 00:14:05 redefine what it actually means to me. I 00:14:08 actually wanted to be safe. I wanted to 00:14:12 feel seen. I wanted to feel loved. I 00:14:16 wanted to be with someone who I could do 00:14:19 that learning with, right? Because I was 00:14:22 not a porn star and I wasn't expecting 00:14:25 to be with one. I wanted to be with 00:14:27 someone who was okay with that. And it 00:14:29 wasn't just about the sex, it was 00:14:30 actually about the intimacy. And I 00:14:32 realized that you can't really cultivate 00:14:34 that relationship with every single 00:14:36 person. And so I was just like, you know 00:14:37 what? In order to no longer see men as 00:14:39 objects or people as sexual objects when 00:14:42 we first start dating or first start 00:14:44 talking. And so I just decided to take 00:14:47 sex off the table. How has porn 00:14:49 obsession affected this lot when it 00:14:52 comes to their relationships? I think 00:14:54 the lie that we've been fed is that if 00:14:56 you have great sexual connection, you 00:14:58 have most of what's needed in a 00:15:00 relationship to make a relationship 00:15:01 work, which actually is not true. Like 00:15:03 you just described, relationships are so 00:15:05 much more than just sex. It's especially 00:15:07 if you're talking about long-term 00:15:08 relationships. I personally would forgo 00:15:12 sex for a great connection. And when I 00:15:15 was younger, of course, I wouldn't say 00:15:16 that, but I've realized if the sex 00:15:18 becomes great, fantastic. If it doesn't, 00:15:20 then I kind of can look past it. the 00:15:22 person that I'm with I want to be with 00:15:24 for the rest of my life. Then personally 00:15:26 I could look past it. But it's also 00:15:28 because I understand as you get older 00:15:29 your priorities change. I think now I've 00:15:31 got a far more realistic view on 00:15:33 relationships. Personally for me I think 00:15:35 it's a great filtering process and I 00:15:37 think it has led to more fulfilling 00:15:40 connecting relationships in general. Um 00:15:42 and it has meant that sex for me has not 00:15:46 been the bedrock of this entire 00:15:48 relationship. Like we actually have to 00:15:50 connect as people. Do I even like you? 00:15:52 Do I like the way you deal with 00:15:53 situations? Is there like a friendship 00:15:54 here before there is a sexual 00:15:56 connection? 00:15:58 Looking back, the impact that porn and 00:16:01 masturbation had on my relationships was 00:16:04 there was a fear of commitment. Um, for 00:16:06 sure. And I felt 00:16:10 as if whatever I wanted, I could get 00:16:12 where I could pick somebody up and drop 00:16:14 them whenever I wanted. I was 00:16:16 prolifically cheating for sure. And I 00:16:19 had no remorse. I did not care. How 00:16:23 about you? How do you feel like 00:16:24 pornography affected your sex life? 00:16:26 Well, I had some sort of like other 00:16:28 things going on in my life with like 00:16:30 addiction and my mom got really sick 00:16:32 when I was really young. So, there was 00:16:34 like loads of other kind of contributing 00:16:36 factors, but I ended up getting into 00:16:38 relationships with like typically older 00:16:40 men who were typically not very nice. 00:16:44 And it was just me replaying this 00:16:47 dynamic that I was really used to and 00:16:49 familiar with. Like almost like what you 00:16:51 were saying, you just get comfortable 00:16:53 like and and so and I was comfortable 00:16:59 just performing, doing whatever I felt 00:17:02 like I was kind of like supposed to do. 00:17:04 And it took me like a long time to 00:17:07 realize that it was supposed to be like 00:17:10 mutual. 00:17:12 Do you know what I mean? like I couldn't 00:17:14 even really get there in my head for a 00:17:16 really long time. I don't think I had 00:17:18 the revelation that sex could be good 00:17:21 for me as well until 00:17:24 probably after yet another relationship 00:17:26 and then divorce in my 30s. 00:17:29 And then I was like, okay, 00:17:32 maybe I can enjoy this too. Maybe this 00:17:35 can be for me. and maybe I can try to 00:17:37 let go finally of some of this like very 00:17:41 internalized shame about the whole 00:17:44 thing. So, is it possible to have a 00:17:46 healthy relationship with porn? One 00:17:49 study by the University of Montreal 00:17:51 indicates that certain groups of young 00:17:53 adults who took part in the research 00:17:56 reported improved sexual satisfaction 00:17:58 when using romantic pornography. Then I 00:18:01 did turn to porn again as a way to help 00:18:05 me 00:18:07 discover that part of myself, but I did 00:18:09 it in a very different way than what I 00:18:12 did the first time. I watched like um 00:18:15 sex toy reviews to kind of get an idea 00:18:17 of like, okay, what are other women like 00:18:20 looking for and like toys and what do 00:18:22 they like? And I found audio porn, which 00:18:26 I found so 00:18:29 interesting and so helpful because 00:18:32 nothing was being depicted to me. It 00:18:36 gave me a chance to allow myself to go 00:18:40 into that headsp space and to just 00:18:42 think. 00:18:45 CeCe, Sha and Courtney have really 00:18:48 opened up about a topic that must be 00:18:50 difficult and they're living proof that 00:18:52 there is life and even sex after porn 00:18:55 obsession. Giving up porn is probably 00:18:57 one of the best decisions I've ever 00:18:58 made. The addiction made me lose 00:19:01 connections and now I'm trying to be 00:19:03 connected to people that I generally 00:19:05 love and I really care about. I can't 00:19:08 speak for other people, but for me, porn 00:19:12 definitely the negatives far outweigh 00:19:13 the pros. Having those conversations 00:19:16 more openly will allow people to realize 00:19:18 one, I'm not the only person. So, I 00:19:20 don't need to be feeling this like guilt 00:19:22 and like need to really hide this thing 00:19:25 because I'm actually not the only one 00:19:26 who watches pornography or does this 00:19:28 thing. Um, but also it allows them to 00:19:30 actually start talking about why and 00:19:33 start talking about what they may need 00:19:34 and how they feel towards it as well. 00:19:36 Because there are some people who are 00:19:38 like, "Yeah, I watch pornography. I 00:19:39 actually really enjoy it. It's great." 00:19:40 And then there are some people who are 00:19:41 like, "I watch it, but I don't want to 00:19:43 watch it anymore." and then you actually 00:19:44 start to get people the help or the 00:19:46 support that they may actually need. I 00:19:48 would say if people are really 00:19:50 struggling with porn, find something 00:19:52 bigger than yourself that allows you to 00:19:53 stop. If you really care about your 00:19:55 partner, your kids, or whoever it might 00:19:57 be, if you want to change your life, 00:20:00 change it. If you've been affected by 00:20:03 some of the issues raised in this film, 00:20:05 details of help and support are 00:20:07 available at bbc.co.uk/actionline. 00:20:15 Hey, hey, hey.
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*Abstract:* This video captures a live stream event centered on the first images and operational launch of the Vera C. Rubin Observatory. The host provides an engaging pre-announcement discussion and conducts a Q&A, complementing the official announcements from National Science Foundation (NSF) and Department of Energy (DOE) representatives. The core of the event details the Rubin Observatory's groundbreaking design, featuring the 3.2-gigapixel LSST Camera and an exceptionally agile telescope. Its primary scientific objectives, which include mapping dark matter and dark energy through weak gravitational lensing, discovering millions of asteroids for planetary defense, identifying supernovae, and charting variable stars, are highlighted. The stream underscores the observatory's unprecedented speed, immense data volume (tens of terabytes nightly), and commitment to public accessibility through citizen science initiatives. Initial image releases, particularly of the Virgo cluster, demonstrate astounding detail and have already led to the immediate discovery of thousands of new asteroids, signifying the observatory's transformative potential for astrophysics. *Exploring the Vera C. Rubin Observatory: First Images and Transformative Science* * *0:11:54 - Major Observatory Announcement:* The live stream centers around an anticipated "huge announcement" from the National Science Foundation (NSF) and the Vera C. Rubin Observatory regarding its first images. * *0:13:31 - Transformative Mission:* The host emphasizes the observatory's upcoming decade-long mission as potentially one of the most important in recent years, capable of producing high-quality images and vast amounts of data. * *0:15:13 - 20-Year Development & Scale:* The Vera C. Rubin Observatory project took approximately 20 years to finalize and is described as having one of the world's largest telescopes and the most sensitive camera. * *0:16:31 - Honoring Vera Rubin:* The observatory is named after Vera Rubin, a pioneering astrophysicist who, by observing galactic rotation curves, provided crucial evidence for the existence of dark matter. * *0:18:01 - Prime Location:* Located on El Peñón Peak (2700m/9000ft) in Chile's Atacama desert, the observatory benefits from some of the best, clearest, and driest night skies globally. * *0:22:17 - Wide Field of View:* Unlike most telescopes, Rubin is uniquely designed to combine a wide field of view with high sensitivity, enabling it to scan vast areas of the sky rapidly without laser auto-correction. * *0:24:05 - Core Scientific Pillars:* The observatory's main scientific missions include: * Studying *dark matter* through weak gravitational lensing. * Investigating *dark energy* and the universe's expansion. * Detecting *transient events* like novae and supernovae. * Discovering and tracking millions of *near-Earth asteroids* and comets, critical for planetary defense. * Mapping the distribution of stars and dark matter within the *Milky Way,* complementing missions like Gaia. * *0:40:58 - Immense Data Generation:* The telescope captures an image every 30 seconds, generating 10-20 terabytes of data each night. A single Rubin image is so massive it would require 400 4K HDTVs to display its full detail. * *0:54:18 - LSST Camera - World Record Holder:* The Department of Energy (DOE) led the construction of the LSST Cam, the largest digital camera ever built for astronomy, boasting 3200 megapixels and a Guinness World Record. * *1:10:04 - First Images & Detail:* The initial images, such as a partial view of the Virgo cluster, demonstrate unprecedented detail, revealing countless faint objects never before seen by humans. * *1:21:01 - "Greatest Movie of All Time":* Over its 10-year survey (Legacy Survey of Space and Time - LSST), Rubin will image each of its estimated 40 billion celestial objects approximately 800 times, creating a dynamic, digital color movie of the night sky. * *1:24:52 - Asteroid Detection Prowess:* Early tests from just a few nights of data yielded 2,000 new asteroid discoveries, including 7 near-Earth objects. The project projects finding 5 million new asteroids in the coming years, surpassing all previous discoveries in the last two centuries combined. * *1:27:07 - Variable Star Mapping:* Rubin's ability to precisely detect changes in brightness of variable stars (e.g., RLI stars, Cepheid variables) is crucial for accurately measuring cosmic distances and mapping dark matter distribution. * *1:47:30 - Open Data & Citizen Science:* The immense data will be accessible to researchers via a cloud-based Rubin Science Platform, and to the public through citizen science projects, fostering global participation in astronomical discovery. * *2:02:51 - Anticipated Surprises:* Beyond predicted discoveries like millions of asteroids and precise cosmological measurements, scientists anticipate finding "unknown unknowns," including potentially 10-20 new interstellar objects per year and even Planet 9 (if it exists in the southern sky). * *2:10:41 - Oumuamua and Interstellar Objects:* The discussion touched on the interstellar object Oumuamua, with the humorous remark that if it were to return, it would suggest an artificial origin. Rubin's observations are expected to provide a much larger sample of such objects for statistical study. * *2:46:41 - Visual Superiority:* A visual comparison of the Triffid Nebula strikingly illustrates the new Rubin image's incomparably higher quality and detail compared to previous observations. * *2:51:32 - The Search for Extraterrestrial Life:* While not a primary mission, the host, from a microbiology background, expresses skepticism about widespread alien life due to the biochemical complexity required, though acknowledges if found, it would most likely be on Mars or Jupiter/Saturn's icy moons. I used gemini-2.5-flash-preview-05-20| input-price: 0.15 output-price: 3.5 max-context-length: 128_000 on rocketrecap dot com to summarize the transcript. Cost (if I didn't use the free tier): $0.0164 Input tokens: 78021 Output tokens: 1328
Abstract:
This video captures a live stream event centered on the first images and operational launch of the Vera C. Rubin Observatory. The host provides an engaging pre-announcement discussion and conducts a Q&A, complementing the official announcements from National Science Foundation (NSF) and Department of Energy (DOE) representatives.
The core of the event details the Rubin Observatory's groundbreaking design, featuring the 3.2-gigapixel LSST Camera and an exceptionally agile telescope. Its primary scientific objectives, which include mapping dark matter and dark energy through weak gravitational lensing, discovering millions of asteroids for planetary defense, identifying supernovae, and charting variable stars, are highlighted. The stream underscores the observatory's unprecedented speed, immense data volume (tens of terabytes nightly), and commitment to public accessibility through citizen science initiatives. Initial image releases, particularly of the Virgo cluster, demonstrate astounding detail and have already led to the immediate discovery of thousands of new asteroids, signifying the observatory's transformative potential for astrophysics.
Exploring the Vera C. Rubin Observatory: First Images and Transformative Science
Below, I will provide input for an example video (comprising of title, description, and transcript, in this order) and the corresponding abstract and summary I expect. Afterward, I will provide a new transcript that I want you to summarize in the same format. **Please give an abstract of the transcript and then summarize the transcript in a self-contained bullet list format.** Include starting timestamps, important details and key takeaways. Example Input: Fluidigm Polaris Part 2- illuminator and camera mikeselectricstuff 131K subscribers Subscribed 369 Share Download Clip Save 5,857 views Aug 26, 2024 Fluidigm Polaris part 1 : • Fluidigm Polaris (Part 1) - Biotech g... Ebay listings: https://www.ebay.co.uk/usr/mikeselect... Merch https://mikeselectricstuff.creator-sp... Transcript Follow along using the transcript. Show transcript mikeselectricstuff 131K subscribers Videos About Support on Patreon 40 Comments @robertwatsonbath 6 hours ago Thanks Mike. Ooof! - with the level of bodgery going on around 15:48 I think shame would have made me do a board re spin, out of my own pocket if I had to. 1 Reply @Muonium1 9 hours ago The green LED looks different from the others and uses phosphor conversion because of the "green gap" problem where green InGaN emitters suffer efficiency droop at high currents. Phosphide based emitters don't start becoming efficient until around 600nm so also can't be used for high power green emitters. See the paper and plot by Matthias Auf der Maur in his 2015 paper on alloy fluctuations in InGaN as the cause of reduced external quantum efficiency at longer (green) wavelengths. 4 Reply 1 reply @tafsirnahian669 10 hours ago (edited) Can this be used as an astrophotography camera? Reply mikeselectricstuff · 1 reply @mikeselectricstuff 6 hours ago Yes, but may need a shutter to avoid light during readout Reply @2010craggy 11 hours ago Narrowband filters we use in Astronomy (Astrophotography) are sided- they work best passing light in one direction so I guess the arrows on the filter frames indicate which way round to install them in the filter wheel. 1 Reply @vitukz 12 hours ago A mate with Channel @extractions&ire could use it 2 Reply @RobertGallop 19 hours ago That LED module says it can go up to 28 amps!!! 21 amps for 100%. You should see what it does at 20 amps! Reply @Prophes0r 19 hours ago I had an "Oh SHIT!" moment when I realized that the weird trapezoidal shape of that light guide was for keystone correction of the light source. Very clever. 6 Reply @OneBiOzZ 20 hours ago given the cost of the CCD you think they could have run another PCB for it 9 Reply @tekvax01 21 hours ago $20 thousand dollars per minute of run time! 1 Reply @tekvax01 22 hours ago "We spared no expense!" John Hammond Jurassic Park. *(that's why this thing costs the same as a 50-seat Greyhound Bus coach!) Reply @florianf4257 22 hours ago The smearing on the image could be due to the fact that you don't use a shutter, so you see brighter stripes under bright areas of the image as you still iluminate these pixels while the sensor data ist shifted out towards the top. I experienced this effect back at university with a LN-Cooled CCD for Spectroscopy. The stripes disapeared as soon as you used the shutter instead of disabling it in the open position (but fokussing at 100ms integration time and continuous readout with a focal plane shutter isn't much fun). 12 Reply mikeselectricstuff · 1 reply @mikeselectricstuff 12 hours ago I didn't think of that, but makes sense 2 Reply @douro20 22 hours ago (edited) The red LED reminds me of one from Roithner Lasertechnik. I have a Symbol 2D scanner which uses two very bright LEDs from that company, one red and one red-orange. The red-orange is behind a lens which focuses it into an extremely narrow beam. 1 Reply @RicoElectrico 23 hours ago PFG is Pulse Flush Gate according to the datasheet. Reply @dcallan812 23 hours ago Very interesting. 2x Reply @littleboot_ 1 day ago Cool interesting device Reply @dav1dbone 1 day ago I've stripped large projectors, looks similar, wonder if some of those castings are a magnesium alloy? Reply @kevywevvy8833 1 day ago ironic that some of those Phlatlight modules are used in some of the cheapest disco lights. 1 Reply 1 reply @bill6255 1 day ago Great vid - gets right into subject in title, its packed with information, wraps up quickly. Should get a YT award! imho 3 Reply @JAKOB1977 1 day ago (edited) The whole sensor module incl. a 5 grand 50mpix sensor for 49 £.. highest bid atm Though also a limited CCD sensor, but for the right buyer its a steal at these relative low sums. Architecture Full Frame CCD (Square Pixels) Total Number of Pixels 8304 (H) × 6220 (V) = 51.6 Mp Number of Effective Pixels 8208 (H) × 6164 (V) = 50.5 Mp Number of Active Pixels 8176 (H) × 6132 (V) = 50.1 Mp Pixel Size 6.0 m (H) × 6.0 m (V) Active Image Size 49.1 mm (H) × 36.8 mm (V) 61.3 mm (Diagonal), 645 1.1x Optical Format Aspect Ratio 4:3 Horizontal Outputs 4 Saturation Signal 40.3 ke− Output Sensitivity 31 V/e− Quantum Efficiency KAF−50100−CAA KAF−50100−AAA KAF−50100−ABA (with Lens) 22%, 22%, 16% (Peak R, G, B) 25% 62% Read Noise (f = 18 MHz) 12.5 e− Dark Signal (T = 60°C) 42 pA/cm2 Dark Current Doubling Temperature 5.7°C Dynamic Range (f = 18 MHz) 70.2 dB Estimated Linear Dynamic Range (f = 18 MHz) 69.3 dB Charge Transfer Efficiency Horizontal Vertical 0.999995 0.999999 Blooming Protection (4 ms Exposure Time) 800X Saturation Exposure Maximum Date Rate 18 MHz Package Ceramic PGA Cover Glass MAR Coated, 2 Sides or Clear Glass Features • TRUESENSE Transparent Gate Electrode for High Sensitivity • Ultra-High Resolution • Board Dynamic Range • Low Noise Architecture • Large Active Imaging Area Applications • Digitization • Mapping/Aerial • Photography • Scientific Thx for the tear down Mike, always a joy Reply @martinalooksatthings 1 day ago 15:49 that is some great bodging on of caps, they really didn't want to respin that PCB huh 8 Reply @RhythmGamer 1 day ago Was depressed today and then a new mike video dropped and now I’m genuinely happy to get my tear down fix 1 Reply @dine9093 1 day ago (edited) Did you transfrom into Mr Blobby for a moment there? 2 Reply @NickNorton 1 day ago Thanks Mike. Your videos are always interesting. 5 Reply @KeritechElectronics 1 day ago Heavy optics indeed... Spare no expense, cost no object. Splendid build quality. The CCD is a thing of beauty! 1 Reply @YSoreil 1 day ago The pricing on that sensor is about right, I looked in to these many years ago when they were still in production since it's the only large sensor you could actually buy. Really cool to see one in the wild. 2 Reply @snik2pl 1 day ago That leds look like from led projector Reply @vincei4252 1 day ago TDI = Time Domain Integration ? 1 Reply @wolpumba4099 1 day ago (edited) Maybe the camera should not be illuminated during readout. From the datasheet of the sensor (Onsemi): saturation 40300 electrons, read noise 12.5 electrons per pixel @ 18MHz (quite bad). quantum efficiency 62% (if it has micro lenses), frame rate 1 Hz. lateral overflow drain to prevent blooming protects against 800x (factor increases linearly with exposure time) saturation exposure (32e6 electrons per pixel at 4ms exposure time), microlens has +/- 20 degree acceptance angle i guess it would be good for astrophotography 4 Reply @txm100 1 day ago (edited) Babe wake up a new mikeselectricstuff has dropped! 9 Reply @vincei4252 1 day ago That looks like a finger-lakes filter wheel, however, for astronomy they'd never use such a large stepper. 1 Reply @MRooodddvvv 1 day ago yaaaaay ! more overcomplicated optical stuff ! 4 Reply 1 reply @NoPegs 1 day ago He lives! 11 Reply 1 reply Transcript 0:00 so I've stripped all the bits of the 0:01 optical system so basically we've got 0:03 the uh the camera 0:05 itself which is mounted on this uh very 0:09 complex 0:10 adjustment thing which obviously to set 0:13 you the various tilt and uh alignment 0:15 stuff then there's two of these massive 0:18 lenses I've taken one of these apart I 0:20 think there's something like about eight 0:22 or nine Optical elements in here these 0:25 don't seem to do a great deal in terms 0:26 of electr magnification they're obiously 0:28 just about getting the image to where it 0:29 uh where it needs to be just so that 0:33 goes like that then this Optical block I 0:36 originally thought this was made of some 0:37 s crazy heavy material but it's just 0:39 really the sum of all these Optical bits 0:41 are just ridiculously heavy those lenses 0:43 are about 4 kilos each and then there's 0:45 this very heavy very solid um piece that 0:47 goes in the middle and this is so this 0:49 is the filter wheel assembly with a 0:51 hilariously oversized steper 0:53 motor driving this wheel with these very 0:57 large narrow band filters so we've got 1:00 various different shades of uh 1:03 filters there five Al together that 1:06 one's actually just showing up a silver 1:07 that's actually a a red but fairly low 1:10 transmission orangey red blue green 1:15 there's an excess cover on this side so 1:16 the filters can be accessed and changed 1:19 without taking anything else apart even 1:21 this is like ridiculous it's like solid 1:23 aluminium this is just basically a cover 1:25 the actual wavelengths of these are um 1:27 488 525 570 630 and 700 NM not sure what 1:32 the suffix on that perhaps that's the uh 1:34 the width of the spectral line say these 1:37 are very narrow band filters most of 1:39 them are you very little light through 1:41 so it's still very tight narrow band to 1:43 match the um fluoresence of the dies 1:45 they're using in the biochemical process 1:48 and obviously to reject the light that's 1:49 being fired at it from that Illuminator 1:51 box and then there's a there's a second 1:53 one of these lenses then the actual sort 1:55 of samples below that so uh very serious 1:58 amount of very uh chunky heavy Optics 2:01 okay let's take a look at this light 2:02 source made by company Lumen Dynamics 2:04 who are now part of 2:06 excelitas self-contained unit power 2:08 connector USB and this which one of the 2:11 Cable Bundle said was a TTL interface 2:14 USB wasn't used in uh the fluid 2:17 application output here and I think this 2:19 is an input for um light feedback I 2:21 don't if it's regulated or just a measur 2:23 measurement facility and the uh fiber 2:27 assembly 2:29 Square Inlet there and then there's two 2:32 outputs which have uh lens assemblies 2:35 and this small one which goes back into 2:37 that small Port just Loops out of here 2:40 straight back in So on this side we've 2:42 got the electronics which look pretty 2:44 straightforward we've got a bit of power 2:45 supply stuff over here and we've got 2:48 separate drivers for each wavelength now 2:50 interesting this is clearly been very 2:52 specifically made for this application 2:54 you I was half expecting like say some 2:56 generic drivers that could be used for a 2:58 number of different things but actually 3:00 literally specified the exact wavelength 3:02 on the PCB there is provision here for 3:04 385 NM which isn't populated but this is 3:07 clearly been designed very specifically 3:09 so these four drivers look the same but 3:10 then there's two higher power ones for 3:12 575 and 3:14 520 a slightly bigger heat sink on this 3:16 575 section there a p 24 which is 3:20 providing USB interface USB isolator the 3:23 USB interface just presents as a comport 3:26 I did have a quick look but I didn't 3:27 actually get anything sensible um I did 3:29 dump the Pi code out and there's a few 3:31 you a few sort of commands that you 3:32 could see in text but I didn't actually 3:34 manage to get it working properly I 3:36 found some software for related version 3:38 but it didn't seem to want to talk to it 3:39 but um I say that wasn't used for the 3:41 original application it might be quite 3:42 interesting to get try and get the Run 3:44 hours count out of it and the TTL 3:46 interface looks fairly straightforward 3:48 we've got positions for six opto 3:50 isolators but only five five are 3:52 installed so that corresponds with the 3:54 unused thing so I think this hopefully 3:56 should be as simple as just providing a 3:57 ttrl signal for each color to uh enable 4:00 it a big heat sink here which is there I 4:03 think there's like a big S of metal 4:04 plate through the middle of this that 4:05 all the leads are mounted on the other 4:07 side so this is heat sinking it with a 4:09 air flow from a uh just a fan in here 4:13 obviously don't have the air flow 4:14 anywhere near the Optics so conduction 4:17 cool through to this plate that's then 4:18 uh air cooled got some pots which are 4:21 presumably power 4:22 adjustments okay let's take a look at 4:24 the other side which is uh much more 4:27 interesting see we've got some uh very 4:31 uh neatly Twisted cable assemblies there 4:35 a bunch of leads so we've got one here 4:37 475 up here 430 NM 630 575 and 520 4:44 filters and dcro mirrors a quick way to 4:48 see what's white is if we just shine 4:49 some white light through 4:51 here not sure how it is is to see on the 4:54 camera but shining white light we do 4:55 actually get a bit of red a bit of blue 4:57 some yellow here so the obstacle path 5:00 575 it goes sort of here bounces off 5:03 this mirror and goes out the 520 goes 5:07 sort of down here across here and up 5:09 there 630 goes basically straight 5:13 through 5:15 430 goes across there down there along 5:17 there and the 475 goes down here and 5:20 left this is the light sensing thing 5:22 think here there's just a um I think 5:24 there a photo diode or other sensor 5:26 haven't actually taken that off and 5:28 everything's fixed down to this chunk of 5:31 aluminium which acts as the heat 5:32 spreader that then conducts the heat to 5:33 the back side for the heat 5:35 sink and the actual lead packages all 5:38 look fairly similar except for this one 5:41 on the 575 which looks quite a bit more 5:44 substantial big spay 5:46 Terminals and the interface for this 5:48 turned out to be extremely simple it's 5:50 literally a 5V TTL level to enable each 5:54 color doesn't seem to be any tensity 5:56 control but there are some additional 5:58 pins on that connector that weren't used 5:59 in the through time thing so maybe 6:01 there's some extra lines that control 6:02 that I couldn't find any data on this uh 6:05 unit and the um their current product 6:07 range is quite significantly different 6:09 so we've got the uh blue these 6:13 might may well be saturating the camera 6:16 so they might look a bit weird so that's 6:17 the 430 6:18 blue the 575 6:24 yellow uh 6:26 475 light blue 6:29 the uh 520 6:31 green and the uh 630 red now one 6:36 interesting thing I noticed for the 6:39 575 it's actually it's actually using a 6:42 white lead and then filtering it rather 6:44 than using all the other ones are using 6:46 leads which are the fundamental colors 6:47 but uh this is actually doing white and 6:50 it's a combination of this filter and 6:52 the dichroic mirrors that are turning to 6:55 Yellow if we take the filter out and a 6:57 lot of the a lot of the um blue content 7:00 is going this way the red is going 7:02 straight through these two mirrors so 7:05 this is clearly not reflecting much of 7:08 that so we end up with the yellow coming 7:10 out of uh out of there which is a fairly 7:14 light yellow color which you don't 7:16 really see from high intensity leads so 7:19 that's clearly why they've used the 7:20 white to uh do this power consumption of 7:23 the white is pretty high so going up to 7:25 about 2 and 1 half amps on that color 7:27 whereas most of the other colors are 7:28 only drawing half an amp or so at 24 7:30 volts the uh the green is up to about 7:32 1.2 but say this thing is uh much 7:35 brighter and if you actually run all the 7:38 colors at the same time you get a fairly 7:41 reasonable um looking white coming out 7:43 of it and one thing you might just be 7:45 out to notice is there is some sort 7:46 color banding around here that's not 7:49 getting uh everything s completely 7:51 concentric and I think that's where this 7:53 fiber optic thing comes 7:58 in I'll 8:00 get a couple of Fairly accurately shaped 8:04 very sort of uniform color and looking 8:06 at What's um inside here we've basically 8:09 just got this Square Rod so this is 8:12 clearly yeah the lights just bouncing 8:13 off all the all the various sides to um 8:16 get a nice uniform illumination uh this 8:19 back bit looks like it's all potted so 8:21 nothing I really do to get in there I 8:24 think this is fiber so I have come 8:26 across um cables like this which are 8:27 liquid fill but just looking through the 8:30 end of this it's probably a bit hard to 8:31 see it does look like there fiber ends 8:34 going going on there and so there's this 8:36 feedback thing which is just obviously 8:39 compensating for the any light losses 8:41 through here to get an accurate 8:43 representation of uh the light that's 8:45 been launched out of these two 8:47 fibers and you see uh 8:49 these have got this sort of trapezium 8:54 shape light guides again it's like a 8:56 sort of acrylic or glass light guide 9:00 guess projected just to make the right 9:03 rectangular 9:04 shape and look at this Center assembly 9:07 um the light output doesn't uh change 9:10 whether you feed this in or not so it's 9:11 clear not doing any internal Clos Loop 9:14 control obviously there may well be some 9:16 facility for it to do that but it's not 9:17 being used in this 9:19 application and so this output just 9:21 produces a voltage on the uh outle 9:24 connector proportional to the amount of 9:26 light that's present so there's a little 9:28 diffuser in the back there 9:30 and then there's just some kind of uh 9:33 Optical sensor looks like a 9:35 chip looking at the lead it's a very 9:37 small package on the PCB with this lens 9:40 assembly over the top and these look 9:43 like they're actually on a copper 9:44 Metalized PCB for maximum thermal 9:47 performance and yeah it's a very small 9:49 package looks like it's a ceramic 9:51 package and there's a thermister there 9:53 for temperature monitoring this is the 9:56 475 blue one this is the 520 need to 9:59 Green which is uh rather different OB 10:02 it's a much bigger D with lots of bond 10:04 wise but also this looks like it's using 10:05 a phosphor if I shine a blue light at it 10:08 lights up green so this is actually a 10:10 phosphor conversion green lead which 10:12 I've I've come across before they want 10:15 that specific wavelength so they may be 10:17 easier to tune a phosphor than tune the 10:20 um semiconductor material to get the uh 10:23 right right wavelength from the lead 10:24 directly uh red 630 similar size to the 10:28 blue one or does seem to have a uh a 10:31 lens on top of it there is a sort of red 10:33 coloring to 10:35 the die but that doesn't appear to be 10:38 fluorescent as far as I can 10:39 tell and the white one again a little 10:41 bit different sort of much higher 10:43 current 10:46 connectors a makeer name on that 10:48 connector flot light not sure if that's 10:52 the connector or the lead 10:54 itself and obviously with the phosphor 10:56 and I'd imagine that phosphor may well 10:58 be tuned to get the maximum to the uh 5 11:01 cenm and actually this white one looks 11:04 like a St fairly standard product I just 11:06 found it in Mouse made by luminous 11:09 devices in fact actually I think all 11:11 these are based on various luminous 11:13 devices modules and they're you take 11:17 looks like they taking the nearest 11:18 wavelength and then just using these 11:19 filters to clean it up to get a precise 11:22 uh spectral line out of it so quite a 11:25 nice neat and um extreme 11:30 bright light source uh sure I've got any 11:33 particular use for it so I think this 11:35 might end up on 11:36 eBay but uh very pretty to look out and 11:40 without the uh risk of burning your eyes 11:43 out like you do with lasers so I thought 11:45 it would be interesting to try and 11:46 figure out the runtime of this things 11:48 like this we usually keep some sort 11:49 record of runtime cuz leads degrade over 11:51 time I couldn't get any software to work 11:52 through the USB face but then had a 11:54 thought probably going to be writing the 11:55 runtime periodically to the e s prom so 11:58 I just just scope up that and noticed it 12:00 was doing right every 5 minutes so I 12:02 just ran it for a while periodically 12:04 reading the E squ I just held the pick 12:05 in in reset and um put clip over to read 12:07 the square prom and found it was writing 12:10 one location per color every 5 minutes 12:12 so if one color was on it would write 12:14 that location every 5 minutes and just 12:16 increment it by one so after doing a few 12:18 tests with different colors of different 12:19 time periods it looked extremely 12:21 straightforward it's like a four bite 12:22 count for each color looking at the 12:24 original data that was in it all the 12:26 colors apart from Green were reading 12:28 zero and the green was reading four 12:30 indicating a total 20 minutes run time 12:32 ever if it was turned on run for a short 12:34 time then turned off that might not have 12:36 been counted but even so indicates this 12:37 thing wasn't used a great deal the whole 12:40 s process of doing a run can be several 12:42 hours but it'll only be doing probably 12:43 the Imaging at the end of that so you 12:46 wouldn't expect to be running for a long 12:47 time but say a single color for 20 12:50 minutes over its whole lifetime does 12:52 seem a little bit on the low side okay 12:55 let's look at the camera un fortunately 12:57 I managed to not record any sound when I 12:58 did this it's also a couple of months 13:00 ago so there's going to be a few details 13:02 that I've forgotten so I'm just going to 13:04 dub this over the original footage so um 13:07 take the lid off see this massive great 13:10 heat sink so this is a pel cool camera 13:12 we've got this blower fan producing a 13:14 fair amount of air flow through 13:16 it the connector here there's the ccds 13:19 mounted on the board on the 13:24 right this unplugs so we've got a bit of 13:27 power supply stuff on here 13:29 USB interface I think that's the Cyprus 13:32 microcontroller High speeded USB 13:34 interface there's a zyink spon fpga some 13:40 RAM and there's a couple of ATD 13:42 converters can't quite read what those 13:45 those are but anal 13:47 devices um little bit of bodgery around 13:51 here extra decoupling obviously they 13:53 have having some noise issues this is 13:55 around the ram chip quite a lot of extra 13:57 capacitors been added there 13:59 uh there's a couple of amplifiers prior 14:01 to the HD converter buffers or Andor 14:05 amplifiers taking the CCD 14:08 signal um bit more power spy stuff here 14:11 this is probably all to do with 14:12 generating the various CCD bias voltages 14:14 they uh need quite a lot of exotic 14:18 voltages next board down is just a 14:20 shield and an interconnect 14:24 boardly shielding the power supply stuff 14:26 from some the more sensitive an log 14:28 stuff 14:31 and this is the bottom board which is 14:32 just all power supply 14:34 stuff as you can see tons of capacitors 14:37 or Transformer in 14:42 there and this is the CCD which is a uh 14:47 very impressive thing this is a kf50 100 14:50 originally by true sense then codec 14:53 there ON 14:54 Semiconductor it's 50 megapixels uh the 14:58 only price I could find was this one 15:00 5,000 bucks and the architecture you can 15:03 see there actually two separate halves 15:04 which explains the Dual AZ converters 15:06 and two amplifiers it's literally split 15:08 down the middle and duplicated so it's 15:10 outputting two streams in parallel just 15:13 to keep the bandwidth sensible and it's 15:15 got this amazing um diffraction effects 15:18 it's got micro lenses over the pixel so 15:20 there's there's a bit more Optics going 15:22 on than on a normal 15:25 sensor few more bodges on the CCD board 15:28 including this wire which isn't really 15:29 tacked down very well which is a bit uh 15:32 bit of a mess quite a few bits around 15:34 this board where they've uh tacked 15:36 various bits on which is not super 15:38 impressive looks like CCD drivers on the 15:40 left with those 3 ohm um damping 15:43 resistors on the 15:47 output get a few more little bodges 15:50 around here some of 15:52 the and there's this separator the 15:54 silica gel to keep the moisture down but 15:56 there's this separator that actually 15:58 appears to be cut from piece of 15:59 antistatic 16:04 bag and this sort of thermal block on 16:06 top of this stack of three pel Cola 16:12 modules so as with any Stacks they get 16:16 um larger as they go back towards the 16:18 heat sink because each P's got to not 16:20 only take the heat from the previous but 16:21 also the waste heat which is quite 16:27 significant you see a little temperature 16:29 sensor here that copper block which 16:32 makes contact with the back of the 16:37 CCD and this's the back of the 16:40 pelas this then contacts the heat sink 16:44 on the uh rear there a few thermal pads 16:46 as well for some of the other power 16:47 components on this 16:51 PCB okay I've connected this uh camera 16:54 up I found some drivers on the disc that 16:56 seem to work under Windows 7 couldn't 16:58 get to install under Windows 11 though 17:01 um in the absence of any sort of lens or 17:03 being bothered to the proper amount I've 17:04 just put some f over it and put a little 17:06 pin in there to make a pinhole lens and 17:08 software gives a few options I'm not 17:11 entirely sure what all these are there's 17:12 obviously a clock frequency 22 MHz low 17:15 gain and with PFG no idea what that is 17:19 something something game programmable 17:20 Something game perhaps ver exposure 17:23 types I think focus is just like a 17:25 continuous grab until you tell it to 17:27 stop not entirely sure all these options 17:30 are obviously exposure time uh triggers 17:33 there ex external hardware trigger inut 17:35 you just trigger using a um thing on 17:37 screen so the resolution is 8176 by 17:40 6132 and you can actually bin those 17:42 where you combine multiple pixels to get 17:46 increased gain at the expense of lower 17:48 resolution down this is a 10sec exposure 17:51 obviously of the pin hole it's very uh 17:53 intensitive so we just stand still now 17:56 downloading it there's the uh exposure 17:59 so when it's 18:01 um there's a little status thing down 18:03 here so that tells you the um exposure 18:07 [Applause] 18:09 time it's this is just it 18:15 downloading um it is quite I'm seeing 18:18 quite a lot like smearing I think that I 18:20 don't know whether that's just due to 18:21 pixels overloading or something else I 18:24 mean yeah it's not it's not um out of 18:26 the question that there's something not 18:27 totally right about this camera 18:28 certainly was bodge wise on there um I 18:31 don't I'd imagine a camera like this 18:32 it's got a fairly narrow range of 18:34 intensities that it's happy with I'm not 18:36 going to spend a great deal of time on 18:38 this if you're interested in this camera 18:40 maybe for astronomy or something and 18:42 happy to sort of take the risk of it may 18:44 not be uh perfect I'll um I think I'll 18:47 stick this on eBay along with the 18:48 Illuminator I'll put a link down in the 18:50 description to the listing take your 18:52 chances to grab a bargain so for example 18:54 here we see this vertical streaking so 18:56 I'm not sure how normal that is this is 18:58 on fairly bright scene looking out the 19:02 window if I cut the exposure time down 19:04 on that it's now 1 second 19:07 exposure again most of the image 19:09 disappears again this is looks like it's 19:11 possibly over still overloading here go 19:14 that go down to say say quarter a 19:16 second so again I think there might be 19:19 some Auto gain control going on here um 19:21 this is with the PFG option let's try 19:23 turning that off and see what 19:25 happens so I'm not sure this is actually 19:27 more streaking or which just it's 19:29 cranked up the gain all the dis display 19:31 gray scale to show what um you know the 19:33 range of things that it's captured 19:36 there's one of one of 12 things in the 19:38 software there's um you can see of you 19:40 can't seem to read out the temperature 19:42 of the pelta cooler but you can set the 19:44 temperature and if you said it's a 19:46 different temperature you see the power 19:48 consumption jump up running the cooler 19:50 to get the temperature you requested but 19:52 I can't see anything anywhere that tells 19:54 you whether the cool is at the at the 19:56 temperature other than the power 19:57 consumption going down and there's no 19:59 temperature read out 20:03 here and just some yeah this is just 20:05 sort of very basic software I'm sure 20:07 there's like an API for more 20:09 sophisticated 20:10 applications but so if you know anything 20:12 more about these cameras please um stick 20:14 in the 20:15 comments um incidentally when I was 20:18 editing I didn't notice there was a bent 20:19 pin on the um CCD but I did fix that 20:22 before doing these tests and also 20:24 reactivated the um silica gel desicant 20:26 cuz I noticed it was uh I was getting 20:28 bit of condensation on the window but um 20:31 yeah so a couple of uh interesting but 20:34 maybe not particularly uh useful pieces 20:37 of Kit except for someone that's got a 20:38 very specific use so um I'll stick a 20:42 I'll stick these on eBay put a link in 20:44 the description and say hopefully 20:45 someone could actually make some uh good 20:47 use of these things Example Output: **Abstract:** This video presents Part 2 of a teardown focusing on the optical components of a Fluidigm Polaris biotechnology instrument, specifically the multi-wavelength illuminator and the high-resolution CCD camera. The Lumen Dynamics illuminator unit is examined in detail, revealing its construction using multiple high-power LEDs (430nm, 475nm, 520nm, 575nm, 630nm) combined via dichroic mirrors and filters. A square fiber optic rod is used to homogenize the light. A notable finding is the use of a phosphor-converted white LED filtered to achieve the 575nm output. The unit features simple TTL activation for each color, conduction cooling, and internal homogenization optics. Analysis of its EEPROM suggests extremely low operational runtime. The camera module teardown showcases a 50 Megapixel ON Semiconductor KAF-50100 CCD sensor with micro-lenses, cooled by a multi-stage Peltier stack. The control electronics include an FPGA and a USB interface. Significant post-manufacturing modifications ("bodges") are observed on the camera's circuit boards. Basic functional testing using vendor software and a pinhole lens confirms image capture but reveals prominent vertical streaking artifacts, the cause of which remains uncertain (potential overload, readout artifact, or fault). **Exploring the Fluidigm Polaris: A Detailed Look at its High-End Optics and Camera System** * **0:00 High-End Optics:** The system utilizes heavy, high-quality lenses and mirrors for precise imaging, weighing around 4 kilos each. * **0:49 Narrow Band Filters:** A filter wheel with five narrow band filters (488, 525, 570, 630, and 700 nm) ensures accurate fluorescence detection and rejection of excitation light. * **2:01 Customizable Illumination:** The Lumen Dynamics light source offers five individually controllable LED wavelengths (430, 475, 520, 575, 630 nm) with varying power outputs. The 575nm yellow LED is uniquely achieved using a white LED with filtering. * **3:45 TTL Control:** The light source is controlled via a simple TTL interface, enabling easy on/off switching for each LED color. * **12:55 Sophisticated Camera:** The system includes a 50-megapixel Kodak KAI-50100 CCD camera with a Peltier cooling system for reduced noise. * **14:54 High-Speed Data Transfer:** The camera features dual analog-to-digital converters to manage the high data throughput of the 50-megapixel sensor, which is effectively two 25-megapixel sensors operating in parallel. * **18:11 Possible Issues:** The video creator noted some potential issues with the camera, including image smearing. * **18:11 Limited Dynamic Range:** The camera's sensor has a limited dynamic range, making it potentially challenging to capture scenes with a wide range of brightness levels. * **11:45 Low Runtime:** Internal data suggests the system has seen minimal usage, with only 20 minutes of recorded runtime for the green LED. * **20:38 Availability on eBay:** Both the illuminator and camera are expected to be listed for sale on eBay. Here is the real transcript. Please summarize it: 00:11:40 Okay, here we go. Let me try this. 00:11:40 Oh, that scared me. 00:11:44 Oh, that's better. And no more music. 00:11:48 Okay. Hello wonderful person and people 00:11:51 of uh all sorts from everywhere. So 00:11:54 welcome to your I guess uh annual stream 00:11:57 sort of even though I keep promising to 00:11:59 make this at least monthly. Um I'm going 00:12:02 to double check that everything is 00:12:04 working before we start and also I think 00:12:07 we still have about 30 30 minutes before 00:12:09 the official announcement um which is 00:12:12 what we're going to be doing today. 00:12:14 But let me see uh okay okay here we go. 00:12:17 Everything seems to be working. Uh, 00:12:21 let me just I'm going to hear myself for 00:12:23 one second. Let me hear myself for one 00:12:25 second. 00:12:28 Where am I? 00:12:30 Where's my stream? 00:12:33 Let me see. Okay. Okay. Okay. Here we 00:12:34 go. All right. Seems to work. Let me 00:12:36 know if there's a problem. Um, or 00:12:38 problems. I'm sure there will be 00:12:40 problems because I have not done this in 00:12:43 over a year. Last time we did this was 00:12:45 during the 2024 solar eclipse and uh now 00:12:49 we're back and I promised last year that 00:12:50 I was going to do one I was going to do 00:12:52 a stream uh sometimes in the summer of 00:12:54 2024 never happened my apologies. 00:12:57 Anyway, so uh what is first of all to 00:13:00 answer your questions still not AI as 00:13:02 you can see still 10 fingers. Second of 00:13:04 all um what are we doing? So today the 00:13:07 main point of this stream the annual 00:13:10 stream is because we actually have a 00:13:12 huge announcement from the uh National 00:13:15 Science Foundation um the uh Vera Rubin 00:13:19 Observatory and basically it is going to 00:13:22 be about let me check how do I disable 00:13:24 this it's going to be about uh this no 00:13:28 this no come back here we go it's going 00:13:31 to be about this we have half an hour 00:13:34 before the announcement from Vera Rubin 00:13:36 Observatory 00:13:38 and I don't exactly know what they're 00:13:39 going to be talking about yet, but it's 00:13:42 basically going to be most likely the um 00:13:45 the discussion about the first images 00:13:47 that were just released and possibly 00:13:49 some more images, which is what I'm 00:13:50 hoping for. And so they basically ask 00:13:52 for anyone who has any following to who 00:13:54 to do a kind of a uh impromptu party, I 00:13:57 guess. Uh and there's actually a whole 00:13:59 list of parties they have listed here 00:14:00 somewhere. Here we go. Let me show you 00:14:02 some of these parties. list. Uh, post a 00:14:05 Reuben party is what it's called. You 00:14:08 can actually see uh some of them are 00:14:10 possibly in your neighborhood and oh, 00:14:12 where's the map? I thought it was a map. 00:14:14 There has to be a map somewhere 00:14:15 somewhere. 00:14:16 Uh, 00:14:18 oh, I thought it was a map. Anyway, I 00:14:21 saw a map somewhere. Anyway, so this is 00:14:23 one of these parties, but it's basically 00:14:24 virtual and not in person. Um and the 00:14:28 point is to look at the images, discuss 00:14:31 them and just to um just to basically 00:14:34 get get ready for the mission that Vera 00:14:36 Rubin Observatory is going to be 00:14:37 performing for the next decade and it's 00:14:40 going to be a huge mission. So that's 00:14:42 basically that's what I'm going to be 00:14:43 talking about. I'm going to try to 00:14:44 simplify the mission as much as possible 00:14:47 and talk about why this is probably one 00:14:48 of the most important observatories of 00:14:51 the last few years really possibly of 00:14:53 the last decade. um maybe even more 00:14:55 important than the James Web just 00:14:57 because of the actual quality of 00:14:59 pictures we're going to be receiving, 00:15:01 but still James Web is still pretty 00:15:03 important. All right, so let me just set 00:15:05 up some of the background pictures I had 00:15:07 here just uh until we wait for the 00:15:10 announcement. Uh oh, also this is what 00:15:13 it looked like a few years back. This is 00:15:15 when they were building it. This project 00:15:17 took approximately 20 years to finalize. 00:15:20 And this is a pretty big observatory and 00:15:22 it has one of the biggest telescopes 00:15:24 with the most sensitive camera in the 00:15:26 world. So this take that Samsung phones 00:15:29 have nothing compared to this. Uh and 00:15:32 what am I looking for here? I'm looking 00:15:34 for my 00:15:36 display picture. I don't need this right 00:15:37 now. All right. Uh while we're waiting 00:15:39 for everything, I was going to briefly 00:15:41 talk about the mission, I guess, and you 00:15:43 know, take some questions. Then we're 00:15:45 going to listen to the announcement from 00:15:46 Ver Rubin. uh because I actually I'm 00:15:48 super curious to to hear what they're 00:15:50 going what they're going to be talking 00:15:51 about. And lastly uh we are going to 00:15:54 finish with a Q&A or maybe just Q maybe 00:15:57 no A because I don't have all the 00:15:58 answers. Uh anyway, so hello everyone 00:16:00 from Canada and from other countries. Uh 00:16:02 and uh 00:16:05 let me see if there's any comments any 00:16:06 comments that I need to answer to yet. U 00:16:09 any questions? Cool. All right. If 00:16:11 there's any problem with sound or if you 00:16:13 cannot cannot hear something or if 00:16:14 there's a music in the background, 00:16:15 please let me know because I'm I'm still 00:16:18 even after years of doing this, I still 00:16:20 forget to turn off things to turn things 00:16:22 on and so on. 00:16:24 And uh in the meanwhile while I'm 00:16:27 waiting for the stream to start which is 00:16:28 going to start in about 27 minutes uh I 00:16:31 wanted to briefly mention what this 00:16:33 telescope is I guess because it is a 00:16:36 pretty exciting telescope and it is 00:16:38 called Vera Rubin telescope because of 00:16:40 this wonderful lady. Let me just get 00:16:42 this checked and checked. This wonderful 00:16:45 lady is Vera Rubin. She unfortunately 00:16:48 passed away uh I think about seven years 00:16:50 ago. I think it was 2018 and she is 00:16:54 considered to be I guess unofficial 00:16:56 mother of uh dark matter even though I I 00:16:59 always get comments about oh this guy 00:17:01 still believes in dark matter blah blah 00:17:02 blah blah uh well she did too but even 00:17:05 though she she wasn't sure what it was 00:17:07 and she w she was the one who 00:17:08 essentially kind of sort of found it uh 00:17:11 by looking at galactic curves of uh 00:17:13 Andromeda galaxy and a few other 00:17:15 galaxies. She was the one who basically 00:17:16 brought it to everyone's attention and 00:17:19 was supposed to get a Nobel Prize but 00:17:21 never did and because of that a lot of 00:17:23 scientists were upset instead she had 00:17:26 instead of Nobel prize she got this she 00:17:28 has a telescope named after her which uh 00:17:30 I personally would take over Nobel Prize 00:17:33 too. Uh so and uh the reason this 00:17:36 telescope is so important is really 00:17:38 because of the just the sheer quality of 00:17:40 the lens, the sheer quality of the 00:17:42 mirror, the uh the the camera, the 00:17:45 actual camera it uses. Um I'm going to 00:17:47 show you one of the pictures that I have 00:17:50 here somewhere. I have a bunch of 00:17:52 pictures actually, but I didn't prepare 00:17:54 at all for this. I just found pictures. 00:17:56 I'm like, "Oh, I I think I'll figure it 00:17:58 out." Here. Here we go. Here's another 00:17:59 picture. Uh this is a picture of the 00:18:01 telescope on the mountain. And this is 00:18:04 located in uh let me let me try to read 00:18:06 the name of this mountain. It's called 00:18:08 El Penong Peak uh of Sero Pachong. It's 00:18:13 a 2700 meter high or about 9,000 ft high 00:18:17 mountain in Kokimbo region of northern 00:18:19 Chile. And this is very close to other 00:18:22 famous telescopes like Gemini South and 00:18:25 Southern Astrophysical Research 00:18:26 Telescopes in the Atakama desert in 00:18:29 Chile. And it's essentially located here 00:18:31 for one simple reason. They have the 00:18:34 best nice skies in the world. They 00:18:36 barely get any rain. Uh they have the 00:18:40 best visibility and all of most of the 00:18:42 modern telescopes are in this in the 00:18:44 same region. It's the Chile and 00:18:46 government managed to find a perfect 00:18:48 niche for their uh supplements for the 00:18:50 government supplements. They get a lot 00:18:51 of money from from these uh projects. Uh 00:18:55 and so this is the new creation and it's 00:18:57 basically going to be one of the most 00:18:59 powerful uh telesc earth telescopes, 00:19:02 optical telescopes that's going to be 00:19:04 doing its mission for the next 10 to 12 00:19:06 years. 00:19:08 Okay, so let me just double check. I I 00:19:10 haven't been reading comments yet. Let's 00:19:11 see. Okay, let's see. Comment number 00:19:13 one. I think I have a comment. Oh, thank 00:19:16 you for the donation. Solar night, uh 00:19:18 can you elaborate a bit about the 00:19:19 current solar maximum flares Parker Sol 00:19:22 possible Carrington event? Uh it's not 00:19:25 really related to this but okay I'll try 00:19:26 to elaborate. Nothing to worry about. 00:19:28 There's not going to be any possible 00:19:29 Carrington event anytime soon. The uh 00:19:31 solar maximum is has passed the race. Uh 00:19:34 the sun is currently going toward its 00:19:36 minimal peak. Uh it's basically on a on 00:19:38 the way down. So we don't think anything 00:19:39 major is going to happen anytime soon. 00:19:41 Uh and Parker Solar Probe is still doing 00:19:43 its mission. It's basically still 00:19:45 collecting data. It it it's done its uh 00:19:48 recent close passage, but it hasn't 00:19:49 really discovered anything major yet. 00:19:51 There will be an update about this uh I 00:19:53 think in about couple of months. Uh but 00:19:56 we'll talk about it in some other 00:19:57 videos. It soler solar probe even though 00:20:00 it's an amazing mission. Um it's it does 00:20:03 collect data very slowly. So it takes a 00:20:05 long time to process everything. So we 00:20:07 don't really have that much information 00:20:08 yet but it it's supposed to solve the 00:20:10 mystery of basically why we get these um 00:20:13 CMEs coronal mass ejections and why how 00:20:15 the solar magnetism works and so on. 00:20:17 It's it's one of its main missions. So, 00:20:19 we'll hopefully get some cool answers 00:20:21 very soon. All right, cool, cool, cool, 00:20:23 cool, cool. Thank you for the question 00:20:25 and for the donation. Love it. No 00:20:27 donation is great, but I'm loving the 00:20:29 questions. Uh, 00:20:31 okay, next question. Um, 00:20:35 if ground B if that's a good question. 00:20:37 Groundbased telescopes, if they're so 00:20:38 good, why do we need space telescopes? 00:20:40 Well, remember on the ground here we 00:20:41 have atmosphere, right? So, not all 00:20:43 frequencies pass through the atmosphere. 00:20:46 uh the atmosphere is opaque to a lot of 00:20:47 different wavelengths and one of them is 00:20:49 of course um infrared wavelength and 00:20:52 also uh ultraviolet. So if you want to 00:20:55 see things in the infrared, you 00:20:57 absolutely have to have a space 00:20:58 telescope. And the only reason we want 00:21:00 to see infrared is because according to 00:21:02 the big bang theory, which is of course 00:21:05 still has not been disproven by anyone, 00:21:08 uh even though there's a lot of AI 00:21:09 videos that claim otherwise, 00:21:12 according to the theory, the ancient 00:21:14 super ancient stars, super super ancient 00:21:16 galaxies were all essentially producing 00:21:19 a lot of UV light. But because of the 00:21:20 red shift, because of the expansion of 00:21:22 the universe, due to the big bang, the 00:21:24 wavelength from those stars has now 00:21:26 decreased to the infrared frequencies. 00:21:28 So if you want to see those super super 00:21:30 ancient stars and very very powerful 00:21:32 galaxies, we have to see infrared light 00:21:34 today. And that's why space telescopes 00:21:37 like the James Web are essentially uh 00:21:40 absolutely necessary for that to to to 00:21:42 essentially prove these different 00:21:43 propositions and hypotheses 00:21:46 that we have. Such a difficult word. 00:21:48 Anyway, uh next comment question 00:21:51 concern. Uh is this telescope using the 00:21:53 laser tag to autocorrect? Uh so the 00:21:56 interesting thing about this telescope 00:21:57 is that as far as I'm aware, it does not 00:21:59 have any auto correction. Uh it does not 00:22:02 correct for atmospheric interference 00:22:04 because it's not able to. It's the way 00:22:06 this is designed is that unlike typical 00:22:09 telescopes that focus on just one point 00:22:10 where you can kind of autocorrect using 00:22:12 lasers, this one has a very it's it's 00:22:15 it's actually essentially the first 00:22:17 telescope to use a very wide uh view. 00:22:20 And that's what makes it so interesting 00:22:22 because normally you have telescopes 00:22:24 that are either wide view or super 00:22:26 focused and you don't we don't really 00:22:28 get a lot of telescope that can do both. 00:22:30 This one though can because of the way 00:22:32 it was designed. So, it has an enormous 00:22:34 mirror and very sensitive um CCD uh 00:22:38 sensor and it's able to collect a lot of 00:22:41 data, but it doesn't auto correct using 00:22:43 lasers. I think they're using some kind 00:22:44 of algorithm. I'm not I hope that maybe 00:22:46 they'll explain it during the stream, 00:22:48 but I don't know the details because I'm 00:22:50 not a technician and not familiar with 00:22:52 the actual technology. So, I'm I'm sure 00:22:54 there's something going on that's going 00:22:56 to correct it a little bit, but just not 00:22:57 as much as a modern telescope that uses 00:22:59 the laser correction system, which is 00:23:01 usually why, you know, if you ever see a 00:23:03 picture of a telescope, let me see if I 00:23:05 can actually find one. Telescope laser, 00:23:09 you get you usually get these like 00:23:10 pictures of Oh, yeah. laser guiding uh 00:23:13 systems. So, that that laser stuff 00:23:16 that's that's to order correct for 00:23:17 atmospheric interference and to guide 00:23:19 telescope towards certain locations. 00:23:20 This one is not going to be doing that. 00:23:23 This one is just going to be sitting 00:23:25 there and collecting a lot of pictures 00:23:27 over and over and over and over again. 00:23:29 And they're all going to be absolutely 00:23:31 uh amazing. 00:23:33 Uh okay, Gang Nin, thank you for the 00:23:38 donation and also a question, I guess. 00:23:40 Good evening. I never missed your single 00:23:41 video since 2019. Uh you've been our 00:23:43 main uh source of science news ever 00:23:45 since. Keep up keep up the good work. 00:23:47 Thank you so much. Not a question, but 00:23:48 thank you so much. I appreciate it. Uh, 00:23:52 all right. Cool, cool, cool, cool, cool, 00:23:53 cool, cool, cool, cool. I hope I didn't 00:23:55 miss the Oh, something's happening. 00:23:57 Nothing's happening yet. Okay, we have 00:23:59 20 minutes. Right. Right. So, let me let 00:24:01 me see what what else I wanted to 00:24:03 mention. I also wanted to mention that 00:24:05 uh this telescope has several primary 00:24:07 missions. Unlike unlike previous 00:24:08 telescopes that would only focus like on 00:24:10 maybe one or two things, this one 00:24:11 actually has a variety of missions that 00:24:13 are going to be quite difficult to 00:24:15 achieve uh at first, but it has 10 years 00:24:18 to do it. 00:24:19 First of all is obviously uh it's going 00:24:21 to study dark matter. Uh the way it's 00:24:23 going to be doing it is through the um 00:24:26 effect known as weak gravitational 00:24:29 lensing. Let me see if I can find it. Uh 00:24:33 didn't find a picture for that in 00:24:34 advance. So it's essentially uh it so 00:24:37 this is the strong gravitational 00:24:39 lensing. This is the effect uh where we 00:24:41 know that certain masses produce 00:24:43 gravitational lenses and uh we like this 00:24:46 is the Einstein lens. We know that this 00:24:47 is the effect from both mass and dark 00:24:50 matter in this object inside this object 00:24:52 inside this galactic cluster. But it's 00:24:54 going to be here this telescope is 00:24:56 mostly going to be focusing on the 00:24:57 weaker effects. So the ones that are 00:24:59 kind of difficult to see but they're 00:25:00 still there and it's going to use a lot 00:25:03 of different pictures that it's going to 00:25:05 be collecting over the next 10 years to 00:25:07 essentially assemble this kind of a map 00:25:08 of dark matter. Um no matter what it is, 00:25:11 we have no idea what it is. We know it's 00:25:12 there. Uh the effects are there. The uh 00:25:15 mystery is there. We just don't know 00:25:16 what it is. We don't know if it's a 00:25:17 particle. We don't know if it's a 00:25:19 formula thing, which it probably isn't 00:25:21 because it's been disproven several 00:25:22 times. We don't know if it's um some 00:25:25 kind of a strange 00:25:27 fifth dimension multi-dimension thing. 00:25:30 We just know that it's there and it's 00:25:31 undeniable. It's been proven many times. 00:25:33 It's just nobody knows what it is 00:25:35 though. It's just that it's there. Uh 00:25:37 and that's one of its main missions. 00:25:39 It's also going to try to study dark 00:25:40 energy uh which is mostly a mission for 00:25:44 another telescope known another mission 00:25:45 known as desi. We've discussed this in 00:25:47 some of the videos uh or you can just 00:25:50 type desi d e s i you you'll find the 00:25:53 actual mission pretty quickly. Uh but 00:25:55 yeah dark matter dark dark energy weak 00:25:57 gradation lensing. What else? Uh we have 00:26:00 the concept known as bario barrier and 00:26:02 acoustic oscillations known as also 00:26:04 known as bow. That's a pretty cool 00:26:06 concept um but it's kind of hard to 00:26:07 explain it in five minutes. Uh, I'm 00:26:10 going to possibly post some links in the 00:26:12 description from previous videos that 00:26:13 talk about it, but it's essentially 00:26:14 these ancient bubbles from the beginning 00:26:16 of the universe that seem to be 00:26:18 everywhere, but it's really difficult to 00:26:20 find them and difficult to see them. We 00:26:22 just think and know they should be 00:26:24 there. And this telescope is going to be 00:26:27 really really good at detecting them. 00:26:29 And uh also it's also going to be really 00:26:31 really really really good at detecting 00:26:33 various um transients which is basically 00:26:36 short word for explosions. Any kind of a 00:26:39 change of light like for example sudden 00:26:41 nova like the one we we just uh talked 00:26:43 about in the video today uh there's a in 00:26:46 case you you haven't watched the video 00:26:47 there's actually a nova in the sky. You 00:26:48 can you can see it with the naked eye. 00:26:50 Um there is also what else? uh any kind 00:26:55 of asteroid passage is going to be able 00:26:57 to see any kind of a comet is going to 00:26:59 be able to see to see is going to be 00:27:00 able to detect minute changes in light. 00:27:03 And so researchers behind this telescope 00:27:05 actually expected to find an enormous 00:27:08 amount of near-ear asteroids like the 00:27:10 amount we've never even imagined. We're 00:27:12 we're talking about instead of finding 00:27:13 hundreds per day, we're going to be 00:27:15 finding like thousands if not even 00:27:17 millions. Uh, and it's going to be able 00:27:20 to find a tremendous amount of objects 00:27:22 we just could not see before because 00:27:23 it's so sensitive. And because this 00:27:26 telescope is has a wide perspective, 00:27:30 um, it's going to be able to capture so 00:27:32 many pictures at once and then compare 00:27:34 them u within just, you know, like a few 00:27:37 days or so. So, it's going to be pretty 00:27:39 pretty good at detecting a lot of 00:27:40 different changes in the night skies, 00:27:42 which is something we've been waiting 00:27:44 for for a long time. All right, let me 00:27:46 show you something else here. I was 00:27:47 going to show you this picture I showed 00:27:49 you. Oh, yeah. That's a picture of Vera 00:27:51 Rubin, the No, go back. The lady who uh 00:27:55 who this telescope is named after. So, 00:27:57 she is probably one of the most 00:27:59 well-known researchers when it comes to 00:28:01 dark matter. And here is the picture of 00:28:04 the actual uh sensor, the you know, like 00:28:07 you have a camera camera sensor in your 00:28:09 in your camera. So, that's the sensor 00:28:11 they have in this telescope. And it 00:28:13 actually looks like this if you look at 00:28:15 it. Uh where is it? Where's the picture? 00:28:16 I had some really cool pictures I found 00:28:19 of someone holding the sensor in their 00:28:21 hand. I just can't find it anymore. Ah, 00:28:24 where are you? Where are you? Picture. 00:28:27 Okay, that's the telescope. I don't need 00:28:28 that one. Oh, that's the uh that's the 00:28:30 mirror. That's how big the mirror is. I 00:28:32 think it's over um what's the exact 00:28:34 size? I have the exact size somewhere. 00:28:36 It is exactly 00:28:39 uh it's exactly 00:28:43 it's 8.4 24 meters which is uh Google 00:28:48 help me what's meters and two two feet 00:28:51 it is uh 28 ft approximately so that's 00:28:54 pretty big it's a pretty big uh mirror 00:28:57 and the sensor is also very big as well 00:28:59 so yeah it's a massive massive telescope 00:29:01 not the biggest but it's going to be the 00:29:03 most sensitive because of the 00:29:04 combination of the mirror and the sensor 00:29:07 uh and back to questions if there are 00:29:10 any did I miss anything 00:29:14 Uh, 00:29:16 okay. 00:29:21 Okay. Questions. I'm looking for the 00:29:21 questions mark. Question marks. 00:29:24 Uh, is the 10 to 12 year old mission 00:29:27 time standard? It's not. It's it's just 00:29:29 this is the minimal time uh for the 00:29:31 mission. They're hoping for more. It's 00:29:32 it basically depends on the funding. Uh 00:29:35 you might have heard that there's a we 00:29:36 don't know what's going to happen with 00:29:37 the funding for the National Science 00:29:38 Foundation. Uh so they already have 800 00:29:42 million prepared for this uh for the 00:29:45 next 10 years. That's the 10-year uh 00:29:46 mission plan. But if there's more 00:29:48 funding, they'll be able to continue it 00:29:49 indefinitely. Unlike uh unlike space 00:29:52 telescopes, this one this one can be 00:29:53 expanded, it can be repaired, it can be 00:29:55 improved. Uh so that's not really an 00:29:58 issue for uh for the mission on on on 00:30:01 Earth compared to a space telescope like 00:30:03 James Web. James Web does have a mission 00:30:05 limitation just because it's in space 00:30:07 and we're unable to repair it and we're 00:30:09 unable to fix it if something breaks. 00:30:12 Okay. Um, 00:30:15 okay. Someone's asking about a white 00:30:16 hole. Uh, white holes. No, never 00:30:18 detected. Sorry. Sorry. Never seen. 00:30:22 Uh, next question or concern. 00:30:25 Uh, do I think we'll ever inhabit Mars? 00:30:28 Not really. Probably not. Sorry. Also, 00:30:31 sorry. We we'll probably send some 00:30:33 robots and automated missions, but like 00:30:35 what would you do on Mars? Uh it's not 00:30:38 not fun. And also there's probably no 00:30:39 way back if you land. So like not not 00:30:43 for a while at least. Not this 00:30:44 definitely not this generation. Maybe 00:30:46 maybe in a few generations from now if 00:30:48 we get a little bit smarter, but not 00:30:49 yet. Um 00:30:52 c cool. So how we doing here? Not hasn't 00:30:56 started yet. Good. Uh so I was going to 00:30:58 go through Oh, here let me show you one 00:31:00 of the first pictures. They're probably 00:31:01 going to be showing this, too. So, this 00:31:04 this is this is what it's capable of. 00:31:06 Let me just remove my face from here. 00:31:09 This what you see in here is the most 00:31:11 detailed picture of one of the most 00:31:13 famous clusters uh Virgo cluster. I want 00:31:15 to show you what it looked like before. 00:31:18 This is the before picture. This is from 00:31:19 like I think a few years back uh when 00:31:22 they took it with the um DSS uh survey. 00:31:27 I think this was this is from the 00:31:29 European Southern Observatory. And now 00:31:32 the same picture kind of looks like 00:31:33 this. So absolutely mind-blowing detail 00:31:36 like just insane amount of detail. Uh 00:31:38 and here we'll be able to see things we 00:31:41 have never seen before from from uh from 00:31:43 the ground. Just ridiculous detail. Uh 00:31:47 I'm sure they will mention more about 00:31:49 this because I didn't really get any 00:31:50 detail either. I mean I got a picture 00:31:52 but that's about it. Uh hopefully when 00:31:54 we have the official official stream 00:31:56 from Vera Rubin Observatory, we'll we'll 00:31:59 get to hear and see more. But the reason 00:32:01 this Virgo cluster is important is 00:32:02 actually because this is one of the few 00:32:04 clusters where we we definitively see 00:32:06 effects from dark matter and it's really 00:32:08 important for dark matter research. And 00:32:10 so by seeing more uh we'll be able to 00:32:13 people scientists will be able to to 00:32:15 tell what's going on here. 00:32:19 Uh the black dots on the other picture 00:32:22 that was most likely just from the 00:32:24 telescope blocking the uh view. They 00:32:26 sometimes certain telescopes have uh 00:32:29 limitations. 00:32:31 Okay, cool. Cool. What's going on next? 00:32:33 Uh what else do we have? So what do we 00:32:35 know about this telescope? Well, first 00:32:37 of all, we know that the actual uh 00:32:39 planning started back in the late 1990s 00:32:43 and by early 2000s they actually started 00:32:45 building it. So it's been in 00:32:46 construction for a very long time. Um 00:32:50 and uh the main mission is to it's it's 00:32:53 sort of a continuation of the uh survey 00:32:55 missions. The the official surveys um 00:32:58 like the first surveys I guess started 00:33:01 like over 150 years ago with what we 00:33:04 used to call photographic plates. So 00:33:05 astronomers would used to take a look at 00:33:07 like a a spot in the night skies. They 00:33:10 would take a picture not a picture but a 00:33:11 photographic plate of that particular 00:33:13 location and then they would do this one 00:33:16 after another after another. uh and keep 00:33:18 them in uh some kind of a library 00:33:20 somewhere. I think I think Harvard 00:33:22 actually has one of the biggest ones and 00:33:24 these photographic plates were super 00:33:25 important for discovering a lot of 00:33:27 things about um astrophysics. For 00:33:30 example, that's how Hubble, the Edwin 00:33:32 Hubble was able to to prove that 00:33:34 universe even existed because he looked 00:33:36 at a photographic plate of the Andromeda 00:33:38 galaxy and he discovered a tiny tiny 00:33:40 piece a tiny tiny spot in there that 00:33:43 turned out to be a very important star. 00:33:45 And that star had to be super far away 00:33:47 for this to be real. And that gave him 00:33:50 sort of a clue that we're looking at 00:33:52 something super distant. And so the 00:33:54 universe must be massive compared to 00:33:56 what scientists thought before that. So, 00:33:58 photographic plates is how it all 00:33:59 started. But by 2000s, we had automated 00:34:03 uh surveys and one of the most famous 00:34:05 ones is called SDSS. Let me see if I can 00:34:07 get a website for this 00:34:10 or not. Didn't work. Okay, let's try 00:34:13 again. SDSS is here somewhere. Yeah, 00:34:17 Sloan Digital Sky Survey. So, that's 00:34:21 where that's our first um 00:34:24 Come back. Where are you? Here. SDSS. So 00:34:27 that's one of our first automated 00:34:29 surveys and it was pretty good. It's 00:34:30 it's still used today by a lot of 00:34:32 different astronomers. Uh this this 00:34:34 basically collected a very very large 00:34:36 amount of I guess equivalent of a 00:34:38 photographic plates but digital 00:34:40 photographic plates across the night 00:34:42 skies and created kind of a map of the 00:34:44 night skies for us. But uh because it 00:34:47 was not super high quality this is why 00:34:50 researchers needed something better and 00:34:52 that that was the birth of the uh this 00:34:54 particular telescope. 00:34:56 So, it's it's going to be the most 00:34:58 accurate, the most uh what's the other 00:35:02 word? The basically the biggest map of 00:35:05 the night skies, but unfortunately only 00:35:07 the southern skies because it's in 00:35:09 Chile, so it's only going to be focusing 00:35:10 on the southern hemisphere. So, we need 00:35:13 to have something similar in the north, 00:35:14 but unfortunately there's no similar 00:35:17 location in the north. Um, unless I 00:35:19 guess someone builds it somewhere in 00:35:21 like north Norway or something, but 00:35:23 hasn't happened yet. 00:35:25 And for the next 10 years, it's going to 00:35:27 be taking advantage of the Chileian 00:35:29 night skies, which are usually supposed 00:35:31 to be super clear and brilliant, uh, and 00:35:35 some of the darkest nights on Earth 00:35:37 actually, to conduct a very large 00:35:39 astronomical survey, 00:35:42 more ambitious than any previous 00:35:43 scientific project. 00:35:46 And one of its uh goals is also except 00:35:48 for dark matter and stuff, it's also 00:35:50 going to be studying uh near earth 00:35:51 asteroids which is actually a lot more 00:35:54 important for I guess uh earth defense. 00:35:58 Uh when it comes to earth defense um we 00:36:00 need to catch as many near-Earth 00:36:02 asteroids as possible. You might have 00:36:04 heard, you might remember the story from 00:36:06 about like a few months ago, the 00:36:08 asteroid that was discovered last 00:36:09 minute, the 2014 YV4 that was possibly 00:36:14 colliding with Earth, but suddenly was 00:36:15 colliding with the moon after that. So 00:36:18 that particular asteroid was discovered 00:36:20 last minute. But according to the 00:36:22 researchers um that were creating this 00:36:24 telescope, they basically said that we 00:36:26 would have found it a long time ago. So 00:36:28 it's going to be able to it's going to 00:36:30 be able to do all of this pretty 00:36:31 quickly. Uh, oh my god, someone gave a 00:36:34 lot of people memberships. Thank you so 00:36:36 much. How do I Wow, 50 memberships. 00:36:39 Thank you, Lucas. Amazing. Wow, that's 00:36:43 amazing. 00:36:44 Thank you so much. And thank you, Yuri, 00:36:47 for donating uh€ 10. 00:36:49 That's That's also my son's name. Um 00:36:53 anyway, so um what was I talking about? 00:36:58 Yeah, so asteroids. is going to be 00:36:59 finding a lot of asteroids, a lot of 00:37:00 comets, a lot of stuff in the solar 00:37:02 system. So for earth defense, it is 00:37:05 going to be abs. This mission is going 00:37:07 to be absolutely essential. And there's 00:37:08 also hope that if planet 9 is real, 00:37:11 which a lot of scientists now doubt 00:37:14 based on the on the video I made a few 00:37:16 months ago where someone uh there's a 00:37:18 team that discovered a dwarf planet that 00:37:21 potentially proves planet 9 uh wrong uh 00:37:25 planet 9 hypothesis. Uh but anyway, so 00:37:28 if it exists, this telescope should be 00:37:30 able to see something somewhere out 00:37:31 there. If not, then well, too bad. 00:37:34 Anyway, uh hello and welcome everyone 00:37:37 whoever just arrived to this stream. Uh 00:37:40 if I'm starting to struggle pronouncing 00:37:43 things and talking very slowly, it's 00:37:44 because it's almost midnight here. Uh I, 00:37:48 as some of you know, I am actually in 00:37:49 South Korea right now. So, it is going 00:37:52 to be pretty hard for me to talk after 00:37:54 after 1:00 a.m. mostly because I'm so 00:37:56 tired. But, we have about 5 minutes 00:37:58 before the stream starts. I'm going to 00:38:00 in in about 5 minutes and 30 seconds, 00:38:02 I'm going to shut up and we're going to 00:38:04 listen to what the uh stream by the uh 00:38:08 Vera Rubin Observatory has to say 00:38:10 because their stuff is going to be 00:38:11 really important or I guess more 00:38:13 important than what what I'm saying 00:38:15 because I'm kind of curious to hear what 00:38:16 they have to say too. Anyway, so apart 00:38:19 from the near-Earth asteroids and all 00:38:21 kinds of Kyper belt objects, um this 00:38:24 mission is also going to be looking or 00:38:26 finding a lot of different Nova, 00:38:28 supernova, all kinds of transients. 00:38:30 We're going to be seeing way way more 00:38:31 explosions in the night skies than ever 00:38:33 could before because of the way that it 00:38:35 is going to be taking pictures after 00:38:37 pictures and comparing them. Um so it's 00:38:40 going to be able to detect a lot of 00:38:41 transients in the night skies 00:38:43 and that's going to be super exciting. 00:38:45 And one of its uh missions is also to 00:38:47 map our galaxy. It's going to be mapping 00:38:49 the actual materials in the Milky Way um 00:38:53 contributing to the previous uh 00:38:55 discoveries by the Gaia mission and 00:38:58 which actually makes it a little bit 00:38:59 different from other telescopes. So we 00:39:00 do have some other powerful telescopes 00:39:02 like uh like I mentioned the mission 00:39:04 known as DESI uh dark energy survey 00:39:07 instrument and that one is kind of doing 00:39:10 something similar but it's looking 00:39:12 everywhere but the Milky Way. So it's 00:39:14 basically looking at other distant 00:39:15 galaxies. It's looking at galactic 00:39:17 clusters far far away. It's ignoring 00:39:19 most of the stuff in the Milky Way. This 00:39:21 telescope though is going to be looking 00:39:23 at everything including the Milky Way. 00:39:26 So this is why it's a little bit more 00:39:28 intriguing, more interesting. There's 00:39:29 basically has like a 00:39:32 collection of different things is going 00:39:34 to be presenting to uh to us and someone 00:39:38 out there is going to love it. no matter 00:39:39 what it presents, it's going to be a bit 00:39:41 of everything for everyone, which is 00:39:43 going to be super exciting, I think. Uh, 00:39:46 basically gives me a lot of hope because 00:39:48 nowadays it's kind of hard to find 00:39:50 exciting topics to talk about, 00:39:51 especially due to a lot of budget cuts. 00:39:54 Um, not a lot of good science has been 00:39:56 going on in the last few months, but 00:39:58 this will probably change it. So, we'll 00:40:00 have a lot of stuff to talk about in the 00:40:01 next few months. 00:40:03 Okay, what's going on? Uh, let's see. 00:40:05 What did I miss? Uh, Grover, thank you 00:40:09 so much for the donation. And how much 00:40:10 data will the sensor be able to capture? 00:40:12 Is it near real-time capture? So, that 00:40:15 part I don't know because I I know just 00:40:19 as much as you when it comes to the 00:40:20 actual technicals. Uh, I just know that 00:40:23 it's supposedly going to have 10 times 00:40:26 at least 10 times more capability 00:40:27 compared to previous uh surveys. So I 00:40:31 think actually if I if you look here at 00:40:33 the preview, it kind of shows you the 00:40:35 the visual representation of this. Let 00:40:38 me see. Uh so in a nutshell, as far as I 00:40:42 know, uh it's supposedly going to be 00:40:44 able to capture approximately um 00:40:49 where where is it? Hold on, let me find 00:40:50 it. I forgot how many exact images it's 00:40:53 going to be capturing. Oh, come back. 00:40:58 So every 30 seconds is going to be 00:41:01 capturing a picture somewhere out there 00:41:03 and it's going to be pointing the uh 00:41:06 actual the researchers are going to be 00:41:08 pointing the telescope at slightly 00:41:09 different parts of the night skies and 00:41:12 they're going to be able to capture huge 00:41:14 areas every single day. And so basically 00:41:17 after every single day they're hoping to 00:41:20 to capture as much as possible and do 00:41:22 this over and over and over again just 00:41:23 to in order to find um various 00:41:26 transients in order to find slight 00:41:28 deviations which might be different 00:41:30 asteroids and so on. Uh also wait 00:41:35 what else was it? Um so is it near 00:41:37 realtime capture? The actual capture is 00:41:39 real time but the data is obviously not 00:41:41 going to be accessed in real time as 00:41:44 with most telescopes. the amount of data 00:41:46 is just absolutely ridiculous. So, it it 00:41:49 will probably most likely have to be 00:41:50 processed first and then like maybe 00:41:52 after a week or two, possibly a few 00:41:54 months, we'll start getting some uh 00:41:56 processed data that researchers can use 00:41:57 for um for actual detections or for for 00:42:01 research. Uh like there was a there was 00:42:04 something I'm trying to remember which 00:42:06 telescope it was recently. There was a 00:42:07 telescope that suddenly released a lot 00:42:09 of data for everyone and we had an 00:42:12 enormous amount of papers coming out 00:42:14 just because the data was kind of stuck 00:42:15 and unprocessed. Uh so once the data is 00:42:18 processed usually you get a lot of 00:42:19 papers at the same time but in terms of 00:42:21 how much data a lot. I don't know 00:42:24 exactly how much but a lot. Uh it way 00:42:27 more than James for sure. Oh yeah yeah 00:42:30 here it says it says in this picture I 00:42:31 think one image would need 4K 00:42:34 highdeinition TVs. So whatever that 00:42:36 means in terabytes or gigabytes. So 00:42:39 basically a lot uh the the the actual 00:42:44 technical parts I'm not really familiar 00:42:46 with. 00:42:48 Uh okie dokie. What's 43 seconds? 42 00:42:52 seconds. Okay. We're almost there. Uh 00:42:53 okay. So let's see. We're once they 00:42:56 start talking and once there's something 00:43:00 here that needs to be listened to. I'm 00:43:02 going to switch. I'm going to turn 00:43:03 myself off and I'm going to let them do 00:43:05 the talking because this is an exciting 00:43:07 stream. It's we we only get these like 00:43:09 once a year. So, you know, it's 00:43:11 interesting to listen to this kind of 00:43:12 stuff. Um, 00:43:15 do we know what frame rate it is? Uh, 00:43:17 it's it's not really a frame rate 00:43:19 because it's just still taking pictures. 00:43:21 So, it's, you know, one picture per 00:43:23 frame. But, but it will be creating 00:43:25 these huge maps though. So, it's and the 00:43:27 maps will be changing slightly. Um, it 00:43:30 says every four nights approximately is 00:43:33 going to be changing the entire night 00:43:35 sky. So, yeah. So, I guess it's one 00:43:37 frame, no, 00:43:40 one frame, two frames per week. There we 00:43:42 go. Two frames per week approximately. 00:43:45 Uh, so, so that's the approximate uh 00:43:48 approximate frame rate. 00:43:51 Uh, 00:43:53 do does Ver Rubin Observatory have 00:43:55 continuous live streams from a website? 00:43:57 I don't think so. I don't think they 00:43:59 actually do this because you have to 00:44:01 remember it is still in a remote 00:44:03 location and uh they do need all of the 00:44:05 all the possible uh data that they can 00:44:08 get for the actual sending out the u the 00:44:12 processed information and stuff. So I 00:44:13 don't think they have a live stream but 00:44:15 I might be wrong. Some telescopes do 00:44:16 have a live stream not of the actual 00:44:18 night skies that they're looking at but 00:44:19 just like of I don't know parking lot 00:44:21 from outside or whatever. Uh, normally 00:44:24 these types of telescopes, they do not 00:44:26 they don't have actual live streams, 00:44:28 unfortunately. Although I'm sure if 00:44:29 someone can figure out how to do it, 00:44:31 it'll be that'll be great. Um, oh, so 00:44:35 someone actually asked a great question. 00:44:38 Dlay H, thank you so much for your 00:44:40 donation. And the question is, how do 00:44:42 they distinguish thousands of asteroids 00:44:44 from thousands of satellites? And that 00:44:46 is actually the biggest question that 00:44:47 just came up recently. Uh so there is an 00:44:51 algorithm that they use to try to avoid 00:44:55 uh detections of various satellites 00:44:57 especially because of the uh all of the 00:44:59 internet based satellites we have today. 00:45:01 Oh, something's happening. Um I'm going 00:45:04 to turn myself off in 5 seconds. But 00:45:06 anyway, yeah, so the long story short is 00:45:08 that it's an algorithm, but it is a huge 00:45:10 issue and I'm sure they'll mention it or 00:45:12 and if not, I'll talk talk about it 00:45:14 after they after they uh we get to watch 00:45:16 this. Let me see. Uh, let me see what to 00:45:19 turn this on. How to turn this on. I 00:45:21 need to turn this off. 00:45:24 I need to turn this off. I'm going to 00:45:25 come back in a couple minutes. Let's see 00:45:28 what uh what they talk about. And tasked 00:45:30 with the longest maybe ever 00:45:50 [Music] 00:45:50 Bringing the night sky to life. 00:46:13 [Applause] 00:46:13 Welcome. Welcome. On behalf of my 00:46:16 colleagues at the National Science 00:46:18 Foundation and the Department of 00:46:19 Energy's Office of Science, I welcome 00:46:22 everybody here and all those streaming 00:46:25 online. 00:46:27 This day marks a very special occasion 00:46:30 revealing and celebrating the first look 00:46:33 at the universe through the eyes of NSF 00:46:36 DOE Vera C. Reuben Observatory. As we 00:46:39 begin to bring online 00:46:42 priority for groundbased astronomy in 00:46:44 the National Academyy's 2010 decadal 00:46:46 survey, 00:46:48 we trust that you will enjoy this tiny 00:46:51 peak at the many discoveries to come and 00:46:54 we are very excited to show you. I am 00:46:58 Edward Aar, the NSF program director for 00:47:01 Reuben Observatory. 00:47:03 Before we begin, I would like to thank 00:47:05 the nationalmies for providing this 00:47:08 beautiful venue and excellent support 00:47:11 for this occasion. And now it is my 00:47:14 pleasure and honor to introduce to you 00:47:16 Brian Stone, NSF Chief of Staff, 00:47:19 performing the duties of the NSF 00:47:21 director. Please welcome Brian Stone. 00:47:25 [Applause] 00:47:34 Well, thank you, Ed, and thank you to 00:47:35 all of you for being here today. Uh, 00:47:38 starting today, our ability to 00:47:40 understand dark matter, dark energy, and 00:47:43 planetary defense will grow even faster 00:47:46 than ever before. This exciting new 00:47:48 future is thanks to the vision, work, 00:47:51 and support of the many people we're 00:47:53 proud to recognize here today. Let me 00:47:56 begin by thanking the White House Office 00:47:58 of Science and Technology Policy 00:47:59 Director Michael Katzios and the 00:48:02 administration for their continued 00:48:03 support of exploratory science. By 00:48:06 working across federal agencies, OSTP, 00:48:09 NSF, DOE, we turned shared investment 00:48:14 and coordination into a transformative 00:48:16 inter agency public private partnership. 00:48:19 The flagship observatory has been more 00:48:22 than 20 years in the making with NSF 00:48:25 behind the project every step. NSF 00:48:28 brought together a coalition of partners 00:48:30 to build and support the cutting edge 00:48:33 facility instrument and data management 00:48:36 systems. More than 40 international 00:48:38 organizations contributed to building 00:48:40 survey telescope with the ability to 00:48:42 gather more data than all other ground 00:48:45 and space-based optical telescopes in 00:48:47 history combined. 00:48:49 NSF is proud to continue to lead 00:48:52 Reubin's operations as it begins to 00:48:54 deliver on its promise to expand our 00:48:56 understanding of the universe. 00:48:59 Thank you to DOE, our international 00:49:02 partners in Chile, private donors like 00:49:04 Charles Simone, the nationalmies for 00:49:07 prioritizing Reubin and the 2020 uh 2010 00:49:10 astronomy and astrophysics decal survey 00:49:12 and the entire Reubin team, especially 00:49:14 Tony Tyson, a Reuben LSST chief 00:49:18 scientist who conceived and championed 00:49:20 this project from the start. 00:49:22 Vera Rubin is the namesake of this 00:49:24 facility because she is the symbol of 00:49:26 scientific excellence. Her legacy 00:49:28 reshaped astrophysics and our 00:49:30 understanding of dark matter. 00:49:32 Generations of researchers have been and 00:49:34 will continue to be inspired by her. 00:49:36 Alan Rubin, one of Vera's children who's 00:49:38 joining us here virtually today, once 00:49:41 told NSF, "Ver believed there is always 00:49:43 more to be discovered. So, let's keep 00:49:46 discovering together and proving her 00:49:48 right." Now, I hand it off to Kathy 00:49:51 Turner from the Department of Energy. 00:49:53 Thank you. 00:50:07 Hello everybody. We're incredibly 00:50:07 thrilled to be here today for the 00:50:08 unveiling of these new images from the 00:50:11 groundbreaking NSF DOE Very Rubin 00:50:13 Observatory. Just a preview of the data 00:50:16 to come. I'm Kathy Turner, program 00:50:19 manager for Reubin Observatory from the 00:50:21 Department of Energy, Office of Science. 00:50:24 Carrying out this project in partnership 00:50:26 with NSF and the private and 00:50:29 international partners has enabled us to 00:50:31 bring all of our strengths to this 00:50:33 amazing observatory. I am honored to 00:50:36 work with all of them and look forward 00:50:38 to our continued partnership. 00:50:41 This observatory represents a giant leap 00:50:44 in our ability to explore the cosmos and 00:50:47 unwrap the mysteries of the universe. Of 00:50:51 great interest also to the observatory's 00:50:53 namesake, Dr. Rubin. Now I'd like to 00:50:56 introduce Harriet Kung, our acting 00:50:59 director of the office of science at 00:51:01 Department of Energy. with decades of 00:51:04 experience in scientific leadership. Her 00:51:07 vision and dedication have made have 00:51:09 been instrumental in making this uh 00:51:12 amazing observatory a reality. Please 00:51:15 welcome Dr. Kun. 00:51:17 [Applause] 00:51:33 Good morning everyone. Thank you Kathy 00:51:33 for the wonderful introduction. 00:51:35 On behalf of the uh the US Department of 00:51:37 Energy, let me add my thanks to the long 00:51:40 list organization that has made today's 00:51:43 event possible. 00:51:45 First of all, nationalmies, I would 00:51:48 especially like to single out the board 00:51:49 on physics and astronomy and also the 00:51:52 space studies board for hosting us in 00:51:55 this beautiful auditorium today. I also 00:51:58 want to thank White House OSTP, 00:52:01 the National Science Foundation and also 00:52:04 the Association of Universities for 00:52:06 Research in Astronomy as well as my 00:52:08 colleagues in DOE Office of Science for 00:52:11 putting together the wonderful program 00:52:13 that will witness today. But let me 00:52:16 first introduce a short video from the 00:52:18 Secretary of Energy, Chris Wright, who 00:52:22 is not able to join us today, but he 00:52:24 took the time during his recent visit to 00:52:26 Slack National Accelerator Laboratory to 00:52:28 film the the video you'll be seeing 00:52:31 shortly. So, let's cue the video. 00:52:53 Today we celebrate the culmination of 00:52:53 two decades of scientific and 00:52:55 technological innovation have given us 00:52:58 an ability to look into the cosmos to 00:53:00 understand our universe itself. 00:53:03 This is the Vera Rubin telescope in 00:53:06 Chile. And I want to congratulate all of 00:53:09 those at the Department of Energy and 00:53:11 the National Science Foundation, those 00:53:13 working at Slack out here in California 00:53:15 where I'm standing right now, and those 00:53:17 on the ground in Chile for this 00:53:19 tremendous technological achievement 00:53:22 that truly will bring an understanding 00:53:24 of our universe simply not possible 00:53:27 before. 00:53:29 The movie is started, the camera is 00:53:31 running, and we're going to see our 00:53:33 cosmos unfold before us. Congrats to 00:53:36 all. 00:53:43 Thank you, Secretary Wright. 00:53:43 Having this event today um really feels 00:53:46 like a homecoming. 00:53:48 It was really the 2010 National Academy 00:53:52 study for astronomy and astrophysics 00:53:54 that recommended that our high energy 00:53:56 physics program partner with NSF on what 00:54:00 would become the Ruby Observatory which 00:54:02 was the one number one topranked 00:54:05 groundbased project. As Brian has 00:54:08 already mentioned, the NSF DOE Verosc 00:54:12 Rubin Observatory was a project long in 00:54:15 the making with many moving parts. The 00:54:18 DOE's Office of Science was proud to 00:54:20 lead the construction of the LSST cam, 00:54:24 the largest digital camera ever built. 00:54:27 It is size of a small car, but twice as 00:54:30 heavy. The camera boasting an impressive 00:54:34 3,200 megapixel resolution 00:54:38 was lovingly designed and fabricated by 00:54:42 scientists and engineers at Slack 00:54:44 National Accelerator Laboratory with 00:54:47 critical contributions from DOE other 00:54:50 national laboratories as well as 00:54:52 international partners. 00:54:54 This camera in conjunction with the Sony 00:54:57 survey telescope will create a 10-year 00:55:00 survey of the sky in the southern 00:55:02 hemisphere known as the legacy surveys 00:55:05 of space and time. 00:55:08 This treasure trove of data data set 00:55:10 will give researchers unprecedented 00:55:13 depth and clarity to questions that 00:55:17 drive the fundamental research supported 00:55:19 by the office of science. And some of 00:55:21 the questions include how can we better 00:55:25 understand the matter and energy that 00:55:27 makes up 95% of our universe and why is 00:55:32 our universe ever expanding quickly and 00:55:35 how is that pattern change over time and 00:55:38 also what role did dark matter play in 00:55:42 how our universe evolved. 00:55:45 We anticipate that the observatory will 00:55:47 give us many insights into our past, our 00:55:51 future, and possibly the fate of the 00:55:54 universe. 00:55:56 Answering these questions is a challenge 00:55:59 that is matted matched with the many 00:56:02 many talents that contributed to today's 00:56:05 success and the survey. And we at DOE 00:56:08 are extremely proud of the many people 00:56:10 that have contributed to this amazing 00:56:12 project. We're especially grateful for 00:56:16 the indispensable cooperations from our 00:56:18 international partners. 00:56:21 In particular, the success of the Reuben 00:56:23 Observatory relies on its location 00:56:28 Sarah Fishon in northern central Chile. 00:56:31 That's why I'm so pleased to introduce 00:56:34 to you his excellency, the ambassador of 00:56:37 Chile to the United States. Ambassador 00:56:41 Juan Gabrielle Valdez has dedicated his 00:56:44 career to fostering strong ties between 00:56:47 our nations. Please join me in welcoming 00:56:51 Ambassador Valdez. Thank you. 00:57:09 Good morning everyone. 00:57:09 Mr. Michael Katzio, director of the 00:57:12 White House Office of Science and 00:57:14 Technology Policy. 00:57:17 Mrs. Harriet Kung, acting director of 00:57:21 the Office of Science at the Department 00:57:23 of Energy. 00:57:24 Mr. Brian Stone performing the duties of 00:57:27 the director of the National Science 00:57:28 Foundation, 00:57:30 distinguished American and international 00:57:32 authorities, esteemed scientists and 00:57:35 friends of the National Academy of 00:57:37 Science who welcome us today. 00:57:40 I'm very happy to be here today. I have 00:57:42 to say that I have received 00:57:45 a number of calls from our friends 00:57:48 astronomers in Chile saying that I had 00:57:50 to be here today. Therefore, it's a 00:57:52 fortune to be representing them this 00:57:54 morning. 00:57:56 Chile is without a doubt an astronomical 00:57:59 nation. 00:58:01 Evidence of astronomical observation by 00:58:03 our earliest inhabitants that back dates 00:58:06 back more than 2,000 years before 00:58:09 Christ. 00:58:11 Our geography gives us clear, dry, and 00:58:13 stable ideal skies for observing the 00:58:16 stars. Astronomy is part of our identity 00:58:19 and our heritage and we are proud of it. 00:58:23 But it is not only nature that has led 00:58:25 us to become global leaders in 00:58:26 astronomical observation. It is also the 00:58:29 the result of our government decision, a 00:58:33 clear and sustained policy of 00:58:34 international cooperation, scientific 00:58:37 development and the protection of our 00:58:40 dark skies. 00:58:42 Today we celebrate the first images from 00:58:44 an extraordinary telescope, the Vera 00:58:46 Rubin Observatory, equipped with the 00:58:49 largest digital camera ever built for 00:58:51 astronomy. 00:58:53 But we also honor the memory of an 00:58:54 extraordinary woman. Vera Rubin was not 00:58:57 only a pioneer who uncovered key 00:59:00 evidence of dark matter, she was also an 00:59:05 inspiring example of integrity, 00:59:07 perseverance, and humanity. 00:59:09 Vera Rubin pushed the boundaries of 00:59:11 scientific knowledge but also her name 00:59:13 her her era. Naming this observatory up 00:59:16 for her after her is a profoundly 00:59:19 symbolic and just act. It sends a 00:59:22 message to new generations and 00:59:24 especially to the children and young 00:59:26 people of Chile and the world that 00:59:28 knowledge has no gender and that the 00:59:30 university is open to all. 00:59:33 Vera Rubin has been the inspirer, 00:59:37 the inspiration for the important and 00:59:40 growing number of women astronomers we 00:59:43 have in our country. 00:59:46 For Chile, the observatories represent 00:59:48 our commitment to knowledge, to 00:59:51 sustainable development, to 00:59:53 international cooperation, and to the 00:59:54 defense of dark skies. 00:59:57 The very 01:00:05 Okay. Okay. Uh, I did not expect so much 01:00:05 dialogue. Uh, I know some people are 01:00:08 getting restless. So am I, 01:00:09 unfortunately. So, uh, how is everyone 01:00:12 going? I actually really didn't think 01:00:15 there would be so many so much politics, 01:00:16 too. Let me just mute this a little bit. 01:00:19 There's a lot of dialogue, a lot of 01:00:21 introductions. 01:00:23 This is very different from what it was 01:00:25 like for the James Web or the Martian 01:00:27 missions. Here they do have a lot of uh 01:00:30 things they want to say. Anyway, um 01:00:32 let's while they're talking, while 01:00:34 they're thanking each other, uh let's 01:00:37 briefly go through some of the questions 01:00:38 or possibly maybe some concerns or Yeah, 01:00:41 by the way, please be nice. Yeah, 01:00:43 someone already got had to be muted 01:00:44 because of the comments they were 01:00:46 making. So, don't be mean or I'll mute 01:00:48 you. 01:00:50 Uh what am I doing here? All right, 01:00:52 let's go through some of the facts I 01:00:54 wanted to mention while they're talking. 01:00:56 Also, let's see. 01:00:59 Uh, okay. I'm going to I have it in my 01:01:03 ears. I'm going to make sure that we 01:01:04 don't miss anything. So, I'll switch to 01:01:06 the stream once they start announcing 01:01:07 the pictures because that's what we're 01:01:09 here for. 01:01:11 Um, 01:01:13 oh, okay. Wait, he start I think he 01:01:14 stopped talking. Um, one thing I 01:01:16 actually forgot to mention is that 01:01:21 Oh, what's happening? Hold on. 01:01:35 an assistant to the president for 01:01:35 science and technology. 01:01:37 Director Katzio previously served as 01:01:39 chief technology officer of the United 01:01:41 States during President Trump's first 01:01:44 term where he advised the president on 01:01:47 landmark initiatives in artificial 01:01:49 intelligence, 5G, quantum computing and 01:01:53 advanced manufacturing. 01:01:56 Looking back, many of these initiatives 01:01:58 not only had launched but have 01:02:08 Okay, uh I'm back. I think they're going 01:02:08 to be talking for a while. My apologies 01:02:10 if you actually want to watch this. Uh 01:02:11 the link for the actual stream is in the 01:02:13 description. Uh so I would like to focus 01:02:16 on actual science, not political 01:02:18 introductions. 01:02:20 So if you do have questions, please ask. 01:02:22 Well, one thing I forgot to mention is 01:02:24 that uh there was actually a sneak 01:02:25 preview of one of the short videos they 01:02:29 made or short pictures. Hopefully 01:02:30 they'll show it to us here as well. And 01:02:32 apparently this was uh done with,00 01:02:35 images um and in event uh actually 01:02:40 showed us approximately 20 billion 01:02:42 different u objects in the in the image 01:02:45 itself. But I don't know if we get to 01:02:47 see this today. Uh, 01:02:50 what? Wait, where did it go? Where are 01:02:53 my comments? Here we go. All right, here 01:02:55 we go. I think I have a question. Can 01:02:57 you explain for a second who Vera Rubin 01:02:59 was? Thank you for the donation and for 01:03:01 the question. QLCS appreciator. I 01:03:04 appreciate your question. So she um she 01:03:07 was a graduate student uh in I forgot 01:03:11 what university it was who was 01:03:13 essentially working on uh studying 01:03:15 different galaxies and studying galactic 01:03:17 curs of galaxies and I want to quickly 01:03:19 show her picture in case you never seen 01:03:20 who she was. Uh the picture the coolest 01:03:23 picture of her is actually here 01:03:24 somewhere here. This is probably the 01:03:26 coolest picture that I think is so far 01:03:29 at least. So here here she is. She's 01:03:32 working on one of the um 01:03:34 uh telescopes. Where was this? I I'm 01:03:37 sorry. I forgot where this was, but let 01:03:39 me let me see. It probably says it here 01:03:41 somewhere. Uh no, it doesn't say here. 01:03:45 Anyway, so she she was a uh astronomer 01:03:48 studying galactic curves and completely 01:03:50 by accident, she discovered that 01:03:51 something in those galactic curves 01:03:53 refers to the way galaxies spin uh 01:03:55 rotate. So normally, you know, galaxies, 01:03:57 they spin pretty slow, right? uh but uh 01:04:00 we we have ways to me of measuring their 01:04:02 rotation speed by looking at the red 01:04:04 shift and the blue shift of various 01:04:06 parts of the galaxies. And um in an 01:04:09 essence in essence if you were to to 01:04:11 simulate this it kind of looks like this 01:04:14 kind of looks like this here. 01:04:19 Here's what it sort of looks like. So we 01:04:22 always expected galactic curves to look 01:04:24 this way essentially. You know, we think 01:04:26 of a solar system, right? In the solar 01:04:29 system, uh, planets like Mercury will be 01:04:32 spinning around the sun much faster. 01:04:34 Planets like Earth will be spinning a 01:04:35 little bit slower. Planets like Jupiter 01:04:37 will be spinning much slower because 01:04:38 they're much farther away from the sun. 01:04:40 And that's what was expected of 01:04:41 galaxies. And when she looked at those 01:04:44 galactic curves of several different 01:04:45 galaxies, including Andromeda, she found 01:04:47 something completely different. The 01:04:48 entire galaxy was spinning as if it was 01:04:50 a disc. Like it was literally the actual 01:04:53 curve was flat. And uh because of this 01:04:58 the she she by herself she kind of 01:05:00 started doing a lot of measurements and 01:05:01 discovered this in a lot of different 01:05:02 galaxies. And her explanation was that 01:05:06 there must be something in the galaxy 01:05:08 that we're not seeing some kind of a 01:05:10 dark matter that uh is making the galaxy 01:05:13 spin this way because it made no sense 01:05:14 otherwise the galaxy would basically fly 01:05:17 apart completely. And so she was the 01:05:19 first to kind of bring it uh into 01:05:20 attention and uh ever since then for 01:05:24 years for decades really this was 01:05:26 studied over and over and it was 01:05:27 confirmed by many different astronomers 01:05:29 and so she was the one who discovered 01:05:31 it. But um the reason the teles I mean 01:05:33 unofficial reason that the the telescope 01:05:35 is named after her is because 01:05:38 of this discovery everyone expect her to 01:05:39 get a Nobel Prize um and she didn't and 01:05:43 she passed away without any you know 01:05:45 claims any anything uh nothing named 01:05:49 after her nothing really important was 01:05:50 kind of uh uh surrounding her legacy and 01:05:53 a lot of scientists were super upset 01:05:55 about this and so this telescope which 01:05:57 was originally known as LL LSST I think 01:06:02 uh what was the name of the telescope? 01:06:03 It was used to be known as 01:06:05 large 01:06:07 synoptic survey telescope. LSST, large 01:06:10 synoptic survey telescope. That's the 01:06:11 name of the technology it's using. Um 01:06:14 and 01:06:16 so a lot of scientists basically sat 01:06:18 together and voted on it and decided 01:06:20 we're naming it Vera Rubin telescope 01:06:22 because she deserves to have something 01:06:23 named after her. Um, and so a year after 01:06:26 she passed away, it was officially 01:06:28 announced that this is now going to be 01:06:29 known as Ver Rubin telescope because one 01:06:31 of its missions is of course to study 01:06:33 dark matter. 01:06:35 So there you have it. That's kind of who 01:06:37 she was and that's the main mission 01:06:38 behind it. Unfortunat I I was really 01:06:40 expecting to talk about it because 01:06:41 that's such an important part of Legacy. 01:06:43 I I don't even know enough about Ver 01:06:45 Rubin myself to to uh to explain. 01:06:48 Obviously, I've never met her, 01:06:49 unfortunately. And she was super old uh 01:06:52 by the time I became interested in 01:06:54 astronomy. So, she was I don't think she 01:06:57 was doing research by uh by then. 01:07:00 Anyway, uh if you have any questions, 01:07:02 let me know. Uh, I'm going to be going 01:07:03 back and forth in between their stream 01:07:05 and I guess my stream, but I'm mostly 01:07:08 focusing on scientific questions and 01:07:09 anything you want to know about, I 01:07:11 guess, the universe or dark matter or 01:07:12 whatever. Um, 01:07:15 and please don't uh don't be mean and so 01:07:18 on and so forth. Uh, and also 01:07:24 and also 01:07:26 Oh, okay. That's there's another 01:07:27 question. There's another question from 01:07:28 Gary Scaran. Why are some galaxies 01:07:30 barred like ours? Uh that's that's a 01:07:33 question nobody knows. Uh because 01:07:36 the way that bars were explained in the 01:07:38 past is that it's a it's a kind of a 01:07:40 structure that seems to form when the 01:07:41 galaxy be when the this galaxy beame 01:07:44 becomes stabilized and um bars seem to 01:07:47 actually influence galactic evolution as 01:07:49 well. But the actual formation is not 01:07:51 entirely understood very well. And dark 01:07:53 matter potentially plays a role but it's 01:07:55 not certain. Uh right now it's it's one 01:07:57 of those open questions especially since 01:08:00 bar galaxies have now been discovered by 01:08:02 the James web. Um some of them are mere 01:08:06 hundreds of millions of years old and 01:08:07 makes no sense. So right now uh right 01:08:11 now it's basically uncertain how they 01:08:13 form. Nobody knows. U I'm I'm sure it 01:08:16 will be at some point explained maybe in 01:08:18 the next few decades and hopefully 01:08:19 because of this telescope. Right now 01:08:20 it's a mystery. Uh okay, next question. 01:08:26 Let me see. Let me see. Uh, Vasper 01:08:30 Valentine, thank you so much for the 01:08:31 donation. I've been watching for years 01:08:33 and wanted to say thank you. No, thank 01:08:35 you. Thank you for watching because 01:08:36 that's basically why I do this. Someone 01:08:38 asked me what I do nowadays for work. 01:08:40 Basically, this uh I'm really grateful 01:08:43 to all the Patreon supporters and 01:08:44 everyone uh on this channel. uh over the 01:08:46 years uh basically ever since co started 01:08:49 I had to take a pause uh also after 01:08:52 there was a tra we had family tragedy a 01:08:54 few years back some of you might know 01:08:56 what it is uh I I took a break from 01:08:58 teaching I used to teach math and I just 01:09:00 couldn't do it anymore uh just because 01:09:02 it was too painful and uh started doing 01:09:05 this full-time so it's been three years 01:09:07 now full-time YouTubing we'll we'll see 01:09:09 we'll see how it goes it I might have to 01:09:11 go back to teaching if if I find a if I 01:09:15 find a position somewhere. Um, 01:09:20 oh, thank you. Someone actually 01:09:21 corrected me. Ruben was granted honorary 01:09:23 doctorate from Harvard, Yale, Smith 01:09:25 College, Grinal College, and Princeton. 01:09:28 That's awesome. Yeah, she definitely 01:09:29 deserves it. I mean, she she's done a 01:09:30 lot of research. That was absolutely 01:09:32 groundbreaking. Uh, can Ruben Oh, what's 01:09:36 happening? Okay, wait, hold on. Oh, here 01:09:39 we go. 01:09:49 today. 01:09:49 This is the first image. 01:09:58 Thank you for your reaction. 01:09:58 But now that we looked at this image, I 01:10:01 have to reveal a fun fact. 01:10:04 This image actually shows only a small 01:10:08 portion of one Reuben image. just about 01:10:12 2%. 01:10:18 In other words, the entire Reuben image 01:10:18 is 50 times larger than what we are 01:10:22 seeing here on the screen. 01:10:25 So you may wonder 01:10:28 why didn't we show the entire image. 01:10:31 Let us see why. 01:10:39 Reuben Observatory including its Simony 01:10:39 survey telescope in the middle, LSSD 01:10:42 camera on the left and an exquisite 01:10:44 software framework is designed to make 01:10:48 huge images rapidly. 01:10:51 These three components you can see on 01:10:53 the screen and their technological 01:10:56 breakthroughs is what makes Reuben and 01:10:59 LSST possible. 01:11:02 Let us first have a quick look at the 01:11:04 super agile Simony survey telescope in 01:11:07 the middle. You will notice the color 01:11:10 scheme is matching everywhere and indeed 01:11:13 my official Ruben Thai is modeled after 01:11:17 the telescope. 01:11:27 Here you can see Simony survey telescope 01:11:27 inside observatory's dome. The point of 01:11:31 this short video is to demonstrate the 01:11:35 amazing ability and agility of this 300 01:11:39 ton telescope. 01:11:42 No other large telescope in the world 01:11:45 can move this fast. It moves around in 01:11:48 seconds. Other large telescopes take 01:11:51 minutes. 01:11:58 Let us now look quickly at the LSSD 01:11:58 camera. This big beautiful camera is 01:12:02 already in the Guinness Book of Records 01:12:05 as the largest astronomical camera ever 01:12:07 made. It makes huge images. As we just 01:12:11 heard, just one Reuben image covers sky 01:12:16 area equal to 45 full moons with its 01:12:20 3,200 01:12:22 megapixels. 01:12:24 But that many pixels makes it very hard 01:12:28 to display such an image. 01:12:31 This is more pixels than the human eyes, 01:12:35 your eyes, my eyes 01:12:38 can see. 01:12:40 And this is the main reason why we could 01:12:43 not show you the entire image right 01:12:46 away, but only this small image shown in 01:12:51 the bottom right. You can see its 01:12:54 relative size to the full field of view 01:12:57 in this small rectangle at the bottom. 01:13:02 As director Gratzio pointed out, we 01:13:05 would need 400 01:13:07 highdefin televisions to properly 01:13:10 display just one Reuben image so that 01:13:13 your eyes could capture all the detail. 01:13:17 That means covering a basketball court 01:13:20 with 400 TVs. 01:13:23 to display just one image so that your 01:13:25 eyes can see all the detail. 01:13:29 But instead of looking at 400 TV screens 01:13:33 or walking around the basketball court, 01:13:36 our team has developed a powerful web 01:13:39 display tool that we can use to move 01:13:42 around our giant images. We can zoom in 01:13:46 and zoom out. We can explore and admire 01:13:50 details of any object you choose to look 01:13:53 at. 01:14:01 Next, we will look at a region of sky 01:14:01 about twice as large as one Reuben 01:14:04 image. 01:14:05 It is centered on the giant elliptical 01:14:08 galaxy called Messier 49. This region 01:14:12 that we'll explore in a second is about 01:14:15 100 times as large as the first image we 01:14:18 saw today. 01:14:20 The follow video is 1 minute long and we 01:14:23 will first enjoy it without any 01:14:24 comments. Then we will replay it and I 01:14:26 will comment. 01:14:29 Enjoy. 01:14:59 [Music] 01:14:59 Why? 01:15:14 We will look at it again. Before we 01:15:14 start, I want to say that the entire 01:15:18 Reuben team is so excited about this 01:15:22 data. We have been talking about this 01:15:25 data for over two decades. It's finally 01:15:28 here. 01:15:35 [Music] 01:15:35 Let's look at it again. 01:15:43 Please pause. 01:15:43 You can see here a universe teeming with 01:15:46 stars and galaxies. 01:15:48 The seemingly empty black pockets of 01:15:51 space between stars in the night sky. 01:15:54 When you look at it with unaded eyes are 01:15:58 transformed here into these glittering 01:16:00 tapestries. There is barely a pixel in 01:16:03 this image that doesn't have some light 01:16:05 coming out. And only Reuben can produce 01:16:09 quickly such large images with this much 01:16:12 color and richness. 01:16:15 Please continue. Play. 01:16:21 You can see spiral galaxies, elliptical 01:16:21 galaxies, 01:16:24 clusters of galaxies. 01:16:39 Please pause here. 01:16:39 This is an amazing region. We need to 01:16:41 stop here. I love it. 01:16:43 Do you love it? 01:16:46 Everybody loves it. 01:16:57 you can see a stunning variety of 01:16:57 celestial objects from bright stars in 01:17:00 our galaxy ranging in colors from blue 01:17:02 to red to these nearby blue spiral 01:17:05 galaxies to more distance distant 01:17:08 elliptical galaxies that are yellow and 01:17:11 red in color. You can see how vividly 01:17:15 these colors are and that's very 01:17:18 important for science. 01:17:20 Colors of galaxies are very important 01:17:22 because using these colors we estimate 01:17:26 distances to these galaxies. You can 01:17:29 also note in this image that galaxies 01:17:31 are not randomly distributed in it but 01:17:34 they are clumped. 01:17:35 They show clumping and statistical 01:17:38 details of that clumping and distances 01:17:41 to these galaxies determined from LSSD 01:17:44 colors will enable very precise 01:17:48 unprecedentedly precise studies of the 01:17:51 expansion history of the universe and 01:17:54 studies of dark matter and dark energy. 01:17:57 That's what we measure where these 01:17:58 galaxies are, how big they are and what 01:18:00 are their colors. And in few years, LSST 01:18:04 will be producing unprecedented 01:18:06 cosmological results. Let's continue. 01:18:22 And now you can see the full extent of 01:18:22 that image. It's about two LSSD or 01:18:25 Reuben fields of view. And this is how 01:18:28 we scan the sky, 30 second per exposure. 01:18:32 There were about 10 million galaxies, 01:18:35 close to 10 million in that image. 01:18:51 Thank you. This slide shows again the 01:18:51 whole area that we just looked at at the 01:18:54 end of video with the first image from 01:18:57 today outlined in the top left corner. 01:19:00 That small portion where your eyes could 01:19:03 tell the detail. Known objects here are 01:19:06 annotated with their names. And you may 01:19:08 notice that most faint objects do not 01:19:12 have their names shown. And that's 01:19:14 because they have not been studied 01:19:16 before. Most of these objects have never 01:19:19 been seen by people before. 01:19:22 As we already discussed it in this 01:19:24 projection, you simply cannot see all 01:19:27 the details in this image because our 01:19:30 human eyes and our screens are not good 01:19:33 enough and large enough. There is so 01:19:36 much more in this image that you can 01:19:38 enjoy that you could see in that one 01:19:41 minute video. And you can actually do it 01:19:44 yourself later at home using our tool 01:19:47 that we developed for this purpose. All 01:19:50 you need is internet and at the end of 01:19:54 presentation I'll give you QR code with 01:19:56 a link and now I'm talking to our 01:19:58 colleagues and friends on on uh on the 01:20:01 internet watching us through YouTube. At 01:20:04 the end of presentation you can get you 01:20:05 will get the link and then you can spend 01:20:07 the rest of your day enjoying 01:20:10 these 10 million galaxies. 01:20:18 We hope you enjoyed it. 01:20:18 But there is more to show you today. 01:20:21 Much more. 01:20:23 Imagine now an image like what we just 01:20:26 looked at. But imagine it thousand times 01:20:30 larger. 01:20:32 That would be half of the sky or the 01:20:34 entire sky visible from Chile. That 01:20:37 thousand times larger image than this 01:20:40 giant image we just looked at. This is 01:20:43 LSST. 01:20:44 Reubin's main goal for the next 10 01:20:47 years. 01:20:50 But LSST will be so much more than just 01:20:53 an image. Even though such great large 01:20:56 image, it will be so much more than just 01:20:59 an image. 01:21:01 And that is because every object 01:21:04 included in LSSD 01:21:06 about 40 billion of them for the first 01:21:10 time more celestial objects than living 01:21:13 people on Earth. 01:21:15 Every object will be imaged about 800 01:21:18 times 01:21:20 during these 10 years that it will take 01:21:22 to deliver LSST. 01:21:25 And that brings us to the greatest movie 01:21:27 of all time, LSST. 01:21:30 Because we will have 800 different 01:21:32 observations, we can take these frames, 01:21:34 we can put them in a movie, a digital 01:21:37 color movie of the night sky. 01:21:44 As I said, Reuben Observatory is the 01:21:44 greatest astronomical discovery machine 01:21:48 ever built. 01:21:49 So, let's see quickly what makes it so 01:21:52 uniquely powerful. 01:21:55 Most importantly, it can scan the sky 01:21:57 super fast, about 10 to 100 times faster 01:22:01 than any other large telescope. This is 01:22:05 like comparing the speed of your car to 01:22:08 the speed of an airplane. That's what we 01:22:10 are doing. Instead of driving around 01:22:13 from east to west coast for many days, 01:22:16 we pop on a plane and we are there in 01:22:18 five hours. That's what we are 01:22:19 introducing here. 01:22:22 It took us few nights to collect data we 01:22:25 are showcasing today. With existing 01:22:28 facilities before Reuben, it would have 01:22:30 taken at least a year and maybe more. 01:22:34 And LSST would take thousand years which 01:22:38 is obviously impractical, not 10 years. 01:22:41 This is why we had to build Rubin 01:22:43 Observatory. 01:22:49 And so let's talk now a little bit about 01:22:50 movies. 01:22:51 We have couple of trailers to show you. 01:22:56 So objects we we make movies of the 01:22:58 night sky to see two things. Objects 01:23:00 that move and objects that change 01:23:02 brightness. 01:23:04 So objects that move come in two 01:23:07 flavors. Stars in our galaxies galaxy 01:23:09 move and they move slow. We detect it 01:23:13 but it's slow. Much faster objects are 01:23:15 asteroids and they are in our solar 01:23:18 system. And so we'll focus now on 01:23:21 asterids that we discovered in those few 01:23:23 nights of data. 01:23:26 So here nothing is moving yet. This is 01:23:28 just to show you tiny portion of that 01:23:30 image that we will zoom in to discuss 01:23:34 asteroids. 01:23:35 Nothing is moving here 01:23:38 either. What you can see is two spiral 01:23:42 galaxies. 01:23:44 What you cannot see is that these two 01:23:47 beautiful galaxies were photobombed 01:23:50 by asteroids. Let us see how. 01:23:56 Here you can see asteroids as colored 01:23:59 streaks. They are not satellites. They 01:24:02 are asterids that move during exposure. 01:24:05 And this color image is made by 01:24:07 combining many individual exposures. But 01:24:10 asteris because they move they disappear 01:24:13 after you got one picture of them one 01:24:16 exposure. So these colors correspond to 01:24:18 the principal colors used to construct 01:24:20 color image. So you have red, you have 01:24:23 green, you have blue. 01:24:26 And so these asteroids when we combine 01:24:28 the image we can remove them. Our 01:24:31 software is smart enough to recognize 01:24:34 them and remove them. remove the streaks 01:24:38 when combining individual images. This 01:24:41 is why you did not see them before. But 01:24:44 now we will focus on asteroids. 01:24:52 It's another one minute video. It 01:24:52 showcases our unprecedented ability to 01:24:56 detect small objects orbiting the sun. 01:24:59 You can see motion against the static 01:25:01 background of stars and galaxies. 01:25:04 And we are only showing asteroids 01:25:06 discovered by Reuben, not previously 01:25:08 known asteroids. These are all new 01:25:11 discoveries that were reported to the 01:25:14 Minor Planet Center at Harvard this 01:25:16 morning. 01:25:18 There are so many of them. 01:25:25 Just a few nights of data, just one tiny 01:25:25 region on the sky. 01:25:36 And now you will see their location in 01:25:36 solar system. 01:25:40 Let's pause here. 01:25:43 So this blue donut this is simulation of 01:25:47 all the asteroids we expect there. And 01:25:49 because we only spent few nights to get 01:25:52 this data and we looked towards one 01:25:54 small region on the sky. All of these 01:25:56 new discoveries are found in this one 01:25:59 narrow slice of this big donut. In two 01:26:02 or three years after we start LSST later 01:26:05 this year, we will sweep around and 01:26:08 discover all of these millions of 01:26:10 asteroids. 01:26:12 So we had 2,000 in this few nights of 01:26:15 data. There are seven near Earth objects 01:26:18 that have orbits that cross Earth's 01:26:20 orbit. None of them is in such position 01:26:24 to strike Earth. Don't worry, 01:26:27 we'll get tens of thousands more 01:26:29 near-Earth objects and we will discover 01:26:32 about 5 million new asteroids during the 01:26:37 next few years with LSST. This is five 01:26:41 times more than all the astronomers in 01:26:44 the world discovered during last 200 01:26:48 years since the discovery of the first 01:26:50 asteroid. 01:26:52 So because of this rapid development of 01:26:55 technology today we can outdo all these 01:26:58 two centuries of effort in just couple 01:27:01 of years. 01:27:07 Let us now see another illustration of 01:27:07 the everchanging night sky. We will look 01:27:10 at objects that change their brightness. 01:27:13 They don't move but they change the way 01:27:15 they look. We will look at stars that 01:27:17 are called variable stars because they 01:27:20 vary in brightness. 01:27:21 They can change brightness on time 01:27:23 scales from minutes to years and by the 01:27:26 end of LSST we'll have data we will know 01:27:29 of about few hundred million variable 01:27:33 stars. This is mindboggling to people 01:27:35 who work in this field. LSST will also 01:27:39 discover a few million supernovi. 01:27:42 Supernovi are exploding dying stars that 01:27:45 are very important for cosmology 01:27:48 because it's relatively easy to estimate 01:27:51 their distance. We will now take a 01:27:53 detailed look at a few variable stars 01:27:55 called RLI. 01:27:57 They can become twice as bright in only 01:28:00 few minutes, half an hour. That's why we 01:28:02 chose them for this presentation. They 01:28:04 are in reality about 50 times more 01:28:07 luminous than our sun. And they change 01:28:09 brightness because because the whole 01:28:11 star is pulsating like this on time 01:28:14 scale of some hours. 01:28:21 They are also very useful for studying 01:28:21 dark matter in our galaxy because we can 01:28:23 get their distances easily too. Here is 01:28:26 see this blue star. It's blue because 01:28:28 it's hotter than our sun. Our sun would 01:28:30 look yellow in this image. 01:28:33 And here we are comparing its 01:28:35 brightness. Please pause here. 01:28:39 So what you can see is color image of 01:28:42 that star average color image and these 01:28:44 two observations show its brightness in 01:28:46 individual images and the one in the 01:28:49 middle is 30% brighter than the one on 01:28:52 your right. It is hard to tell with your 01:28:56 eyes but it is very easily measurable in 01:29:00 our high quality images with our high 01:29:03 quality software that goes through those 01:29:06 images. Let's continue. We'll see a few 01:29:08 more. Roly, 01:29:10 the next example is even harder to tell 01:29:13 with your eyes. It's only 11%. 01:29:16 But again, for our 01:29:19 powerful, precise software that looks at 01:29:22 it, we know it's 11% and not 10 or 12. 01:29:27 All these stars are found in our home 01:29:29 galaxy, the Milky Way. It's easy to get 01:29:32 their distance to distances much further 01:29:34 than we can do today. And so over the 01:29:36 next few years, we will map the 01:29:39 distribution in the outskirts of our 01:29:41 galaxy of both stars and dark matter 01:29:44 more precisely than ever before. 01:29:47 [Music] 01:29:51 As you can see, the strength of Reuben 01:29:53 and LSSD is in huge images, 01:29:58 in fast scanning of night sky, 01:30:02 in discovery of huge samples of billions 01:30:05 of celestial sources and in studies of 01:30:09 those sources with time. How they vary 01:30:12 with time? Do they move? Do they change 01:30:13 brightness? And that is the real purpose 01:30:16 why we built Rubin Observatory. 01:30:20 But there is one more thing to tell you 01:30:22 today. As we look at the sky, we don't 01:30:25 only collect huge samples. We make 01:30:28 images of beautiful objects. And so 01:30:31 today we want to share with you few 01:30:34 beautiful objects. And we chose the 01:30:37 Triffid and Lagoon nebula. These nebula 01:30:40 are giant clouds of gas and dust and 01:30:42 they represent stellar nurseries. They 01:30:46 are places in our galaxy where new baby 01:30:48 stars are born by those clouds 01:30:50 collapsing and becoming hotter and 01:30:52 denser until you end up with a protoar 01:30:55 with a young star in the center. 01:30:59 So this is the whole image. There are 01:31:01 two nebula. Top right is the triffet 01:31:03 nebula. This pink nebula in the bottom 01:31:07 is called the lagoon nebula. Again, this 01:31:10 image is very large. It's about as large 01:31:13 as entire Reuben image. And your eyes 01:31:16 and our screen are not good enough to 01:31:19 display all the detail that we recorded 01:31:22 in that region. Again, we will show 01:31:26 through video that zooms in around all 01:31:29 the vivid detail that is captured in 01:31:32 that image. 01:31:34 So ready. Warp one engage. 01:31:43 [Music] 01:31:43 Wrong video. How did that happen? 01:31:57 [Music] 01:31:57 All right, 01:31:59 we will have to leave that for later. 01:32:02 So let me say a few words about what's 01:32:04 next for us. That video by the way you 01:32:08 can see when you follow the link from 01:32:09 before. So nothing much is lost. You can 01:32:11 enjoy it later. 01:32:13 So 01:32:19 we've just seen mesmerizing treasure 01:32:19 trove of the stuff that LSST will start 01:32:22 producing. We are getting to the close 01:32:25 of the construction project. We are not 01:32:27 done yet. We have some commissioning 01:32:29 work to complete, some verification work 01:32:32 to complete. But in a few months, we 01:32:34 expect the project to be completed. We 01:32:37 go into operations and we will start 01:32:40 this greatest digital movie of the night 01:32:43 sky later this year and it will go for 01:32:46 10 years. 01:32:48 We did not talk today about much about 01:32:51 science, but I do want to mention over 01:32:55 2,000 01:32:56 LSST scientists who are eagerly awaiting 01:33:00 the start of LSST survey. We want to 01:33:03 thank them today. Thank them for helping 01:33:06 us to arrive to this point with their 01:33:09 support and expertise. They helped us 01:33:12 first build the science case for LSSD 01:33:16 that led to LSSD being ranked number one 01:33:20 in NASDAQL survey in 2010 and they also 01:33:25 are helping us to build Rubin 01:33:27 Observatory. They are organized in eight 01:33:30 topical science collaborations and they 01:33:33 greatly benefit from the supporting 01:33:35 nonprofit organization called LSST 01:33:38 Discovery Alliance. 01:33:40 It's formerly known as LSST Corporation 01:33:44 and that is organization that started 01:33:46 this project. But I also want to 01:33:48 emphasize it is not just the scientists 01:33:51 who will enjoy LSST data. It is everyone 01:33:55 everyone with curious mind interested in 01:33:58 what's up there. Every child in school 01:34:01 we will have tools and materials that 01:34:03 our education and public outreach team 01:34:06 produced that you can use to be citizen 01:34:09 scientist that you can see in videos in 01:34:12 planetaria that if you're a teacher in 01:34:14 high schools it maps on your science 01:34:16 curriculum. All of these will be 01:34:18 available from that link QR code in this 01:34:22 in this slide. 01:34:25 And so now I will finally finish this 01:34:27 brief presentation. The entire Ruben 01:34:30 team and let me add that I was greatly 01:34:34 honored by our Reuben team to represent 01:34:38 us today. The entire Rubin team hopes 01:34:42 that you enjoy this presentation. Please 01:34:44 stay tuned for the exciting discoveries 01:34:47 expected from LSSD over next 10 years 01:34:49 and beyond. 01:34:51 Thank you all here. Thank you all who 01:34:54 are watching us over internet. 01:34:57 Hundreds of locations in the US and 01:34:59 Chile. Thank you and much gracias. Thank 01:35:02 you to several hundred close to 300 01:35:05 other locations around the globe. 01:35:09 And thank you for being with us today. 01:35:11 And a big thank you to Slack and ARA, 01:35:14 our managing organizations. 01:35:16 Heartful thank to our funding agencies 01:35:18 NSF and DOE, to our awesome program 01:35:21 officers, Dr. Edar, Dr. Katy Turner. 01:35:25 Thank you. Thank you. Thank you. And 01:35:27 finally, we are all very grateful. 01:35:31 Okay. Uh he is thanking everyone and 01:35:36 that's great but also we have so many 01:35:39 questions that we get to uh we didn't 01:35:40 get to answer. Um okay so I think that's 01:35:44 pretty much it for the stream for their 01:35:46 stream. Uh oh wait unless there's a Q&A. 01:35:48 Is there a Q&A? Hold on a second. 01:35:55 Probably not. 01:35:55 I'm going to listen with one ear. Um, so 01:35:58 before we finish the stream, I just 01:35:59 wanted to go through a very, very quick 01:36:02 Q&A from I guess my side because I'm 01:36:04 sure there are probably a lot of 01:36:05 questions. I'll try to answer everything 01:36:07 I can, but I cannot answer everything. 01:36:09 Oh, wait. 01:36:16 Oh, there's there's more. Oh, there's a 01:36:16 panel. 01:36:18 Okay. Uh, yeah, there is a question Q&A. 01:36:22 All right. So, uh, 01:36:24 I'm going to turn back their stream once 01:36:28 they start answering the questions. Um, 01:36:30 one question I didn't get to answer here 01:36:32 was someone was asking me, can they can 01:36:34 this telescope see technic signatures? 01:36:36 The answer is very likely big no. Mostly 01:36:39 because that's not its main purpose and 01:36:40 uh, technic signatures is is an open 01:36:43 field. We don't really even know what to 01:36:44 look for. Uh normally when it comes to 01:36:46 techno signatures, researchers look for 01:36:49 specific uh wavelengths of light and uh 01:36:51 you have to be able to see an actual 01:36:53 star system in a planet. That's not the 01:36:55 main mission for this telescope. It's 01:36:56 it's mostly think of this as a kind of a 01:36:59 uh I guess it's creating kind of a 01:37:01 Google Earth of the universe is 01:37:03 basically creating a massive amount of 01:37:04 data, a map of the entire uh southern uh 01:37:08 night skies. That's that's that's why 01:37:10 it's probably not going to be good at 01:37:11 detecting techn signatures. Uh, also 01:37:15 there was another question, but I 01:37:16 already forgot what it was. But, uh, 01:37:18 during this during the stream, we uh did 01:37:21 get to see how good it is at detecting 01:37:23 asteroids. Within just a few hours, it 01:37:24 was able to detect thousands of 01:37:26 different near-Earth asteroids. And 01:37:28 that's just mind-blowing. Like, imagine 01:37:30 in in the next year or so, we'll have 01:37:31 like millions of asteroids to to to 01:37:34 study or at least to um to study their 01:37:37 orbits, making sure that they're not 01:37:38 dangerous because that's really one of 01:37:40 the main missions here. And it was 01:37:42 really cool how they explained how it's 01:37:44 able to re um uh it's able to see the 01:37:46 variable stars um extremely well and 01:37:49 thus helping researchers um 01:37:53 uh establish distances to various 01:37:55 objects. So um when it comes to variable 01:37:59 stars such as sephiid variables which 01:38:01 are probably the most famous ones that's 01:38:03 the stars that kind of like they they 01:38:04 they blink but they blink with a 01:38:06 pattern. Um, oh wait, there's a 01:38:07 question. 01:38:18 To scan the entire southern sky in only 01:38:18 a few nights with this exquisite image 01:38:21 quality. Thank you, Sandrine. Aaron 01:38:24 Rudman. Hello, I'm Aaron Rudman. I'm a 01:38:28 professor at the Slack National 01:38:29 Accelerator Lab at Stanford University 01:38:32 and I've been honored to lead the team 01:38:34 at Slack that built the world's largest 01:38:36 camera. I'm particularly excited about 01:38:38 the discoveries that the Reuben 01:38:40 Observatory will make and particularly 01:38:43 um eagerly awaiting the light that we 01:38:46 will shed on the nature of dark energy 01:38:48 and dark matter. Thank you, Victor 01:38:50 Krabendum. 01:38:52 Good morning. My name is Victor 01:38:53 Krabendom. I am the project manager for 01:38:55 Ribbon Observatory. I joined the project 01:38:58 21 years ago, but it's been my honor for 01:39:01 the last 13 to be leading the project. 01:39:04 The team that we rep that we represent 01:39:06 here today is an incredible one. We have 01:39:10 persevered, we've innovated, and we have 01:39:13 overcome challenges. Uh, and right now, 01:39:16 we envisioned that the project was going 01:39:18 to be everything that we dreamed it 01:39:20 would be. I look forward to delivering 01:39:22 this project uh on budget and uh handing 01:39:26 it over to the to the operations team 01:39:28 later this uh later this calendar year. 01:39:31 On behalf of all the scientists, the 01:39:33 engineers, the administrators, and the 01:39:35 technicians, I want to thank both 01:39:37 agencies and some early donors uh for 01:39:40 trusting us with over $800 million to 01:39:43 make this ambitious project a reality. 01:39:47 Jelko mentioned uh Dr. Turner and Dr. 01:39:50 Ajar. I just want to recognize All 01:39:53 right, I'm back. Uh there I thought they 01:39:54 were asking questions because I do 01:39:56 actually want to hear some of the 01:39:57 answers. Um so this is more uh more 01:40:01 comments and about everyone thanking 01:40:03 each other. So I I mean I it's great to 01:40:07 hear that but we are here for the 01:40:09 science anyway. So uh what was what I 01:40:12 was talking about? I was talking about 01:40:13 something in regards to variable stars. 01:40:15 That's right. So safety variables are 01:40:17 super important for the for establishing 01:40:19 distances. Uh some stars out there they 01:40:21 they blink they blink with a certain 01:40:23 pattern. They go brighter and dimmer 01:40:25 brighter and dimmer and over the years 01:40:27 researchers established how they do it. 01:40:29 And because of this we can now establish 01:40:31 distances to various distant objects if 01:40:33 we can find those stars. That's actually 01:40:35 how Edwin Hubble was able to establish 01:40:37 the distance to the Andromeda galaxy. 01:40:39 And so this telescope apparently is one 01:40:41 of the best for doing this now. And so 01:40:44 it will be able to detect a lot of new 01:40:46 sephid variables and other variable 01:40:48 stars, thus allowing us to recalculate 01:40:50 distances to various objects and 01:40:53 potentially um either resolve or uh the 01:40:56 mystery of dark energy and maybe some 01:40:58 other mysteries in regards to expansion 01:41:00 of the universe or make it even worse by 01:41:02 basically establishing that distances 01:41:04 are actually uh farther or closer and so 01:41:06 on. So anyway, it's going to be it's 01:41:09 going to be improving our universe maps 01:41:11 in a sense. Um, 01:41:14 okay. So, I missed another question here 01:41:16 somewhere. Um, 01:41:18 let's see. Let's see. Uh, thank you so 01:41:21 much for the donations. And let's see if 01:41:22 there's a there's a question here. Thank 01:41:24 you, Alv. Uh, thank you, Shapely 01:41:27 Attractor. What does greater resolution 01:41:29 mean for dark matter hunting? Um, 01:41:32 I think what what this means is that 01:41:34 basically we need to find a solution to 01:41:36 dark matter because is it Nobody knows 01:41:38 if it's a particle. Nobody knows if it's 01:41:40 if we need to rework some of the 01:41:41 physics, if we need to rework some of 01:41:43 the um formula, whatever. That's the 01:41:47 basically the biggest resolution. If we 01:41:49 can actually physically find a particle, 01:41:51 solved, done. We can close that book. 01:41:53 But you know, it's been decades now, 01:41:56 lots of different experiments. Uh there 01:41:58 was a there was a video I made just last 01:42:00 week, I think, about a potential 01:42:01 detection of maybe dark matter. uh but 01:42:04 it's there are other explanations and it 01:42:06 could be a neutrino and so on and so 01:42:08 forth. So so that's basically why this 01:42:11 telescope is important because by 01:42:13 measuring the um weak orientation of 01:42:15 lensing and by measuring a lot of other 01:42:18 um parameters inside different galactic 01:42:20 clusters it will actually help us um 01:42:22 figure out maybe maybe what it is right 01:42:25 now. It's it's it's a it's an 01:42:26 interesting question to answer because 01:42:28 uh a lot of physical concepts kind of 01:42:30 depend on it. uh the entire cosmological 01:42:32 model depends on the dark matter 01:42:36 principle. So if it's not real then 01:42:38 everything has to be reworked again. 01:42:41 Next question. Uh Robert, thank you so 01:42:43 much for the donation. And can it find 01:42:44 planet 9? That's one of the missions. 01:42:46 Hopefully within a year of operation it 01:42:48 will capture enough of the southern 01:42:50 skies to see if it's in the southern 01:42:52 skies or not. It will be able to detect 01:42:54 it will be able to detect a very minute 01:42:55 motions of tiny objects. Uh, and so if 01:42:58 it does see a very small object moving 01:43:00 super slow on the outskirts of the solar 01:43:02 system, we'll know for sure that it's 01:43:04 planet 9 or not. Uh, but only the 01:43:06 southern skies because you know it could 01:43:08 be in the northern skies. So, so that's 01:43:11 the the little shortcoming there. Um, 01:43:16 thank you so much for the donation. And 01:43:17 the question is, oh wait, where did it 01:43:19 go? Um, this is only the beginning. We 01:43:23 will get full 4D exploration 01:43:24 capabilities for every user in this v 01:43:26 vast library of real-time recorded data. 01:43:29 Oh, that's a question. Will we get full 01:43:30 4D exploration capabilities for every 01:43:32 user in this vast library of real time 01:43:35 recorded data? Oh, okay. I see what 01:43:37 you're asking. Uh, will we be able to 01:43:38 explore the data of the telescope? Well, 01:43:41 just like SDSS, which is the previous 01:43:43 survey that um that was able to collect 01:43:45 a lot of data on different stars, this 01:43:47 telescope in the next few years will 01:43:49 collect enough data where you'll 01:43:50 actually have like a like a website 01:43:52 where you can just go in and you'll see 01:43:54 all the stars there. Uh you can even do 01:43:56 this right now for SDSS survey. Uh 01:43:58 there's a map you can access. Um Sloan 01:44:02 Digital Sky Survey is the name of this 01:44:04 one. Uh but do I have the link? I don't 01:44:08 have the link. Uh here let's go to the 01:44:11 classic one. Anyway, it's it's 01:44:13 definitely going to have a website like 01:44:16 um access service which which is 01:44:19 probably going to be available by 01:44:21 possibly 20 26 I guess. Anyway, I'll 01:44:25 post the link for SDSS later once I find 01:44:28 um so yes, the answer is yes. Will it be 01:44:30 stored in analog memory systems 01:44:32 providing larger storage that I don't 01:44:34 know. I'm sorry. I don't know where 01:44:35 where they're going to store it. Uh, 01:44:38 next question or concern. Will this add 01:44:40 Oh, thank you so much team Alaska. Will 01:44:42 this add to our ability to see the 01:44:44 creation of planets? Uh, not really. 01:44:46 It's so for planetary creation, you need 01:44:49 telescopes that can see through dust. 01:44:51 Uh, because normally typical young star 01:44:53 systems, which we sometimes refer to as 01:44:56 propolids, which funny word. Uh, you 01:44:59 might want to look for this one in one 01:45:01 of the links in the description. I'll 01:45:02 post it later. uh it's essentially it's 01:45:04 a it's like a cocoon of dust and to see 01:45:08 planet information you have to see 01:45:09 through that and you you need to have 01:45:11 either radio or microwave telescopes for 01:45:13 that. So for that purpose you need uh 01:45:16 there's a there's another telescope 01:45:17 that's also in Chile. It's called ALMA 01:45:19 and that one does a pretty good job. It 01:45:21 can see planets planetary formation. Uh 01:45:23 but it's not super high resolution 01:45:25 though. So we're still we still have a 01:45:26 lot of shortcomings there. Um, okay. 01:45:32 Cool, cool, cool. Can it see UFOs? I 01:45:36 don't know. Can anyone see UFOs? I don't 01:45:39 know. I don't know. 01:45:42 Uh, not a UFO channel to be honest. 01:45:45 Evidence-based only. Uh, okay. What's 01:45:49 this? Thank you so much, Suhoy 29K. 01:45:58 Uh, would space Oh, wait. uh would space 01:45:58 engine implement all of this 10 terabyte 01:46:00 data? So, space engine is the simulation 01:46:03 I sometimes use for visualization of 01:46:06 different planets and stars and so on. 01:46:08 It it already has all of those objects 01:46:10 in there. Uh it it there's no uh there's 01:46:13 no need for to to have um the data from 01:46:16 this particular telescope because here 01:46:18 what this is going to be doing is 01:46:20 basically introducing new asteroids. Oh 01:46:22 yeah. Okay. It will probably have new 01:46:23 asteroids and it will probably be 01:46:25 introducing um much more accurate maps 01:46:29 and distances and much more accurate 01:46:31 gravitational lensing effects that we 01:46:33 can now measure. So this is more for 01:46:36 accuracy as opposed to um actual 01:46:39 objects. And Space Engine is I think 01:46:41 there's only like two volunteers doing 01:46:43 most of the work. So I doubt they'll 01:46:45 have time to introduce everything in 01:46:46 there. It's pretty hard. Uh, I mean I 01:46:49 actually long long time ago when this 01:46:50 channel just started, I tried to do a 01:46:52 lot of different um space engine mods 01:46:54 and so on and it was super challenging. 01:46:56 It's it's it's it's tough work even even 01:46:59 putting all this data in to uh like new 01:47:02 planets, new stars and so on. It takes a 01:47:04 lot of work. So I'm actually grateful 01:47:05 that they do as much as they do. 01:47:08 Next, what did I miss? Oh, wait. I'm not 01:47:12 listening to what they're saying. this 01:47:13 will create and how NSF and DOE have 01:47:15 approached making that available to 01:47:17 researchers quickly through the science 01:47:19 platform and alert system and then my 01:47:21 followup would be what the timeline for 01:47:23 those tools are uh going forward. 01:47:26 Oh, let's listen to the answer. I don't 01:47:28 know what the question is. I'm uh I 01:47:30 missed the question. Sorry. So, with all 01:47:32 the data, I think you get a sense from 01:47:34 JO's presentation how much data we're 01:47:36 talking about is he said about 10 to 20 01:47:38 terabytes of data every night. uh very 01:47:41 early on people realized instead of 01:47:43 sending the data and the software out to 01:47:46 scientists uh it's much better to bring 01:47:48 the scientists to the data and so 01:47:51 there's something called the Reuben 01:47:53 science platform that people work very 01:47:55 hard on where you can um actually just 01:47:59 um log in to the cloud and have access 01:48:03 to all of the data be able to do queries 01:48:06 analysis and so on and you know it just 01:48:10 works It's it's uh fantastic. Rather 01:48:12 than having to distribute software, you 01:48:15 just have it all there set up for you. 01:48:18 So that is something that is uh um you 01:48:21 know I think we're very excited about 01:48:23 the um timeline. Um we have a sequence 01:48:27 of data previews um from the 01:48:30 commissioning data. In fact, the first 01:48:32 preview using the com Cam data is about 01:48:35 to uh hit the streets. Um and then that 01:48:38 will be followed by a second data 01:48:41 preview from commissioning and then 01:48:43 release of the data through a regular 01:48:45 data release schedule that's known to 01:48:48 the community. 01:48:50 Can I just add Jelco? Um please do. Um 01:48:53 and also so Steve has really outlined 01:48:55 how um science community can get access 01:48:58 to the data but there's also 01:49:00 opportunities for um the public for 01:49:02 anyone to participate in this discovery 01:49:04 process through citizen science. So, our 01:49:07 partners um will be hosting um citizen 01:49:10 science projects that anyone in the 01:49:12 world can um help us uh sort through 01:49:15 this amazing amazing treasure trove um 01:49:17 and and create those projects. And so um 01:49:20 as Steve mentioned, the first uh data is 01:49:23 coming with that was taken with the 01:49:25 commissioning camera. And so we'll have 01:49:26 our very first small projects coming in 01:49:28 the next couple of months um that are 01:49:30 all kind of building up the foundations 01:49:32 and the frameworks and and the um 01:49:35 resources for um the launch of the 01:49:38 survey and all the projects that will 01:49:39 come after that. 01:49:41 Fred, do you want to add a few words? 01:49:42 Yes, let me add on top to that um we 01:49:44 also as you mentioned uh we also have 01:49:47 the alerts. You've seen how Ruben will 01:49:49 build this cosmic movie. We have things 01:49:51 we we're looking for we're trying to 01:49:52 understand things that change over time. 01:49:55 So that particular data product will 01:49:57 come through in the form of alerts. So 01:49:59 overnight our data runs really fast from 01:50:02 the mountain top all the way to slack uh 01:50:04 where it gets processed and we look at 01:50:06 what change in the night sky compared to 01:50:08 how we know that the sky looks normally. 01:50:11 It looked before when we looked at it 01:50:13 earlier and then every time that 01:50:15 something changes sufficiently that we 01:50:17 can detect it technically at a five 01:50:19 sigma level uh we package that into an 01:50:22 alert packet. So we collect the 01:50:24 information about it, where it is, how 01:50:26 much the brightness changed, how much 01:50:27 the color changed, and we add postage 01:50:29 stamps of that part of the image that 01:50:32 scientists can use to make do our their 01:50:35 science of course, but also to trigger 01:50:37 other facilities that can take more data 01:50:39 about those things so we can learn about 01:50:41 them even better. And those uh get 01:50:43 distri distributed worldwide. that 01:50:45 particular data product has no 01:50:47 proprietary restriction because we need 01:50:49 all of the scientists in the world to 01:50:51 like point their telescope to learn more 01:50:53 about these things that we discover. 01:50:55 Thanks Fed. Mike back to you. 01:51:05 Hi uh Mackenzie Pryin from Science News. 01:51:05 Um and thank you all so much for uh 01:51:08 having this press conference today. 01:51:10 Going off something uh said just a few 01:51:11 moment moments ago, uh you even talked 01:51:15 about the citizen pro science projects 01:51:17 uh being uh starting and you've clearly 01:51:20 made this all very accessible to the 01:51:22 public uh through your Sky Viewer app 01:51:24 and other ways. Um can you talk about 01:51:26 the importance of bringing the public 01:51:28 along uh throughout this journey and uh 01:51:31 over the next 10 years? 01:51:33 Thank you. I'd love to talk about that. 01:51:35 Um so this is an amazing data set but 01:51:40 it's also a very complex data set. And 01:51:42 so one of the things that our team that 01:51:44 has been part of the observatory um 01:51:46 since the beginning has been working 01:51:48 toward is making many ways for people to 01:51:50 engage with this data in whatever form 01:51:53 you would like whether it's just 01:51:54 enjoying beautiful images or looking on 01:51:56 social media or we have an educational 01:51:59 component and so we're bringing Ruben 01:52:01 data into the classrooms and one of the 01:52:03 things I'm really excited about is the 01:52:05 fact that we're about to see a 01:52:07 generation of students who will see can 01:52:09 see Ruben data in their classrooms um in 01:52:12 high school and then perhaps choose to 01:52:14 study that in university and then you 01:52:16 know go on to maybe make the next 01:52:18 amazing discovery that will be in that 01:52:20 that treasure trove of data um that is 01:52:23 produced through the survey. And so we 01:52:26 have many options like that. Um one of 01:52:28 the other things um that's in there is 01:52:30 we also have a way to explore the data 01:52:32 through sound and sonification. And so 01:52:34 that's also part of our our sky viewer 01:52:37 app that is just as what you're seeing 01:52:40 visually is mapping that color data um 01:52:42 into a visual landscape, we have a 01:52:45 soundsscape that also is the same 01:52:47 representation of that data um that you 01:52:49 can explore. 01:52:51 As a reminder, there will be more than 01:52:53 one star and more than one galaxy for 01:52:56 every living person on Earth. 01:53:03 Thank you. 01:53:03 Hi Sam again from AFP. I have another 01:53:05 follow up on the um asteroid detection 01:53:07 capabilities. Uh earlier this year we 01:53:09 had 2024 Y4 um city killer asteroid 01:53:13 which briefly posed a risk to Earth. How 01:53:16 will uh V Rubin Observatory help in 01:53:18 these detections? Will we give get more 01:53:20 lead time? What do you expect to see out 01:53:22 of the asteroid hunting uh and the 01:53:23 planetary defense capabilities? Thank 01:53:25 you. I can take that question. 01:53:29 So solar system science is one of the 01:53:32 four scientific pillars of Reuben. So we 01:53:35 have developed software framework that 01:53:37 can fully utilize our images to make 01:53:39 unprecedented discoveries. We are not 01:53:42 particularly 01:53:44 designed for near-earth objects. But 01:53:46 because we look at everything, we will 01:53:48 be extremely efficient at discovering 01:53:50 near-earth objects. And as soon as we 01:53:54 have a plausible discovery, all our data 01:53:58 will be on daily basis sent to the minor 01:54:02 planet center at Harvard, which is the 01:54:04 world's clearing house for these 01:54:06 observations. And within sometimes even 01:54:09 within less than 24 hours, everyone in 01:54:12 the world will know that there is a 01:54:14 potential object that could be hazardous 01:54:18 and they can get more data. In practice, 01:54:20 typically once you get more data, you 01:54:22 rule out the level of the danger, but 01:54:26 you need more data. Everyone in the 01:54:28 world will be able to follow up on 01:54:30 Reubin's initial discoveries. Very 01:54:33 often, we'll get our own orbits, too. 01:54:40 I'm Jelvis, 01:54:40 and you can spell it the way I pronounce 01:54:42 it. 01:54:44 [Applause] 01:54:44 [Music] 01:54:50 and your role. Uh, thank you. I think 01:54:50 it's time we gave our journalists online 01:54:52 a chance now. 01:55:00 All right. So, our next question is from 01:55:00 James Dan at New Scientist. What are the 01:55:04 unique capabilities of the telescope 01:55:05 that enable it to detect so many more 01:55:07 asteroids than other instruments? Are 01:55:09 these early detections of so many 01:55:11 asteroids unexpected or did we expect 01:55:13 this volume of objects? How many will 01:55:16 Reuben how many Reuben detections will 01:55:18 feed into existing planetary defense 01:55:20 networks? 01:55:23 They were not surprises. We have 01:55:25 exquisite simulations that we used for 01:55:28 example to predict we'll discover 5 01:55:30 million new asteroids. 01:55:33 Can you repeat the first part of the 01:55:35 question again? 01:55:36 Just the first part. What are the unique 01:55:38 capabilities of the telescope that 01:55:40 enable it to So that is that is 01:55:42 interesting point. So when you ask for 01:55:45 each of our four science pillars which 01:55:47 which vary a lot from asteroids in solar 01:55:50 system to cosmology to dark energy and 01:55:52 dark matter when you ask what kind of 01:55:55 system would you like to have and we 01:55:57 asked that question 20 years ago you get 01:56:00 very similar answers and that's another 01:56:03 power of Rubin Observatory that we 01:56:05 didn't emphasize today that we get one 01:56:08 data set that will serve all these 01:56:11 different science goals. We do not get 01:56:13 specialized data for asteroid asteroid 01:56:16 specialized data for dark energy. It's 01:56:18 one and the same data set because 01:56:20 observatory is designed to be so 01:56:23 powerful that we can get such a powerful 01:56:26 data set called LSST which will serve 01:56:28 everyone. That's why we can get so many 01:56:31 asteroids. The short answer is you need 01:56:33 to scan the sky very fast with very 01:56:37 large field of view repeatedly for a 01:56:39 long time. And that's what we do for 01:56:41 every science program. 01:56:44 All right, thank you. Our next me 01:56:47 question is from Katarina Miller from 01:56:48 the New York Times. She asks that given 01:56:51 the length of time it took to bring this 01:56:53 project to fruition, how does it feel 01:56:55 that the observatory is complete? 01:56:58 I will call on Sandine. 01:57:00 Is great. 01:57:04 Uh it's really an amazing achievement. 01:57:07 It's the achievement of again I 01:57:10 mentioned 10 years of work of a lot of 01:57:12 people really carefully and um 01:57:16 methodously putting everything together 01:57:19 designing properly using the best um 01:57:23 technology to align the telescope to um 01:57:28 build the camera and build the data 01:57:31 pipeline behind it. It's really the 01:57:32 results of a lot of very very careful 01:57:35 and hard work. So that's why it feels 01:57:37 great. Thanks Andre. 01:57:46 So uh Katarina had a followup and that 01:57:46 is now that the first look milestone is 01:57:48 complete what can we expect next from 01:57:50 Ruben Observatory between particularly 01:57:53 between now and the start of the survey. 01:57:56 I think that's question for Victor. 01:58:00 So we are completing the construction 01:58:02 project and what we are looking forward 01:58:04 to is finishing up the validation uh of 01:58:07 the observatory and how it functions. Uh 01:58:09 tuning it up to make it work uh 01:58:11 exquisitly uh and continuously. And so 01:58:14 for the next uh three or four months 01:58:16 that'll be our main objective. And after 01:58:18 that we'll be handing it over to the 01:58:20 operations team. 01:58:25 Thanks ML. 01:58:25 Great. Our next question is from Megan 01:58:27 Bartles of Scientific American. She 01:58:30 asked, "I know it's challenging given 01:58:31 the size of the images, but could a few 01:58:33 of you point out something that strikes 01:58:35 you as particularly interesting when one 01:58:37 of you looks at these images essentially 01:58:40 help a non-scientist look at this part 01:58:42 of the data the way you do." 01:58:46 So if you look at the image where we had 01:58:48 spiral galaxies and you had also 01:58:52 clustered galaxies that were more 01:58:54 yellowish in color 01:58:57 that tells you how far they are. And 01:58:59 when we look at twodimensional images 01:59:02 all the objects that are different 01:59:04 distances they are projected into one 01:59:06 plane. But with the power of this data, 01:59:09 the power of recorded information that 01:59:12 we decipher with our software pipelines, 01:59:16 this projection of 2D image becomes 01:59:19 threedimensional 01:59:20 data. We unpack all these objects into 01:59:25 three-dimensional distribution. 01:59:27 That's what I find exciting about this 01:59:30 data. It gives you the third dimension 01:59:33 that without this data, you just don't 01:59:35 get. It's like looking at 01:59:36 constellations. Constellations don't 01:59:38 have these shapes in reality. These 01:59:40 stars are different distances, but they 01:59:42 project to us to bears and lions and 01:59:44 everything else. Once you have the third 01:59:47 dimension, then you realize, oh, that 01:59:49 looks totally different. And that's what 01:59:51 we want to know with galaxies too to do 01:59:54 cosmology. 01:59:56 Aaron, 01:59:58 one thing I I would like to add to that 02:00:00 is uh when I look at the images, I often 02:00:03 don't pay attention to the beautiful 02:00:05 nearby galaxies. I look at the little 02:00:08 fuzz balls and if you zoom in close to 02:00:11 any one of our images and almost any 02:00:14 portion of the sky, you will see tiny 02:00:16 little galaxies. To the eye, they look 02:00:19 like uh small uh balls of fuzz, but many 02:00:23 of those galaxies are five or perhaps 02:00:26 even 10 billion lighty years away and 02:00:28 have up to a 100 billion stars in them. 02:00:31 And those are the galaxies actually that 02:00:33 we use the most if we want to study the 02:00:35 expansion of the universe and dark 02:00:36 energy. 02:00:38 Thank you, Erin. Steve, do you want to 02:00:40 add a few words? Yeah, we thought a lot 02:00:42 about how to select targets and how to 02:00:45 represent images and I think what we 02:00:48 hope as people engage and look at these 02:00:50 images first I think just we hope you 02:00:53 see them as beautiful um and they're 02:00:56 also a little different from what you're 02:00:58 used to seeing actually significantly 02:01:00 different the f the difference I would 02:01:01 point out and what we're so excited 02:01:03 about Jooko said it um between objects 02:01:07 and most astronomical pictures it kind 02:01:10 of looks like inky black space. That's 02:01:12 what you've seen before. But that's not 02:01:14 what you saw here. What you saw was that 02:01:17 inky black space actually is full of 02:01:20 stuff. It's full of galaxies. It's full 02:01:22 of all kinds of interesting things. And 02:01:25 it's because of Reubin's unique 02:01:28 combination of capabilities that we're 02:01:30 able to bring that all out and to see it 02:01:33 and do the kind of uh fundamental and 02:01:36 broad range of science that Aaron 02:01:38 mentioned. And so I hope people just see 02:01:41 that and the vast range of colors and 02:01:45 vast range of different kinds of objects 02:01:48 that we are going to see. In addition, 02:01:50 there's all the time domain stuff that 02:01:53 you've already heard about. And I think 02:01:55 the thing we hope everybody sees also is 02:01:58 promise and opportunity to find the new 02:02:01 stuff that that um is just, you know, 02:02:05 waiting for us. And so I think it's that 02:02:08 combination of things that we're we're 02:02:10 really most excited about and we hope 02:02:13 people will take the time to really 02:02:15 explore these images because as I said 02:02:17 they're different and it's the reason 02:02:19 that uh the EPO team built the sky 02:02:21 viewer so that you can have a look 02:02:23 around and we hope people enjoy that. 02:02:25 Thank you Steve Mike. 02:02:28 All right our next question is from Greg 02:02:30 Redford the space reporter at WP News 02:02:33 here in Washington DC. He asks, "What is 02:02:36 the most anticipated discovery made by 02:02:38 LSST? What surprises await?" 02:02:51 So there are so many of them, it's hard 02:02:51 to pick one. We will be looking for 02:02:53 unknown unknowns. But we also know that 02:02:57 some of the discoveries will be made. I 02:02:59 already mentioned earlier today 5 02:03:00 million asteroids 02:03:02 and not everything will be discovery. We 02:03:05 are also doing precise measurements in 02:03:08 cosmology in dark matter dark energy 02:03:11 context. We'll be measuring things 02:03:13 precisely. That's one of the goals. We 02:03:16 will get some unexpected discoveries 02:03:18 like for example interstellar objects 02:03:21 that we are now in position to get 10 or 02:03:23 15 of them and get much better 02:03:25 understanding than those two that are 02:03:27 known. Oh, Mua Mua and Borisov. So we we 02:03:31 will learn a lot. Of course, the most 02:03:33 every survey prior to Rubin and LSST, 02:03:37 every big project that scan the sky 02:03:40 discovered many unexpected things. So by 02:03:43 that argument, we think we'll discover a 02:03:46 lot. But then different people are 02:03:47 excited about different things. Maybe 02:03:49 Fed can tell us in the time domain 02:03:52 context, what are you excited about? 02:03:55 Well, I'm going to double down on the 02:03:56 unknown unknowns. Uh and I I love the 02:03:59 question because can you tell us what 02:04:01 the surprise is? No, it's a surprise. 02:04:03 That's a bit tautological. Um, and it's 02:04:05 really uh exciting that it is a 02:04:07 surprise. And I want to emphasize how 02:04:10 difficult it still is going to be to 02:04:12 find those things that we have never 02:04:14 seen before. Um, people make the 02:04:16 analogy, it's like a needle in a 02:04:18 haystack. It's not. It's a needle in a 02:04:20 hay stack. If you don't know what the 02:04:21 shape of the needle is, if you don't 02:04:23 know what the color of the needle is, if 02:04:25 you don't know whether the needle moves 02:04:26 through the haystack, and if you don't 02:04:28 know really what the haystack is 02:04:30 composed of, because there's millions of 02:04:32 things in the haststack, we don't know 02:04:33 all of them to the same level of detail. 02:04:36 So, it's really an adventurous horizon. 02:04:38 And yeah, I'm very glad that we cannot 02:04:40 answer the question what surprises 02:04:42 they're going to be because they're 02:04:43 really surprises. 02:04:46 All right, great. Our next question is 02:04:48 from Corey Powell from American 02:04:50 Scientist. He asks, "How will Ruben be 02:04:52 able to expand our understanding of the 02:04:54 far outer solar system deeper into the 02:04:57 Kyper belts and searching for in 02:04:59 interstellar objects or even planet 9?" 02:05:03 Yes, all of the above. 02:05:11 If planet 9 exists, it is still just 02:05:11 theoretical conjecture. If it exists, 02:05:13 Reuben is the best positioned 02:05:15 observatory to discover it. We will also 02:05:19 obtain very sensitive images very 02:05:23 quickly over a large area of the sky 02:05:25 including the full ecliptic coverage, 02:05:27 the plane in which these objects move. 02:05:30 So we will extend the outer reaches of 02:05:34 solar system by a large factor. We will 02:05:37 see way beyond 02:05:39 the orbits where Pluto and other Kyper 02:05:42 belt objects are found. We will be 02:05:44 sensitive. It depends on the object 02:05:46 size. But we could see Pluto even if it 02:05:49 were at 10 times larger distance roughly 02:05:51 speaking. And then for interstellar 02:05:53 objects so far there were two 02:05:55 discovered. So it is very hard to 02:05:57 predict how many we would discover 02:05:59 because we don't understand population. 02:06:01 It's only two objects. But by simple 02:06:03 scaling arguments, we do expect 10 maybe 02:06:06 20 somewhere there. 02:06:08 So we will be extremely powerful solar 02:06:11 system survey. 02:06:17 Thank you. Our next question is from 02:06:17 Jenna Ahart from Quantum Magazine. Is 02:06:19 there an estimate for how many stars or 02:06:21 galaxies are in the first image 02:06:23 presented today? How does this compare 02:06:25 to the full set of galaxies Reuben will 02:06:27 observe? 02:06:28 I think Steve knows all the numbers. 02:06:33 Uh we're still counting but um it's it's 02:06:37 as Jooko said around 10 million objects 02:06:41 and um as uh Zoko also said we're 02:06:46 expecting about uh 20 billion galaxies 02:06:50 and after the 10-year survey and uh at 02:06:53 18 billion or so uh individual stars. 02:06:56 That's a lot. when you view them 800 02:06:58 times, that means 32 trillion about or 02:07:01 30 trillion observations. Very 02:07:04 impressive. Um, and so, uh, we're really 02:07:07 just getting started. The image you saw 02:07:10 of the Virgo field, kind of the 02:07:13 impression you'll have for the whole sky 02:07:16 after about half the survey, 5 years, 02:07:19 just to give you a sense. It's, you 02:07:20 know, very roughly. Um, and we'll just 02:07:24 be able to see objects um, dimmer and 02:07:27 dimmer over time. That's one of the real 02:07:29 advantages of continuing to do the 02:07:31 survey to look for new things, but also 02:07:33 to measure more precisely uh, Aaron's 02:07:36 fuzzy things as well. 02:07:40 Does that answer the question? I think 02:07:42 so. Very good. Uh, our next question is 02:07:44 from Kobe Brown from Astro Kobe's 02:07:46 YouTube channel. What are some 02:07:48 short-lived or previously unseen 02:07:50 phenomena that Reuben Observatory might 02:07:52 uncover thanks to its rapid high cadence 02:07:54 imaging? 02:08:01 Do you want to take this one, Fed? Uh, 02:08:01 again, they're previously unseen and 02:08:04 unknown. So, no, I cannot answer this 02:08:06 question. I can answer that. We really 02:08:08 do believe we will discover new things. 02:08:13 Can I can I add I I one of the things I 02:08:15 like to think about is the fact that um 02:08:18 when you're talking on a survey where 02:08:20 everything's in the scale of billions, 02:08:22 these one in a million events aren't 02:08:24 that rare anymore. You get lots of one 02:08:26 in a million events if you're talking on 02:08:27 the scale of billions. 02:08:34 All right, thank you. Our next question 02:08:34 is from Alana Shodvinkle from Dur 02:08:37 Spiegel. I had a look at the sky viewer 02:08:40 app and wondered, is the idea that 02:08:41 anyone can discover something in this 02:08:43 image that no astronomer has found yet? 02:08:45 If so, how can no one how could one know 02:08:48 if something is truly new? And what does 02:08:50 someone actually need? What kind of 02:08:52 knowledge or tools to be able to find 02:08:53 something new in these images? Claire, 02:08:56 would you like to comment? Yeah. So, um, 02:08:59 that is one of the things I think is 02:09:01 very fun is if you zoom in and you look 02:09:03 at one of the little fuzzy galaxies in 02:09:04 there, you might be the first person to 02:09:06 be paying attention to that fuzzy blob. 02:09:08 Someone might have glanced at it before, 02:09:09 but you can choose your favorite in 02:09:11 there, which is very cool. Um, if you uh 02:09:15 using that app, you can find the 02:09:16 position, which is given in RA and deck, 02:09:19 which are our coordinates, and you can 02:09:21 look at other cataloges online um that 02:09:24 would if there's information about that, 02:09:26 they'll be in there. But there'll be a 02:09:27 lot of things in there for which there 02:09:29 is no name, there is no catalog yet um 02:09:32 until uh all the amazing science of 02:09:33 Ruben comes out. 02:09:36 Steve, would you like to add? Yeah, let 02:09:37 me just add one other there's so many 02:09:39 great things about Sky Viewer, but one 02:09:41 of the really cool things if you if you 02:09:42 discover a scene you like or an object 02:09:45 you like, you can zoom in to it, frame 02:09:47 it how you like, and then the button on 02:09:49 the lower left will give you a URL, 02:09:52 something you can paste into any browser 02:09:54 and share it with your friends and they 02:09:56 will see the same scene. So you can, you 02:09:58 know, it's it's that's so much better 02:10:00 than saying, "Oh, you know that big 02:10:02 elliptical galaxy sort of off to the 02:10:03 left. Go down a little bit there and 02:10:05 then a little bit over or try to read 02:10:07 the RA and deck, which you can also show 02:10:10 or turn on and off. There are lines of 02:10:12 constant RA and deck. It's so much 02:10:14 easier just to use this fantastic URL 02:10:16 generator and we're hoping people just, 02:10:19 you know, share their favorites." 02:10:22 Thank you, Steve. Mike, so I think 02:10:24 that's all the time we have for 02:10:25 questions today. Uh, do we have we can 02:10:27 one this will be the last question. 02:10:30 Yeah, I just perked up when you talked 02:10:31 about omua. Do you think you'd be able 02:10:32 to resolve the question of its origin if 02:10:35 it's artificial or natural by pointing 02:10:37 at it uh where you where where you think 02:10:39 it is now or it we know it is now? I'm 02:10:41 sorry. Can you Umua Mua uh do you think 02:10:44 you'll be able to resolve its artificial 02:10:46 or natural origin based by by pointing 02:10:48 at it now? Uhua Mua is long gone. We 02:10:53 cannot detect it. But we think we will 02:10:56 learn more about that interesting 02:10:58 question because we will have a much 02:11:00 larger sample. We will get between 10 02:11:03 and 20 maybe even more. And then by 02:11:06 studying statistical properties of those 02:11:09 objects we can ask is it more consistent 02:11:11 with some natural population or we can 02:11:15 go to far-fetched theorist too. 02:11:20 if it comes back. 02:11:27 Thank you again. 02:11:27 [Applause] 02:11:36 Okay. Uh so that was pretty funny. I 02:11:36 thought I actually laughed out aloud. Um 02:11:38 so theua mua question was that it's all 02:11:42 it's long gone and uh if it comes back 02:11:45 we know that it's artificial. That's 02:11:46 actually a pretty good answer. Oh, I can 02:11:48 also take off my super uncomfortable 02:11:51 headphones. All right, so uh I think 02:11:54 what time is it? 1:30 a.m. Oh my god, I 02:11:56 got to go to bed. Uh so 20 more minutes 02:11:59 maybe max ask last minute last minute 02:12:02 questions. Anything else? Anything else 02:12:04 that was confusing or you didn't 02:12:06 understand? I'll try to I'll try my best 02:12:07 to explain. But as I mentioned in the uh 02:12:10 the no what are you calling in the 02:12:12 comments in the in the chat um I will 02:12:14 most likely do a kind of a brief 02:12:16 overview of what they discussed in some 02:12:18 of the feature videos because they do 02:12:20 they did mention a lot of different 02:12:21 links that they uh posted and a lot of 02:12:23 different QR codes and so on and so 02:12:25 forth. Uh and because their website 02:12:28 actually crashed in the middle it's kind 02:12:30 of difficult to access everything. 02:12:32 So, we'll we'll definitely come back and 02:12:34 talk more about this, but honestly, I'm 02:12:37 just generally more excited to see um 02:12:39 what the future images are going to be. 02:12:41 Uh and we'll we'll definitely discuss 02:12:43 some of the first discoveries from Vera 02:12:45 Rubin in hopefully the next month or so. 02:12:49 Cool. So, uh we got the OMU question 02:12:52 answered. So, it's all it's long gone. 02:12:54 And if it comes back, we know it's 02:12:55 aliens. And if it's doesn't if it 02:12:56 doesn't come back then uh as they 02:12:59 mentioned in the press uh in the in the 02:13:02 stream uh we expect that they expect at 02:13:05 least 20 different objects at least uh 02:13:08 did he say per year? I think he said per 02:13:10 year. Uh different interstellar object 02:13:12 per year or was it in total? No, I think 02:13:15 it's per year. That's how that's how 02:13:17 extremely accurate Ver Rubin is going to 02:13:19 be. And that's that's actually 02:13:21 mind-blowing when you think about it. 02:13:22 Being able to detect so many 02:13:24 interstellar objects, not we're not 02:13:26 talking about comets. We're not talking 02:13:27 about or cloud objects or Kepler uh not 02:13:29 Kepler Kyper belt objects. We're talking 02:13:31 about actual objects from other star 02:13:33 systems. So here the expectation 02:13:35 expectation is that this telescope is 02:13:38 sensitive enough to be able to detect 02:13:40 practically 02:13:42 a handful every every year. So that's 02:13:45 that's amazing. 02:13:47 So anyway, uh, 02:13:50 uh, so people are asking me about the 02:13:52 next stream. Last year when we had a 02:13:54 stream in regards to the solar eclipse, 02:13:57 that was actually quite amazing. I 02:13:59 promised to stream uh in next month. So 02:14:01 I'm going to do the same this time, 02:14:03 which means that it's probably going to 02:14:04 be next year. It's It's not Okay, so 02:14:06 truth be told, I would love to do more 02:14:08 streams, and I know that streams are 02:14:10 fun, and this is great for everyone. The 02:14:13 thing is um because I do post daily 02:14:16 videos and I have to pick up my kids in 02:14:19 the morning. I just it's difficult. It's 02:14:21 very difficult to do streams uh more 02:14:24 frequently than I guess what I'm doing 02:14:25 now. But I'll try to do a few uh at 02:14:28 least maybe in the next few months 02:14:30 assuming there's something to talk about 02:14:31 because I mean having a stream without a 02:14:34 topic is difficult. Here we have a great 02:14:36 topic. It's a it's a great discussion 02:14:37 and uh definitely something to look 02:14:39 forward to. Um, okay. I guess they're 02:14:42 they're done with their stream. I can 02:14:43 close this and let's take a look at Oh, 02:14:46 I finally found the map I was mentioning 02:14:48 some of the previous uh comments. That's 02:14:51 the map. The map of different uh Rubin 02:14:55 parties. Basically, every location you 02:14:56 see here, they had a either a in-person 02:15:00 party or a virtual party you could 02:15:02 attend to to basic to listen to this 02:15:05 announcement and to talk about the 02:15:06 discoveries from Ver Rubin. Anyway, 02:15:08 we'll be we won't be needing this 02:15:10 anymore because that's done and I wanted 02:15:12 to leave it on this image right here. 02:15:14 Cool. So, um let me see. Let me read 02:15:17 some of the comments I missed. Uh 02:15:21 will will this telescope What? I missed 02:15:23 the comment. I'm so sorry. Uh 02:15:31 it's it so my apologies for being super 02:15:31 slow. I'm I need to wear glasses to read 02:15:34 these comments and also there are a lot 02:15:35 of comments and some of them are uh some 02:15:39 of them have a lot of questions so I 02:15:40 have to be able to focus at the same 02:15:42 time as I try to think uh what will uh 02:15:45 so night post is asking what will you do 02:15:46 with the data app images will you go in 02:15:48 and discover yourself get your name on 02:15:50 another object oh yeah so I was actually 02:15:53 so some of you might not know but uh 02:15:55 there's an astronomer in Canada that 02:15:56 decided to name an asteroid after me I 02:15:59 was just as surprised as you and I had 02:16:01 no idea he was doing it. Uh, so now 02:16:03 there's a little asteroid out there 02:16:05 that's probably going to be visible to 02:16:07 Ver Rubin telescope that is named Anton 02:16:10 Petro and that was just as shocking to 02:16:12 me as as you. Um, anyh who uh 02:16:22 so some people are talking about the 02:16:22 streams. Yeah. So when it comes to 02:16:24 streaming, I actually have done streams 02:16:26 with Frasier Kane. Um and uh 02:16:30 the biggest issue for me with those with 02:16:32 streaming with with other people with 02:16:33 other content content creators is that I 02:16:36 live in East Asia and they most of them 02:16:39 live in North America. So when they can 02:16:41 stream, which is usually around noon, 02:16:43 maybe 1 2 p.m., it's my bad time. And uh 02:16:47 I 02:16:48 um yeah, I I basically can just cannot 02:16:50 handle it. It's it's it's very tough 02:16:52 with young kids especially. So when I 02:16:55 can do it, they're they're sleeping and 02:16:57 when they can do it, I'm sleeping. So 02:16:58 that's that's the issue. I would love to 02:17:00 do it with Asian uh streamers, but 02:17:02 unfortunately uh astronomy is not really 02:17:04 a big field in in uh in East Asia. Even 02:17:07 though there are a lot of um there's a 02:17:09 lot of research coming out of China, but 02:17:10 just not a lot of streamers, not a lot 02:17:12 of people interested in astronomy here. 02:17:14 It's not a field that people pursue 02:17:16 usually. Um 02:17:18 anyway, uh moving on. Don't 02:17:23 so someone's asking me don't I want to 02:17:24 try some educational series basic of 02:17:26 astronomy? I actually used to make those 02:17:29 videos before like the the actual 02:17:31 channel started as an educational 02:17:32 channel. I was teaching math and uh 02:17:34 different sciences and there is I did 02:17:38 have a plan for several videos and it's 02:17:40 still being worked on and I will 02:17:42 definitely finish it probably in the 02:17:43 next year or so. However, uh the 02:17:46 challenge there is that um I basically 02:17:50 had to rely on AI tools to create the 02:17:52 actual website for it. And there it's so 02:17:54 badly made that I'm I'm not able to just 02:17:57 I I I cannot do it. It's those websites 02:18:00 are required for basically, you know, 02:18:01 practicing things or figuring out how to 02:18:03 for example tracking different asteroids 02:18:05 and learning how to how to discover 02:18:07 asteroids. Um the I had a whole series 02:18:10 of astronomy videos that I wanted to 02:18:12 create with actual practice. uh tests or 02:18:15 uh practice tools. Uh and unfortunately 02:18:17 AI really screwed it up for me. So um 02:18:20 it's being worked on in the future once 02:18:23 I have enough time. Maybe I'll take a 02:18:25 summer break or something and work on 02:18:26 it. But yeah, educational series are 02:18:28 definitely coming. I mean the point of 02:18:30 this channel is really it's not just 02:18:32 entertainment. It's really education and 02:18:34 it's inspiring people to not forget that 02:18:37 science exists and that, you know, 02:18:39 astronomy is real and biology is there 02:18:41 and there's so many things discovered 02:18:43 every single day that it's worth it's 02:18:46 worth pursuing. 02:18:48 Cool. Uh so someone is asking me, can I 02:18:50 just move to a new location? I would 02:18:52 love to. Uh but uh because uh well it's 02:18:55 really because of my family situation 02:18:57 right now. Uh my wife uh who is Korean, 02:18:59 she needs to stay in South Korea for at 02:19:01 least a few more years and um we have 02:19:03 young kids that basically are they they 02:19:07 are difficult to raise without 02:19:09 grandparents and so we need their help 02:19:11 and once they get older then yeah 02:19:13 definitely 02:19:14 uh but for now I'm I'm here just have to 02:19:18 stay here mostly because of the kids and 02:19:20 the family. Um and yeah, Frasier Kane is 02:19:24 actually he's he's a great guy. He I 02:19:26 definitely did. I did two streams with 02:19:28 him at least. And uh I would love to do 02:19:30 more, but I wanted him to come here. I 02:19:32 invited him a few times, but he never 02:19:34 came. I mean, traveling from North 02:19:37 America to Asia is a little bit 02:19:38 challenging. Uh 02:19:42 okay. Uh so what else did I miss? 02:19:47 Uh will we be able to find and track 02:19:49 rogue planets? So uh when it comes to 02:19:51 rogue planets, 02:19:53 most of the rogue planets are usually 02:19:55 discovered through the gravitational 02:19:56 lensing effects and u even though 02:20:00 technically this telescope can do it 02:20:03 because based on what they've provided 02:20:05 us uh what they've told us so far there 02:20:07 seems to be like a 3 to 4 day 02:20:09 difference. I don't think it will be I 02:20:12 don't think it'll be accurate enough. 02:20:13 There are better telescopes for this but 02:20:14 it will be definitely able to detect 02:20:16 some rogue planets. Uh, actually, no. I 02:20:19 think it would be actually pretty good 02:20:20 at it now that I'm thinking about it. It 02:20:22 it because it's able to detect most of 02:20:25 the objects in the galaxy, it should be 02:20:27 able to detect um sudden changes in 02:20:30 brightness. Yeah, sorry, my bad. Yeah, 02:20:31 it would definitely be good. I I had to 02:20:33 rethink about it for a second. I'm like, 02:20:34 wait a second. What am I talking about? 02:20:35 It's really good at detecting 02:20:36 gravitational lensing. Yeah, so it 02:20:38 should be good at detecting rogue 02:20:40 planets. Uh one issue that you might 02:20:42 have though is um 02:20:45 there will be definitely a time limit. 02:20:48 So we have about three days between 02:20:51 frames. Um so you'll have one frame, 02:20:53 you'll have another frame, you have 02:20:54 another frame and there's like 3 days 02:20:56 between them. So the actual 02:20:57 gravitational lensing will be um most 02:21:01 likely not very accurate. So you'll have 02:21:03 to use other telescopes for this. Uh but 02:21:05 yeah, I think rogue planets defin 02:21:07 basically anything in the Milky Way 02:21:08 it'll be able to detect as far as we 02:21:10 know except for black holes. It's black 02:21:12 holes usually visible in different 02:21:14 frequencies. 02:21:16 Cool. Okay, solar and night. Uh thank 02:21:18 you so much again. Uh like uh what's uh 02:21:21 life during the next major eclipse date? 02:21:24 Next major eclipse. Uh when is the next 02:21:26 major eclipse? It's like in a couple 02:21:28 years. No, hold on. Let me check. 2027, 02:21:30 I think. Next solar eclipse. 02:21:34 I thought it was 2027. And it's like 02:21:36 somewhere in the Pacific, I think. 02:21:40 Uh, no, it's not the one. 02:21:48 Uh, oh, okay. So, there's a partial 02:21:48 solar eclipse in September, but that's a 02:21:51 that's a partial. We don't want partial. 02:21:53 We want the we want the total solar 02:21:56 eclipse. Oh, okay. Greenland, Iceland, 02:21:58 and Spain, August of 2026. All right. 02:22:01 Yeah, that's next year. That's exactly a 02:22:03 year from now. So definitely I'll 02:22:05 definitely stream that. Uh I mean if I 02:22:08 can make it to Greenland or Iceland or 02:22:10 Spain that would be great but chances 02:22:12 are probably not unless I can take my 02:22:15 kids with me. Uh so okay someone ask me 02:22:18 would I come back to Canada? Yeah I I 02:22:20 would love to come to Canada. The the 02:22:23 issue is that so my life has been kind 02:22:26 of paused because of COVID at first. Uh 02:22:28 I was I used to work here as a teacher. 02:22:30 Then COVID started. I took a pause. Then 02:22:32 we had a family tragedy unfortunately. 02:22:35 Uh and so we decided to stay here for in 02:22:37 Korea for a little bit. Um and Canada is 02:22:42 basically my home and it's my next 02:22:43 destination hopefully. But when I'm 02:22:45 going to come back is obviously unknown. 02:22:47 Uh and since we have young kids now, 02:22:49 it's just a little bit difficult to 02:22:50 travel with them. Uh, our youngest 02:22:52 daughter is two years old and she is, 02:22:54 you don't want to sit, you don't want to 02:22:56 sit on an airplane with her for more 02:22:58 than two hours. She goes crazy. Um, 02:23:03 so, okay, cool, cool, cool. What did I 02:23:05 miss? Thank you so much, Drop Baruda, 02:23:08 and thank you for enjoying astronomy. 02:23:10 Um, 02:23:12 some people are saying that I look good 02:23:14 look good with glasses. This is a 02:23:16 requirement. I cannot read comments or 02:23:17 anything on my screen unless I have 02:23:19 them. When I record videos, I actually 02:23:20 had to remove these because they they 02:23:22 have a bit of a glare and because of the 02:23:25 green screen, it sometimes makes my eyes 02:23:26 invisible. So, I had to remove them. But 02:23:29 I basic uh So, one of the reasons my 02:23:31 videos might sound different from how I 02:23:33 talk right now is actually because I 02:23:36 don't have a script. I kind of have a 02:23:38 bunch of points I want to make and I 02:23:39 think about them for a while and then I 02:23:42 talk about them and I stop, I pause, I 02:23:44 think. So, that's why some of the videos 02:23:45 are a little bit disjointed. Uh, I guess 02:23:48 if I do find glasses that don't create 02:23:50 glare, I can maybe have scripts and read 02:23:52 through from them. But yeah, it's just 02:23:54 it's a it's a YouTuber thing. It's a 02:23:56 challenge. Cool, cool, cool. Uh, moving 02:23:59 on. Uh, anyway, any questions about the 02:24:00 Heer Rubin telescope? Okay, so here 02:24:03 here's one. Colin Whitehead asks, um, 02:24:06 will this telescope help us accurately 02:24:08 figure out how many stars are in the 02:24:10 Milky Way? Um h that's a good question 02:24:14 but 02:24:15 I don't think so because 02:24:19 it Gaia telescope would be much better 02:24:21 at that 02:24:23 and it has already showed us quite a lot 02:24:25 of different stars and also this 02:24:27 particular telescope it'll be able to 02:24:29 see stars 02:24:31 but I don't think it'll be better at 02:24:33 seeing just stars. I mean, I need to 02:24:36 think about this though. And also, you 02:24:38 know, the stars that are blocked by the 02:24:40 uh actual um center of the galaxy, the 02:24:43 central molecular zone as we call it, 02:24:45 they're still going to be invisible. 02:24:46 This telescope is entirely optical in 02:24:48 nature. So, it's kind of like seeing 02:24:50 things with your eyes, just like more 02:24:51 accurately, you know. Um so, uh I'm 02:24:55 going to say no to that because I don't 02:24:59 think it will be it'll be seen more 02:25:01 stars. We've already seen plenty of 02:25:02 stars in the galaxy. it will just be 02:25:05 able to see what what it can see better 02:25:07 is changes in those stars. So if those 02:25:09 stars are basically flaring or if 02:25:11 they're if they're changing their 02:25:13 brightness just a little bit, if they're 02:25:14 um variable stars, you'll be able to 02:25:16 detect that for sure. So in that sense, 02:25:18 it will it will be able to like for 02:25:20 example, if it's a a sephid variable, 02:25:23 which is a star that allows us to 02:25:24 determine distances, it will be able to 02:25:27 see that star and then tell us how far 02:25:29 away it is much more accurately. That 02:25:31 will be its sort of strength, I guess. 02:25:36 Cool. 02:25:38 Uh oh, I missed the comment. Nightpost, 02:25:40 thank you so much. Um, one day I hope to 02:25:44 hear you say it's aliens. First of all, 02:25:46 I have to the for years people complain 02:25:49 how I pronounce aliens and I'm changing 02:25:50 I'm not changing that by the way. Uh, 02:25:52 but if if that never happens, it was it 02:25:54 was wonderful to just stay curious. 02:25:56 Yeah. So um most of you probably don't 02:25:59 know but my background is not astronomy. 02:26:01 My background is actually in in 02:26:02 microbiology and biochemistry and um 02:26:06 because of this I still have trouble 02:26:10 believing in existence of 02:26:12 extraterrestrial life in general not 02:26:14 even aliens. I knowing what I know about 02:26:16 microbiology which I'll discuss in some 02:26:18 of the future videos I don't think life 02:26:22 is that easy to create to form in in on 02:26:25 other planets. I think we just for some 02:26:27 reason our planet got super lucky. 02:26:29 That's the question we cannot answer 02:26:30 yet. But yeah, I hope so too. I hope one 02:26:33 day we'll be like, "Hey, look at that." 02:26:34 So, we finally found them. Um, aliens 02:26:37 somewhere out there. 02:26:40 Someone is asking me about K-pop. I have 02:26:41 I don't I know nothing about K-pop. I'm 02:26:44 sorry. I don't don't don't 02:26:47 do not expect it to know anything. Uh, 02:26:57 so and someone's asking me if the Oh. Oh 02:26:57 no, my chat. Where did it go? 02:27:00 I'm sorry. My my browser just crashed. 02:27:03 Okay, here we go. I missed a bunch of 02:27:05 comments. Um, so, uh, is there no life 02:27:10 on Europa? Well, 02:27:13 this is all pure guess work on my part. 02:27:16 I no evidence whatsoever in terms of 02:27:18 like if there's anything or not. If 02:27:20 there is anything on Europa, on Titan, 02:27:23 on u on Ganymede, even on Mars, in my 02:27:28 opinion, it might have come from Earth. 02:27:31 It might have been a contamination from 02:27:32 an asteroid from previous missions. 02:27:35 It it might have been made here, 02:27:38 transferred there. That's basically 02:27:40 Pensburgh. That's my opinion. I don't I 02:27:44 mean we just don't have any evidence of 02:27:45 anything existing anywhere out there 02:27:47 right now. It's all guess work. If 02:27:49 however we discover something on an 02:27:51 object out there for example your robot 02:27:53 right if we actually do find something 02:27:55 that's entirely different in structure 02:27:57 the the uh genome is different like just 02:27:59 impossible to create on earth then okay 02:28:02 yeah we found alien life I was wrong it 02:28:04 can be created somewhere else in 02:28:06 different conditions but as it is right 02:28:08 now just based on the complexity of 02:28:10 biochemical reactions uh how DNA is is 02:28:14 formed how the cells are structured just 02:28:17 the the the even the process of protein 02:28:19 folding itself, it is just so 02:28:21 astronomically difficult to create that 02:28:23 somewhere else. And if it does exist, it 02:28:26 exists somewhere super far away like not 02:28:28 not in our galaxy. I think that's my 02:28:30 that's my sort of two cents. 02:28:34 Um what do I think about quantum nature 02:28:37 of target rates? 02:28:39 I don't think much about quantum nature 02:28:42 of target rates. Uh I mean I didn't I 02:28:43 didn't mention that there was a study 02:28:45 like a few years ago where they tried to 02:28:47 quantum entangle target grades but a lot 02:28:49 of people also then kind a lot of 02:28:51 scientists kind of pushed back on that 02:28:53 particular study because nobody was 02:28:56 certain that was a quantum entanglement 02:28:57 of target grades. On the other hand 02:29:00 there's also a study slash hypothesis by 02:29:02 famous Roger Penrose that maybe just 02:29:05 maybe our consciousness is actually 02:29:07 based on quantum entanglement. That's 02:29:09 there's a video in the description you 02:29:11 can you can uh not in the description. 02:29:12 Sorry. In the on the channel, you can 02:29:14 look up quantum consciousness. Uh it's 02:29:16 one of the videos I made a few years ago 02:29:18 because that was a pretty interesting 02:29:20 proposition that maybe for all we know 02:29:22 our consciousness is based on quantum 02:29:24 effects and there seems to be evidence 02:29:26 that something quantum is going on 02:29:28 inside our brain. But right now, nobody 02:29:30 knows. All of these questions about uh 02:29:32 consciousness, alien life, um 02:29:37 basically quantum stuff in general 02:29:39 usually is right now we're still kind of 02:29:41 figuring out. There's no no concrete 02:29:43 evidence, no concrete conclusions yet. 02:29:46 Um 02:29:48 okay, another question about pansermia. 02:29:50 What if complex life only formed because 02:29:51 panspermia brought alien life to an 02:29:53 already inhabited earth and allowed 02:29:55 greater greater genetic mutation than 02:29:57 otherwise available? Well, I mean it's a 02:29:59 good question, but by that by that 02:30:01 logic. So, okay. Well, where did that 02:30:03 life come from, right? And did it start 02:30:05 somewhere else? And did that come from 02:30:06 somewhere else too? Is this like a 02:30:08 continuous panspermia? Because it's an 02:30:11 interesting proposition, but right now 02:30:13 there is just no evidence for either 02:30:16 panspermia. We we have not discovered 02:30:18 any asteroid that seems to contain 02:30:19 contain any life or signs of life in it. 02:30:22 Uh there's no evidence for life in on 02:30:24 other moons, other planets, other 02:30:26 asteroids, nowhere out there. And 02:30:28 there's definitely no life um even on 02:30:31 Mars so far at least. Uh the the most 02:30:33 famous announcement was in the nuh was 02:30:36 the press release by Bill Clinton in 02:30:38 1997. That's actually when I started 02:30:39 doing a lot of astrobiology as well as 02:30:41 as a hobby. Uh and his announcement was 02:30:45 incorrect. He he he basically jumped 02:30:47 jumped the gun there. Uh there was the 02:30:49 the little Let me show you what I'm 02:30:51 talking about. Uh the little asteroid 02:30:55 that he was talking about. Um 02:30:59 Alen Hills 84001, 02:31:02 the famous asteroid. Let me see if I can 02:31:04 show this to you by pressing 02:31:07 Oh, here by removing my face. Here we 02:31:10 go. Uh it was this this little thing. 02:31:14 This this is this was the the biggest 02:31:17 announcement in history of science I 02:31:19 guess uh on the potential discovery of 02:31:22 alien life on a on on another planet and 02:31:25 later on um it was confirmed to be not 02:31:28 life almost 100% because researchers 02:31:30 were able to recreate this using just 02:31:32 chemical reactions and it was too small 02:31:34 to be anything living and it was like in 02:31:36 nanometers in size and I mean after this 02:31:39 a lot of scientists became super 02:31:41 skeptical because it was such a big 02:31:43 announcement And it created a lot of 02:31:44 buzz over nothing because within months 02:31:47 someone was able to recreate this just 02:31:49 by using chemistry. And so um I don't 02:31:53 think it's I don't think it's going to 02:31:56 be easy to prove existence of 02:31:58 extraterrestrial life. 02:32:01 Um okay, what does the observatory do 02:32:04 during daytime? Oh, that's a good 02:32:05 question. I mean 02:32:08 I the observatory itself probably just 02:32:10 recalibrates. they probably clean it and 02:32:12 stuff but uh researchers work 24/7 for 02:32:16 uh for as much as the observatory is 02:32:19 available to them. Uh normally um from 02:32:22 what I know from some of the other 02:32:23 observatories during daytime they 02:32:25 actually do a lot of uh maintenance and 02:32:27 data transfers and during night time is 02:32:29 when they they do the actual captures uh 02:32:31 the the data uh captures at least that's 02:32:34 what I know from previous observatories. 02:32:36 This one I'm not sure. 02:32:38 Uh 02:32:43 oh, that's a good question. Scott Brown 02:32:43 asks, "Where is the line between being a 02:32:45 rightly deeply skeptical scientist and 02:32:47 being a scientist that rejects new data 02:32:48 because it conflicts with their life's 02:32:50 work personal beliefs?" It's a great 02:32:51 question and um it's it's a question I 02:32:55 think a lot of scientists do deal with 02:32:56 every day probably. I mean, it's it's a 02:32:59 matter of it's my ego and I want to be 02:33:01 proven correct versus here's the data. I 02:33:03 chose something that's completely 02:33:04 different, right? And the the beauty of 02:33:07 science is that I mean if you have an 02:33:11 overwhelming evidence coming toward you, 02:33:14 you just have to accept it, you know, 02:33:16 suck it up and be uh be be the man uh be 02:33:20 a big boy and just accept it. And it 02:33:21 happened to most scientists, I think, uh 02:33:23 not not all scientists. There are 02:33:25 actually still scientists uh even alive 02:33:27 today that um in the 60s proposed that 02:33:29 the big bang theory was incorrect and 02:33:31 they still refused to accept it. And 02:33:33 though I understand their point, the 02:33:36 evidence is just completely overwhelming 02:33:38 against them. And it's uh the so-called 02:33:40 steady state theory is just does not 02:33:43 seem to be does not seem to align with 02:33:45 the we have yet they refuse to accept it 02:33:48 because they they strongly strongly 02:33:50 believe that it's not true. And and and 02:33:52 in that sense, well, you can still hear 02:33:54 their opinion. I I I I mean that's 02:33:56 that's also the other beauty of science 02:33:58 is that you're still welcome to accept 02:33:59 someone's opinion, but if the evidence 02:34:01 is against it, I think it's fair to say 02:34:04 that they might be incorrect. And that's 02:34:06 just something that is great about 02:34:08 science is that it's it's it's a it's a 02:34:10 sharing of opinions, but the evidence 02:34:12 always wins. 02:34:14 Someone has asked me if I'm religious. 02:34:16 Once upon a time, a long time ago, 02:34:18 especially when my mom passed away, I 02:34:19 had I became religious for a little bit 02:34:22 to to deal with with my uh number one 02:34:25 tragedy. And unfortunately, it it didn't 02:34:28 work. And so, no, not anymore. I'm I'm 02:34:31 religious in the sense that I'm just as 02:34:33 religious as Einstein. Uh he once said 02:34:35 that he believed in the god of what's 02:34:38 his name? The god of 02:34:41 I have to look it up real quick. 02:34:44 God of uh 02:34:51 he believed in God of Spinoza Spinoza's 02:34:51 god. Uh it's it's named after Baruk 02:34:53 Spinoza a um was it Dutch? Was that the 02:34:56 Dutch or Spanish uh philosopher who 02:34:58 basically proposed that you know the 02:34:59 universe is the god. So so you it 02:35:02 doesn't have to be conscious. It doesn't 02:35:03 have to be thing think thinking or 02:35:05 caring about us. It's just there. It's 02:35:07 something that's there. And in that 02:35:09 sense, yeah, I think there's might there 02:35:11 might be something, but it's not like a 02:35:12 it's not a it's just you believe in the 02:35:14 universe as as as a as a thing. And 02:35:18 that's what Einstein believed. And 02:35:19 that's kind of what I think is maybe out 02:35:21 there, too. But beliefs are to me, 02:35:23 they're not important anymore. I really, 02:35:25 in my opinion, it's more important to 02:35:26 follow the evidence. And if there's an 02:35:29 overwhelming evidence for something, you 02:35:31 just have to you really have to kind of 02:35:33 accept that you might have been wrong. 02:35:34 And I've I've taught myself that over 02:35:36 the years. Uh, I mean, I was wrong about 02:35:39 a lot of things in some of the previous 02:35:40 videos even. Um, and uh, just just you 02:35:44 just have to you just have to find a way 02:35:45 to to accept that sometimes you're 02:35:47 incorrect. 02:35:49 So, you know, 02:35:51 that's the answer. Not maybe not a good 02:35:54 answer. 02:35:56 Um, 02:35:58 okay. So, I'm trying to see some 02:36:00 questions. Uh, h if there's any last 02:36:02 questions. I'm probably going to stop 02:36:04 this in about five minutes, but mostly 02:36:06 because it's 2 am here. 02:36:10 Uh 02:36:12 oh, so someone's asking me if I believe 02:36:13 we live inside a black hole. So, in the 02:36:16 last few years, there's there's been a 02:36:17 few studies about this. Um there mostly 02:36:20 on sort of circumstantial evidence. I 02:36:22 wouldn't say it's very strong evidence, 02:36:24 but evidence in regards to, you know, 02:36:26 things rotating in a certain way and uh 02:36:29 possibly some explanations in in regards 02:36:31 to how we have a horizon that seems to 02:36:35 resemble a black hole horizon except 02:36:38 that it's on the outside. Um what's the 02:36:40 what was the other evidence? Um 02:36:43 anyway, long story short is that 02:36:47 because there are other better 02:36:48 explanations 02:36:50 and because the black hole explanation 02:36:53 is really more of a like a hype 02:36:56 explanation as opposed to like okay that 02:36:57 makes sense. Um right now I don't think 02:37:00 so. it it's it really does not look like 02:37:03 we we are inside a black hole especially 02:37:05 based on some of the studies we have 02:37:09 like for example the rotation studies 02:37:11 they established that it seems to be a 02:37:13 bias and it there's there seems to be 02:37:15 something going on but it's not entirely 02:37:17 certain if if the things are rotating 02:37:19 really how we think they're rotating or 02:37:21 if it's just we've seen them rotate this 02:37:23 way. Uh as a matter of fact uh a lot of 02:37:25 studies establish that things just seem 02:37:27 to clump certain way and that's because 02:37:29 of the so-called um cosmic web which 02:37:32 kind of resembles this humongous uh web 02:37:36 of stuff across the universe kind of 02:37:38 looks like this. And because of this 02:37:40 things just tend to organize a little 02:37:42 bit differently around the universe. Uh 02:37:45 and this might give us a bit of a bias 02:37:47 looks like oh things are rotating this 02:37:48 way but it's really because they're just 02:37:49 kind of in the same location. Um, so 02:37:52 yeah, so right now there's just not 02:37:54 enough evidence about the black hole 02:37:56 living inside the black hole hypothesis. 02:37:58 It would be cool obviously and there was 02:38:00 a recent study that tried to explain 02:38:02 this as a basically the universe the big 02:38:05 bang was a kind of a expansion of the 02:38:08 black hole um from as a result of some 02:38:11 kind of a 02:38:14 um entropy effect. It was a very 02:38:17 difficult explanation. It took me a few 02:38:19 hours to even wrap my hand head hand 02:38:21 head around it, but um having read 02:38:24 through the study and having read some 02:38:26 of the counter evidence, it's still it's 02:38:29 it's like a cool proposition, it kind of 02:38:31 makes sense, but there's just no 02:38:33 evidence that that it that's that 02:38:36 they're correct. Mostly because we don't 02:38:38 have enough evidence from before the Big 02:38:39 Bang. We have no evidence for what 02:38:41 happened in the first few nanoconds of 02:38:43 the universe. And so what they're saying 02:38:45 is like, okay, it's cool. It explains 02:38:47 some stuff, but it just doesn't explain 02:38:48 enough. So, I would say no. At least for 02:38:51 now. Maybe. Maybe they're right. But for 02:38:54 now, I would say it's just we're just we 02:38:57 seem to be in a universe that's just 02:38:59 expanding. I don't think there's a 02:39:00 anything more to it for now at least. 02:39:03 Uh so anyway, 02:39:06 let's see if I missed anything 02:39:08 important. Uh 02:39:14 okay, I need my I need my coffee. 02:39:14 Could 02:39:17 it be a white hole? Um, so as of 2025, 02:39:22 what is it? June almost July 2025, 02:39:25 from all of the observations out there, 02:39:27 there has not been a single white hole 02:39:29 discovered anywhere in the universe, 02:39:31 anywhere in the universe. Um, and so I 02:39:36 don't think it's a white hole. I think 02:39:37 white holes might be just hypothetical 02:39:39 or may exist in some kind of a I don't 02:39:42 know like a reverse universe that goes 02:39:44 back in time but we don't seem to have 02:39:46 white holes. Sorry. 02:39:53 Draw bar is asking me a question I uh 02:39:53 deserve right now because I'm so tired. 02:39:55 Do I ever imagine myself as a giraffe 02:39:57 eating tiny trees when eating broccoli? 02:40:00 Uh every day. Every day. Barakuda. 02:40:09 Uh, have I heard of not physics theory? 02:40:09 No, sorry. Not familiar with that. 02:40:12 Um, 02:40:14 cool. 02:40:22 All right. 02:40:22 So, I think I didn't miss any questions. 02:40:24 If you have any last minute Q&A uh Q 02:40:26 questions to ask before I say goodbye to 02:40:29 you until next year or until the next uh 02:40:33 what what was it uh eclipse I guess 02:40:35 actually there might be an announcement 02:40:37 uh before the end of the year. We'll 02:40:38 definitely do a stream if there's a big 02:40:39 announcement from from any astronomical 02:40:42 facilities or science foundations. But 02:40:45 uh any last questions because I'm 02:40:47 probably going to be leaving in about 02:40:48 five minutes. I need to go to bed. It's 02:40:51 2 am 157. Uh 02:40:59 yeah, 02:40:59 cool. The best best question award for 02:41:02 the best question goes to Mr. Barracuda 02:41:04 for asking me if I if I can eat uh if I 02:41:08 dream of eating broccoli as a giraffe. 02:41:16 And someone is asking me if I if I if if 02:41:16 I know how I how I say. Do you know you 02:41:19 say aliens in a funny way? No, I don't. 02:41:21 You say aliens in a funny way. I say it 02:41:23 the right way. That's how you say it. 02:41:25 Aliens. Aliens. It's aliens. 02:41:30 Say it with me. Aliens. 02:41:33 Um, someone asked me, "Why am I good? 02:41:35 Why am I so good at this?" at what? I'm 02:41:37 not good at this. I'm not good at 02:41:39 streaming. I barely record. Well, I've 02:41:42 been doing this for since 2016 02:41:45 part-time. Then I started doing it 02:41:47 full-time in 2020. So, like five years 02:41:48 full-time, and I'm still struggling. 02:41:51 so difficult. You don't know how 02:41:53 difficult it is. Do not ever become a 02:41:55 YouTuber or any content creator. It's 02:41:57 just so challenging. 02:42:07 okay, I'm reading some of the last 02:42:07 comments and uh someone's asking me 02:42:10 about merch. You want to know about 02:42:12 merch? Would you like to buy merch? 02:42:14 Actually, yeah. I wanted to create a 02:42:16 design with that asteroid, Anton Petra 02:42:20 asteroid, but it's still being worked 02:42:21 on. I want it to be super funny and it's 02:42:24 mostly for me. It's not even for you to 02:42:25 buy, but if you want to buy this, it's 02:42:27 cool. It's going to have like a funny 02:42:29 face. Let me see if I can actually find 02:42:30 the picture. Uh there was a there was a 02:42:32 student in somewhere in California, 02:42:35 undergraduate student who did not share 02:42:37 his or her name, but he goes by K Lee. 02:42:41 Uh, and he created this incredible 02:42:43 infographics with all of the uh, funny 02:42:45 asteroid pictures. Uh, and one of them 02:42:48 has my face on it. I want to see if I 02:42:49 have it here. Do I have it here? Let me 02:42:51 see. Uh, 02:42:54 it's so funny. I could not stop 02:42:56 laughing. 02:42:58 So, I want to have that as a merge. 02:43:00 Oh, I don't have it here. H. Anyway, I 02:43:03 it was in that video where I where I 02:43:05 talked about the asteroid Anton Petro. 02:43:07 So, that's going to be the next merch. 02:43:09 And that you don't have to buy. You 02:43:11 really don't have to, but it helps. I 02:43:13 get like about $3 off every purchase, in 02:43:15 case you wondered. Uh, so 02:43:19 yeah. And also, a lot of I kind of 02:43:22 stopped mentioning this, but a lot of 02:43:23 the stuff I do when it comes to like 02:43:25 merch or if I ever do sponsorships, by 02:43:28 the way, most of this goes to charities 02:43:30 because I just I I make enough from 02:43:33 YouTube as it is. And I don't um the the 02:43:38 charity I've been supporting is is a 02:43:40 there's a Korean um orphanage. So, okay, 02:43:43 in case you in case you were not here in 02:43:45 2022, um our family had a small tragedy. 02:43:49 Uh our son, our super young son passed 02:43:51 away when he was only 3 months old. And 02:43:53 ever since then, I basically kind of 02:43:54 committed to supporting uh a few 02:43:56 orphanages here and there. And so many 02:43:59 many of the things that um I make as a 02:44:02 as an extra income including uh Patreon 02:44:05 and um donations and stuff like that. 02:44:08 All of pretty much most of this not like 02:44:10 all of this but most of this like I 02:44:12 would say 95% of this usually goes to 02:44:14 the one of those orphanages. Just just 02:44:16 something that my wife and I do to feel 02:44:18 better. It's been it's been tough. It's 02:44:20 been tough three three years for us but 02:44:22 we we're trying our best. 02:44:24 And then you know as some of you 02:44:26 probably know that I have a lot of 02:44:27 family in Eastern Europe, Ukraine, 02:44:30 Bellarus and Russia and uh even though I 02:44:33 don't know them that well we all got 02:44:35 affected by the war. So it's just it's 02:44:38 been it's been it's been pretty crazy 02:44:40 three years for me. Uh so so yeah just 02:44:45 trying to survive. But anyway, so here 02:44:48 here's your answer to that merge 02:44:50 question. It's coming but it's going to 02:44:51 be the funny face with the asteroid on 02:44:53 it. 02:44:54 Anyway, thank you so much KFD. I really 02:44:56 appreciate it. Thank you for the 02:44:57 donation and for the comment. Um, 02:45:01 someone is saying I should collab 02:45:03 collaborate with famous asteroid 02:45:04 YouTubers to make a series of my 02:45:06 asteroid is better. That's actually a 02:45:09 good one. I would love to do that. Uh, 02:45:10 one person that has an asteroid named 02:45:12 after her that I would love to 02:45:13 collaborate with or at least meet with 02:45:15 is Dr. Becky. She's awesome. But she's 02:45:18 in England. I'm here in in Korea. We've 02:45:20 we've briefly chatted through like 02:45:22 comments. We we don't know each other 02:45:24 very well. And uh she's awesome though. 02:45:26 Her videos are really great. Um if 02:45:29 you're not subscribed to her channel, 02:45:30 definitely definitely subscribe. Uh and 02:45:33 she has a she has a asteroid that's just 02:45:36 a little bit bigger than mine by like 02:45:38 100 meters. Uh so yeah, she's cool. And 02:45:42 also she has an legit PhD in in 02:45:44 astrophysics, which I don't. 02:45:48 Uh, 02:45:53 okay. So, any last questions before I 02:45:53 go? Because I Oh, yeah. Scott Manley. 02:45:55 Scott Manley has a bigger asteroid and 02:45:57 he's also pretty cool. But Scott Manley, 02:45:59 he is he only does YouTube as as 02:46:01 part-time 02:46:03 hobby. Literally, he he works for Apple. 02:46:06 Um, he works for Apple, so he has better 02:46:10 priorities there. He makes way more from 02:46:12 Apple than he does from uh from YouTube. 02:46:17 Uh, okay. Cool, cool, cool. So, I'm 02:46:20 looking at any last important questions 02:46:21 or comments and also possibly anything 02:46:25 about does anyone wants to know anything 02:46:26 about Ver Rubin or you missed anything? 02:46:28 Did we talk about we talked about the 02:46:32 uh galactic curves, 02:46:34 gravitational lensing? 02:46:37 Oh, they actually did they show this 02:46:39 picture? I forgot if they if they showed 02:46:41 this picture. This was one of the images 02:46:42 they released uh for the press uh press 02:46:45 uh for the media. This this is the 02:46:47 famous trifffit nebula and if you look 02:46:50 at the original image it looks nothing 02:46:52 like this. Let me show you the original. 02:46:56 Look at this. Incomparable the original 02:47:01 the new image. The original the new 02:47:04 image so much better. 02:47:07 So that's going to be the quality of 02:47:08 this new telescope. Uh, 02:47:17 okay. Oh, there's some more questions. I 02:47:17 see my name. What is my science degree? 02:47:19 Uh, my degree was in microbiology and 02:47:22 psychology of all things. Uh, and then I 02:47:25 did I did a degree in masters of science 02:47:28 education, which is why I started 02:47:29 teaching science and math. And after 02:47:32 this, I just realized academia was not 02:47:35 for me. You need to you need to be 02:47:37 really good at 02:47:39 uh academic politics to be good at 02:47:42 academia. I was just not cut out for it. 02:47:46 Do I know David Kipler from Cool Words? 02:47:48 No, I I've talked to him as well. Uh he 02:47:51 lives in in in the US and he is in at 02:47:54 Columbia University. He actually did 02:47:56 invite me to do a stream with him, but 02:47:58 it is just super difficult because of 02:48:00 the time zone differences. When he was 02:48:02 available, it was 2 a.m. for me. 2 am in 02:48:05 the morning. Um, when I was available, 02:48:08 it he it was basically night time for 02:48:09 him. 02:48:15 Okay. What exists between the Higs mass 02:48:16 and the plank mass? I could not answer 02:48:18 that. I'm sorry. I don't think there's 02:48:20 anything there. That's not a question I 02:48:22 can answer. 02:48:28 If I discovered aliens, would I tell 02:48:28 anyone? No. 02:48:30 If I discovered aliens, uh, 02:48:33 if I actually discovered evidence of 02:48:35 alien life on another planet, 02:48:38 you would probably be hearing a lot 02:48:40 about it already because I would be 02:48:43 saying how wrong I was this whole time. 02:48:46 Um, 02:48:48 all right. So, I'm going to close these 02:48:51 pictures one by one before I log off. 02:48:54 Let's see if I missed anything. Oh, 02:48:55 here. Did I talk about this? This was 02:48:57 the pictures from a few This was a 02:49:00 picture when the facility was being 02:49:01 built I think about 10 years ago. 02:49:05 And we have this beautiful image of the 02:49:08 beautiful time lapse actually of the uh 02:49:11 Vera Rubin Observatory 02:49:13 with the night sky above it. Then 02:49:16 there's the website which I will post 02:49:19 later. 02:49:20 And we have the observatory on top of 02:49:24 the mountain. It's approximately 2,800 02:49:26 meters above the surface. 02:49:30 Then we have Bar Rubin herself. 02:49:32 That's the sensor picture of the sensor. 02:49:36 It's uh this is like roughly around was 02:49:39 like 1 meter or something uh 3 ft 02:49:42 where Rubin when she was super young. 02:49:45 This is around the same time when she 02:49:46 discovered the rotation curves were 02:49:49 slightly different from what was 02:49:50 expected when basically when she 02:49:51 discovered dark matter. That's the 02:49:53 mirror of the Vera Rubin telescope. The 02:49:56 size of the mirror. 02:49:59 Picture of the observatory during 02:50:01 nighttime. 02:50:03 And 02:50:05 I think 02:50:07 that Oh, that's the first picture they 02:50:08 released. And that's the the nebula they 02:50:11 released as well. Cool. So, I think I 02:50:14 pretty much covered most of the things I 02:50:15 wanted to cover and uh answered a lot of 02:50:18 questions. 02:50:19 most of the questions. I think not all 02:50:22 questions. Um, 02:50:26 was there anything else I wanted to say 02:50:27 before I go? I'm reading super quickly. 02:50:32 Oh, fun fact. This was actually this 02:50:34 made me laugh. So, uh, this originally 02:50:37 this observatory was, um, did not 02:50:39 receive a lot of funding. It was 02:50:40 actually funded by private fund funders 02:50:44 and one of them was Bill Gates. Hey, I'm 02:50:47 sure people will love to hear that. I 02:50:49 don't really care about Bill Gates, but 02:50:50 I'm sure some people really don't like 02:50:51 him. I don't know why. 02:50:54 My chip is working fine. 02:50:57 Um, 02:50:59 and one of them was uh a billionaire 02:51:02 family by the family named Simony. 02:51:06 That's why that's why this telescope 02:51:07 sometimes is referred to as Simony. 02:51:10 Simony survey telescope. They actually 02:51:12 donated several million dollars. 02:51:16 Um, 02:51:18 okay, cool. I think I got everything 02:51:20 covered. So, I am going to slowly 02:51:26 slowly walk away from this stream. 02:51:32 Uh, and someone is asking me last 02:51:32 question about alien life. Which 02:51:34 celestial body will most likely be the 02:51:36 first to be discovered with non-earth 02:51:38 life? If we find something, anything 02:51:40 ever, it's either going to be Mars or 02:51:43 one of the ice icy moons of um Jupiter 02:51:46 or Saturn. I don't think we're going to 02:51:48 find anything else anywhere else. So, 02:51:50 we're talking about Ganymede, Europa, 02:51:52 probably Titan, but I don't think we'll 02:51:55 find anything, but we'll see. 02:51:59 Uh, okay. I think I just saw the last 02:52:02 question here. Where is it? Go to sleep. 02:52:04 People are telling me to Okay, I'm going 02:52:05 to bed uh in five seconds. 02:52:13 Three, two, one. All right. So, I think 02:52:13 I've covered everything. So, thank you 02:52:14 so much for coming and for staying with 02:52:16 me for the last what is it? Three hours. 02:52:19 I think we definitely Okay, I I'm trying 02:52:22 to promise another stream, but I can't 02:52:25 because last time I promised this, it 02:52:27 never happened. If there's an important 02:52:28 announcement from NASA, from ISSA, from 02:52:31 Science Foundation, from really anyone, 02:52:34 I'll definitely make do a stream about 02:52:35 it. However, uh because it's difficult 02:52:38 to find topics on on an actual stream 02:52:42 as this one, um I don't know if I'll be 02:52:45 able to do it in the next few months, 02:52:46 but I'll try. If there's time, I'll 02:52:47 definitely do it. Uh anyway, thank you 02:52:49 so much for coming. Thank you for all 02:52:51 the support and for great comments and 02:52:53 for being wonderful. And honestly, just, 02:52:57 you know, stay wonderful and be nice 02:53:00 because we do live through some 02:53:02 difficult times. Um, and I keep smiling. 02:53:06 There's there's a lot of stuff to look 02:53:08 up to. We'll uh so tomorrow there will 02:53:10 probably be no video, but uh I'll come 02:53:12 back with a regular schedule on Tuesday 02:53:15 or I guess your Monday maybe. Um and 02:53:18 we'll discuss a we'll be discussing new 02:53:22 discoveries about the largest comet ever 02:53:24 found. Uh it's actually a pretty 02:53:26 exciting study and that comet will 02:53:29 hopefully be imaged by this telescope 02:53:31 very soon because it is one of the 02:53:33 coolest uh objects discovered in the 02:53:35 last few years. It was discovered in 02:53:36 2021. Stay wonderful. I'll see you