The Most Powerful Computers You've Never Heard Of

공유
소스 코드
  • 게시일 2024. 03. 27.
  • Analog computers were the most powerful computers for thousands of years, relegated to obscurity by the digital revolution. This video is sponsored by Brilliant. The first 200 people to sign up via brilliant.org/veritasium get 20% off a yearly subscription.
    Thanks to Scott Wiedemann for the lego computer instructions - • LEGO Logic Gates - Hal...
    Antikythera Archive & Animations ©2005-2020 Images First Ltd. • The Antikythera Cosmos "The Antikythera Cosmos" (2021) follows the latest developments from the UCL Antikythera Research Team as they recreate a dazzling display of the ancient Greek Cosmos at the front of the Antikythera Mechanism.
    Tides video from NASA - climate.nasa.gov/climate_reso...
    Ship animation from this painting - ve42.co/Agamemnon
    Moore’s Law, the op-amp, and the Norden bombsight were filmed at the Computer History Museum in Mountain View, CA.
    ▀▀▀
    References:
    Freeth, T., Bitsakis, Y., Moussas, X., Seiradakis, J. H., Tselikas, A., Mangou, H., ... & Edmunds, M. G. (2006). Decoding the ancient Greek astronomical calculator known as the Antikythera Mechanism. Nature, 444(7119), 587-591. - ve42.co/Freeth2006
    Freeth, T., & Jones, A. (2012). The cosmos in the Antikythera mechanism. ISAW Papers. - ve42.co/Freeth2012
    Cartwright, D. E. (2000). Tides: a scientific history. Cambridge University Press. - ve42.co/tides
    Thomson, W. (2017). Mathematical and physical papers. CUP Archive. - ve42.co/Kelvinv6
    Parker, B. B. (2007). Tidal analysis and prediction. NOAA NOS Center for Operational Oceanographic Products and Services. - ve42.co/Parker2007
    Parker, B. (2011). The tide predictions for D-Day. Physics Today, 64(9), 35-40. - ve42.co/Parker2011
    Small, J. (2013). The Analogue Alternative. Routledge. - ve42.co/Small2013
    Zorpette, G. (1989). Parkinson's gun director. IEEE Spectrum, 26(4), 43. - ve42.co/Zorpette89
    Tremblay, M. (2009). Deconstructing the myth of the Norden Bombsight (Doctoral dissertation). - ve42.co/Tremblay
    Gladwell, M. (2021). The Bomber Mafia. Little, Brown and Company. - ve42.co/Gladwell2021
    Mindell, D. A. (2000). Automation’s finest hour: Radar and system integration in World War II. Systems, Experts, and Computers: The Systems Approach in Management and Engineering, World War II and After. Edited by A. C. Hughes and T. P. Hughes, 27-56. - ve42.co/Mindell
    Haigh, T., Priestley, M., & Rope, C. (2016). ENIAC in Action. The MIT Press. - ve42.co/Eniac2016
    Soni, J., & Goodman, R. (2017). A mind at play: how Claude Shannon invented the information age. Simon and Schuster. - ve42.co/Soni
    Haigh, T. & Ceruzzi, P. (2021). A New History of Modern Computing. The MIT Press. - ve42.co/ModernComputing
    Rid, T. (2016). Rise of the Machines: a Cybernetic History. Highbridge. - ve42.co/Rid2016
    Ulmann, B. (2013). Analog computing. Oldenbourg Wissenschaftsverlag. - ve42.co/Ulmann2013
    ▀▀▀
    Special thanks to Patreon supporters: Dmitry Kuzmichev, Matthew Gonzalez, Baranidharan S, Eric Sexton, john kiehl, Daniel Brockman, Anton Ragin, S S, Benedikt Heinen, Diffbot, Micah Mangione, MJP, Gnare, Dave Kircher, Edward Larsen, Burt Humburg, Blak Byers, Dumky, , Evgeny Skvortsov, Meekay, Bill Linder, Paul Peijzel, Mac Malkawi, Michael Schneider, Ludovic Robillard, jim buckmaster, Juan Benet, Ruslan Khroma, Robert Blum, Richard Sundvall, Lee Redden, Vincent, Stephen Wilcox, Marinus Kuivenhoven, Clayton Greenwell, Michael Krugman, Cy 'kkm' K'Nelson, Sam Lutfi, Ron Neal
    Written by Derek Muller, Stephen Welch and Emily Zhang
    Filmed by Derek Muller, Emily Zhang and Raquel Nuno
    Animation by Fabio Albertelli, Jakub Misiek, Mike Radjabov, Ivy Tello, Trenton Oliver
    Edited by Derek Muller
    Additional video supplied by Getty Images
    Music from Epidemic Sound and Jonny Hyman
    Produced by Derek Muller, Petr Lebedev and Emily Zhang

댓글 • 10K

  • @EngineeringMindset
    @EngineeringMindset 2 년 전 +6784

    I'm absolutely fascinated by these old mechanical computers. There was no software back then to design them, the device was designed within someone's imagination. Truly incredible.

    • @man0warable
      @man0warable 2 년 전 +468

      They were designed on paper using methods and instruments that were practiced for years. Imagination alone was never enough. We have always used tools to supplement the deficiencies of our bodies and minds. Software is merely the latest tool.

    • @andreasu.3546
      @andreasu.3546 2 년 전 +107

      I'm sure the ancient alien astronauts visiting us had workstations on their UFOs that could run Autocad.

    • @tushargupta1968
      @tushargupta1968 2 년 전 +133

      Your comment doesn't make much sense. Even right now when you are designing something you need to visualize the outcome before writing the code for the task. So this has been happening in the past and in the present and will continue to happen in the future. You can't design something without imagining it in your head first.

    • @brianvogt8125
      @brianvogt8125 2 년 전 +30

      A mechanical computer is simply a scale model simulator of the process under consideration. Its components are assumed to represent all of the forces involved in the real world process, but some aspects might have been overlooked. As the narrator said, an analogue computer is specific to the problem being solved, hence there is no concept of software.

    • @ishworshrestha3559
      @ishworshrestha3559 2 년 전

      Ok

  • @howtodrink
    @howtodrink 2 년 전 +863

    This is a phenomenal explainer!

    • @Kittu_Rbx
      @Kittu_Rbx 2 년 전 +3

      Maybe a scientist

    • @siggimatti1129
      @siggimatti1129 2 년 전 +3

      What’s up checkmark?

    • @oakstrom2174
      @oakstrom2174 2 년 전 +6

      Glad to see you watching another great creator. Love both your videos, for slightly different reasons lol

    • @rileylaforge7640
      @rileylaforge7640 2 년 전 +2

      Well you're a good explainer too, you're just usually 3-4 drinks in before you film it.

    • @WinterNox
      @WinterNox 2 년 전 +4

      How to drink bro I'm thirsty

  • @colleenforrest7936
    @colleenforrest7936 년 전 +174

    My mom used to work on an analog computer in the 1940's. She worked in a comptometer office when they got this "new machine." She never called it a computer but as She described it my mouth nearly dropped. I was in college learning programming at the time and we had recently gone over the history of computing. She said it had a bunch of wires and plugs and dials and flashing lights. Her boss couldn't figure it out so he gave her the manual to figure it out.

    • @josepherhardt164
      @josepherhardt164 9 일 전 +3

      A lady in my writers group used to program plug boards (for card sorting applications, IIRC). Hasn't been that long ago!

  • @JackpineGandy
    @JackpineGandy 년 전 +354

    As a US Navy reactor operator of 60s-era nuke submarines, I am recalling that subs had a large number of analog computers, from bow to stern, so to speak. In my own training for my specialty, we were told of magnetic amplifiers (mag-amps) used in German gun directors, that still worked perfectly after being recovered from sunken ships. Part of my work was checking and correcting as needed, the micrometer settings of certain variable circuit components in a particular analog computer that was absolutely vital to the operation of a nuclear submarine engineering plant. In the meantime, we did manual calculations with a slide rule and graphs, to determine when the reactor should go critical. (all of these submarines were turned into razor blades decades ago, so no useful classified information is in this remark)

    • @CCDNNewsNetwork
      @CCDNNewsNetwork 7 개월 전 +5

      Razor blades?

    • @JackpineGandy
      @JackpineGandy 7 개월 전 +56

      the classic submariner's lament...when a sub is decommissioned and turned into so much scrap metal, the end result of which is the sub is remanufactured into other steel products...we say, she was turned into razor blades (a trivial end to a once formidable machine. @@CCDNNewsNetwork

    • @masterplayz7904
      @masterplayz7904 6 개월 전 +11

      That's truly fascinating.Thank you for ur service

    • @charleslord8672
      @charleslord8672 6 개월 전 +9

      Thank you for your service, swabee! Charlie Lord
      USN

    • @Microbex
      @Microbex 6 개월 전 +9

      You can only get stories like that on KRplus. Thanks mate.

  • @LeoCoot
    @LeoCoot 2 년 전 +29

    07:10 ''a number of pulleys'' (SmarterEveryDay heavy breathing Intensifies)

  • @Shadow0fd3ath24
    @Shadow0fd3ath24 2 년 전 +3702

    Chris from "Clickspring" is building an Antikytherean mechanism and has been building it using period tools and techniques to the best of the experts knowledge...the ww1/2 analog firing computers are still incredibly advanced and smartly built tbh. They are just insanely accurate for as little input as they take and what they can interpret and output for solutions

    • @lordpablo1985
      @lordpablo1985 2 년 전 +148

      He's also writing a paper about it as he's figured some stuff about it no knew previously if I remember rightly

    • @Inurufu
      @Inurufu 2 년 전 +53

      That's a beautiful channel.

    • @oscill8ocelot
      @oscill8ocelot 2 년 전 +27

      Ha I was going to mention this. :3

    • @fiusionmaster3241
      @fiusionmaster3241 2 년 전 +3

      Interesting

    • @fiusionmaster3241
      @fiusionmaster3241 2 년 전 +3

      Very, very interesting my brother

  • @millbean13
    @millbean13 년 전 +136

    I’m always amazed at how these guys were able to figure this stuff out so long ago. I had a hard enough time trying to understanding FFT and Laplace transform in my engineering classes today and I still feel like I don’t have a good hold.

    • @geisaune793
      @geisaune793 년 전 +15

      Probably because they didn't have social media, the internet, smartphones, and television as constant distractions and it was actually possible for them to spend time thinking critically and creatively. Plus, all of those things, when used in an unhealthy way, can literally cause symptoms of addiction, literally change brain circuitry, and inhibit your ability to focus and think deeply. Tech companies deliberately design all of those things to be addictive.

    • @cjwrench07
      @cjwrench07 년 전 +19

      @@geisaune793 if you don’t think they had wild distractions back then, which older people also constantly complained about. I have this bridge in New York, I can sell you for dirt cheap.
      The exact way you derisively describe modern electronics as a distraction, is the way the older generation of their time derisively described distractions such as: radios, going to a movie theatre, sports, watching street performers, drinking, dating, etc…
      “The(My) older generations were better” mentality has been a well documented social problem since the 1700s. If you were an older man after WW2, you would have likely been with most others in society, publicly & angrily calling the younger *WW2 veterans* : “The Scared Rabbit Generation.”
      A claim mostly due to them staying home with their modern distractions, and “being scared of public places.”
      (Cartoonist, & WW2 veteran, Bill Maudlin was one of the biggest 1950s-60s voices in calling out the hypocrisy.)

    • @dmitripogosian5084
      @dmitripogosian5084 년 전

      @@cjwrench07 You may notice that Fourier lived 200 years ago. Not to mention Laplace

    • @cjwrench07
      @cjwrench07 년 전 +7

      @@dmitripogosian5084 and those guys had just as many distractions as we have, just different types. Having Money, or hanging around money to get funding/money, was just as much of a freedom granter as today.
      If there wasn’t time for distractions for the average earners, how do we explain the sheer amount of religious, social, and alcohol establishments in basically every single small town or bigger city that’s investigated?

    • @drTobiasz
      @drTobiasz 9 개월 전 +5

      ​@@cjwrench07 I agree with you in this type of thinking - people hundreds of years ago had quite similar needs and feelings like we have today, so we can guess their ambitions, joys etc. We just live in another system and we have new tools for dealing with problems.
      But I see some difference between today's entertainment and that time entertainment bunch of years ago. So today we bring our entertainment with us, in our pockets, or we have it in our houses in the form of smartphones, computers, game consoles and such. It makes people quite lazy, because if they want to spend some time playing, watching movies, listen to music or such, they have just to turn the device on. And there is no big resistance for a person to do this. It's just easy. Years ago people had to put in a little more effort to have fun. They had to go to someone if they wanted to talk with her/him. They had to go somewhere to listen to beautiful music or watch a theater play or a movie. I'm not talking about huge differences but I think this is understandable that young people today open eyes and mouths wide when they hear how much work people did 150...350 years ago just to solve one problem.
      Also I think that today's school doesn't work as good as it would and discourages young people from learning. Education system in many countries, including my homeland - Poland, is based on standards of Prussian school 200 years ago. The main purpose of this system is to create educated and obedient society and not exactly curious.
      (sorry for my language mistakes if they're terrifying, I'm still learning English 😅)

  • @karlschulte9231
    @karlschulte9231 년 전 +229

    I used and helped develop analog computers in 1960's and early 70's. Gun aiming analog mechanical computers used gears and wheels . It considered ship vector and speed and distance to target. The disk/ball mechanism for integration mentioned were also part of it. Electronic ones used tube then transistor operational amplifiers with resistor input and feedback for aritmatic plus capacitor feedback for calculus anf special diode networks in input for trig. And so on. Moon landing simulator we made combined analog (to "think" ) and digitals with control for in/ out. Civil engineers and auto companies used analog pc's to optimize suspensions and roadside slope grading. Plotters as large as beds drew plans and curves far more accurate than primitive digitals. I used m9 in USAF.

    • @tango_uniform
      @tango_uniform 년 전 +4

      The firing solution computer on the USS North Carolina is impressive. It also considered temperature, barometric pressure, delta in altitude (for targets on cliffs), rotation of the earth, and roll of the ship.

    • @johndoh5182
      @johndoh5182 년 전 +8

      And now a digital computer, very small can do all this calculation very quickly, less costly and much easier to maintain.
      I did two tours on DDGs that were converted DLGs and we had a 5" gun that used this old analog system, but everything else ran on digital computers. The accuracy of the 5" gun wasn't great. I did a tour on an FFG with a 3" gun and it could put a round through a window of about 1sq. m at quite a distance. It ran on a digital computer.
      I was a DS, Data Systems Tech, and worked with these digital computers and different systems involved in CIC. Out system changed names a couple times and eventually it got eaten up into an integrated weapons system when AEGIS came about.
      I REALLY enjoyed working on this equipment (1980 - 2000) and I've followed computer technology ever since.
      The need for ever more powerful computers does not require that a transistor keeps shrinking and this is a fallacy that different people who follow computer technology have spread (what we do when we can no longer shrink a transistor). The fact is when a transistor hits that point it will use such a small amount of electricity that ICs can become much larger as long as clock speeds are low enough. But this brings up the problem of failure rate for die being produced from a wafer, where the larger the die is the higher in percentage is for unusable die from the wafer, since every wafer has imperfections. So we have now moved to chiplets, so a CPU can be made of multiple chiplets and this solves so many problems, along with being able to stack one die on top of another, and eventually probably being able to produce multi layer die that I see most of this talk about the need to move away from digital along with moving away from silicon wafers as sensationalism and nothing more.
      A bigger problem for digital computers has been and will be how fast memory is. CPUs have to do a LOT of work to try to predict what data/instructions will be needed and fetch it from memory and load it into cache on the CPU which works much faster. If memory could be sped up to where it could run even 1/2 the speed of the CPU cores that amount of performance boost would be VERY impressive and it would simplify the CPU because you wouldn't need so much branch prediction and prefetching, flushing an instruction pipeline with a branch prediction is wrong, etc........

    • @johndoh5182
      @johndoh5182 년 전 +1

      @@tango_uniform Also pitch, wind direction and speed, for a gun if I remember correctly. Even in launching SAR missiles, you need pitch and roll to get the missile going in the correct trajectory

    • @NoticerOfficial
      @NoticerOfficial 년 전 +2

      I hope you have watched the video narrated by Spock titled “The Last Question”. If youre an AC pioneer, you’ll appreciate it.
      You guys are the golden age of engineering. Hats off.

    • @mykolapliashechnykov8701
      @mykolapliashechnykov8701 년 전 +2

      In 2000s, I helped to disassemble a big modular analog computer from 70s. It was pretty universal in its day, but mostly used to model the transients during a big electric motor startup. A big 20x20 switchboard, few electric drums for variable coefficients, everything an engineer could have wished for.
      As the students, our task was to grab the equations it was modelling and port it into MATLAB. A paltry Pentium-2 PC was quite faster and much more precise than that giant machine. After the model was ported, we together with the faculty's staff disassembled the computer and moved its modules into the humidity-controlled storage. They wanted to preserve them for history. Wonder if it's still in there...

  • @Erik-pu4mj
    @Erik-pu4mj 2 년 전 +5056

    This was astoundingly relevant to--almost a summary of--my History of Science: The Digital Age course, for which I have a final for tomorrow. This video is practically a 'further reading' section. Thank you for this.

    • @ekksoku
      @ekksoku 2 년 전 +62

      Good luck

    • @mfp5431
      @mfp5431 2 년 전 +28

      You will ace it

    • @ahadmrauf
      @ahadmrauf 2 년 전 +39

      Good luck! Although it depends what part of the world you live in, a final on the week of Christmas sure is rough. Hope you at least get New Years off!

    • @MationGaming
      @MationGaming 2 년 전 +15

      Hmm yes indubitably

    • @serevinvukele8046
      @serevinvukele8046 2 년 전 +5

      You are as lucky as Lord Kelvin.

  • @shangerdanger
    @shangerdanger 2 년 전 +34

    crazy how they predicted the tides back then

  • @logannearhood1154
    @logannearhood1154 년 전 +60

    I dropped out of school, regrettably, but whenever I find your channel while scrolling, I always seem to pay more attention than I did in school. You've taught me more than most of the people who were paid to teach me, and for that I appreciate you V, keep up the good work!

    • @olgagaming5544
      @olgagaming5544 년 전 +8

      No worries, school does not have anything to do with wisdom, inteliigence etc. and the knowledge can be fill in

    • @hendrikdebruin4012
      @hendrikdebruin4012 18 일 전

      Our traditional school system wastes at least 5 years of your time. Self educate - that is what one does at varsity in any case.

  • @mathmeetsmachines
    @mathmeetsmachines 년 전 +20

    Absolutely great video! The first person who added sine waves with Scotch Yoke was not William Thomson (Lord Kelvin) but Francis Bashforth (1819-1912). He built a Fourier synthesizer in 1845 for purely math purposes (equation solver). When Kelvin's tide predictors started to become famous he tried to make his priority known but it didn't work very well. His paper "A description of a machine for finding numerical roots of equations" was reprinted in 1892.

  • @AlphaPhoenixChannel
    @AlphaPhoenixChannel 2 년 전 +6980

    I exclaimed at my TV when you showed the rotary ball integrator. What a beautiful system!

    • @marc-antoineb.2125
      @marc-antoineb.2125 2 년 전 +305

      my small brain cannot understand how this mathematically works

    • @arsenhere7020
      @arsenhere7020 2 년 전 +40

      @@marc-antoineb.2125 same here

    • @w_ldan
      @w_ldan 2 년 전 +89

      @@marc-antoineb.2125 same, but the pulley and the ball thing looks cool

    • @wsshambaugh
      @wsshambaugh 2 년 전 +255

      I got chills when they turned it into a Fourier transformer by oscillating the platform. Ingenious, and so simple!

    • @marc-antoineb.2125
      @marc-antoineb.2125 2 년 전 +39

      @@wsshambaugh also with the pulley system to add all the functions

  • @fabioandrade8476
    @fabioandrade8476 2 년 전 +931

    The ball and disk integrator actually blew my mind. I cannot believe such a thing has existed and I only ever heard about it now. What a beautiful machine.

    • @tomorrow6
      @tomorrow6 2 년 전 +59

      For those interested, May I suggest books 📚 like “1800 mechanical movements, devices and appliances” which give an amazing insight into the variety of complex mechanical movements possible in that realm.

    • @janglestick
      @janglestick 2 년 전 +8

      @@tomorrow6 Yes that Ball and Disk was really neat, I thought I knew about all the fundamentals in this area. That 1800 movements book is really cool too.
      Any other sources of roots concepts like that, feel free to post'em : )
      also hoping I don't miss it when the new part 2 video comes out

    • @mannyortega
      @mannyortega 2 년 전

      I WANT ONE!

    • @Fregmazors
      @Fregmazors 2 년 전 +1

      Same thought I had. I had never heard of this. it's such a brilliant idea

    • @gorgolyt
      @gorgolyt 2 년 전 +3

      Honestly, I don't think it would be too hard to come up with this idea. It follows pretty naturally from the fundamental theorem of calculus, which basically says that you have to translate the height of the input into the slope of the output.
      I was more impressed by the pulley thing. Now that is neat!

  • @rogergrimsby5805
    @rogergrimsby5805 년 전 +20

    I had no idea about the history of tide computations. The presentation of the Fourier application is the best video that I ever saw. Even if I hadn't taken Calculus 30 years ago, there would have been a lot of understanding imparted from the stunning visual aids. The video also provides an appreciation of the genius (1% inspiration and 99% perspiration) of earlier generations.

  • @jsp1611
    @jsp1611 년 전 +4

    What a great talk.
    I remember hearing a story about analog computers for use in naval gunnery; they were used to keep the guns level at the target in rolling seas. When they tried to replace them with digital computers they found the digital computers were too slow to compensate for the movement of the ship, and had to go back to analog controls. It took a couple of decades of digital computer development before the digital computers were fast enough to replace the analog ones.

    • @blaster-zy7xx
      @blaster-zy7xx 9 개월 전

      I’m glad you brought that up. This video states the problems with analog but did not mention the huge advantage and that is speed. An analog computer can solve VERY quickly, which is why they were so effective for use on gun sights against dive bombers.

  • @victoreijkhout7115
    @victoreijkhout7115 2 년 전 +673

    As a total software person I find these mechanical devices so fascinating and clever. Those people coming up with them were geniuses.

    • @zeNUKEify
      @zeNUKEify 2 년 전 +49

      Yea no doubt. The more I learn the more it becomes apparent our whole human world is a massive construction standing on the shoulders of countless geniuses. It’s just mind boggling how clever the differential machine is alone.

    • @samzfisher
      @samzfisher 2 년 전 +1

      This is more like mechanical clock

    • @JohnR436
      @JohnR436 2 년 전 +16

      Talk about “hard-coded” 😉

    • @et_aliae
      @et_aliae 2 년 전 +10

      it also helps to understand that because mathematics dogma was driven towards physical representations of equations before the advent of digital computing, that it would be a lot more intuitive for people at the time to make mechanisms that perform equations !

    • @MrShaheer
      @MrShaheer 2 년 전 +2

      same here man, I cannot even understand how would they come up with those elegant solutions, but they did and it moved humanity forward!

  • @salernolake
    @salernolake 2 년 전 +700

    When I was learning to be an engineer back in the early '70s, analog computers were on the way out the door. Large-scale integration was beginning, and Moore's Law was a new concept that my professor's predicted was going to revolutionize computers.
    Fifty years later I am retired after a career in digital computing, and now I find that analog is making a comeback. I am looking forward to part 2; I know enough about analog computer that I can anticipate some of the application for which they will be useful. I suspect the improvements in electronics, and perhaps even 3D printing of components will produce new and sophisticated analog machines.
    Makes me wish I was 20 again, so I could have a second career in analog!
    Please keep making these videos - you are doing valuable work. 👍

    • @tomc.5704
      @tomc.5704 2 년 전 +27

      Absolutely.
      Although I personally suspect that 3D printing will take a back seat to modern CNC machining -- "computer numerical control" -- use a digital computer to control a lathe or mill (or yes, a 3D printer) to build the parts for an analog computer.
      3D printing plastic parts is great, but I'd rather have a precision machined piece out of aluminum or brass.
      And just as an example (that I googled; I am not an expert in either field), a typical 3D printer has a resolution of 140 microns, while precision machining can get below 5 microns

    • @Red_Black_splay
      @Red_Black_splay 2 년 전 +16

      You rule!

    • @gutoguto0873
      @gutoguto0873 2 년 전 +6

      Thank you for your work, sir.

    • @TubeUil
      @TubeUil 2 년 전 +5

      Nice that you share this with us! What a time to have been in digital computing, all those changes. I hope you see still more evolution happening. Must be exciting, for me it is anyway, though I'm only 40 years old:)

    • @bahaatamer1245
      @bahaatamer1245 2 년 전 +5

      Can you give a young engineer like me a bit of perspective on what's coming up? I'm at least a year away from graduation and can really use some help!

  • @HowesAero
    @HowesAero 년 전 +9

    Excellent presentation. When I was doing my aerospace masters in 1981, I had a project to simulate an unstable combat aircraft and then to add the effect of an active control system to stabilise and control it. This was all analogue using potentiometers and amplifiers. The reason was that analogue computers have the immediate response needed to bring a dynamically unstable systems under control without introducing nuisance and limit cycle oscillations. All artificial stability systems for aircraft at the time had an active end built as an analogue computer, even if the pilot input end was still digital. It was a very powerful lesson. As my tutor observed, in general with digital systems you can have fast or you can have powerful. With analogue computing, it's possible to make the sensor the source of power (as in aerodynamic servo tabs, the BAe146 regional jet has an entirely analogue pitch control system involving a devious concoction of pneumatic, aerodynamic and inertial devices), the result can be both fast (=responsive) and powerful.

  • @ericcsuf
    @ericcsuf 년 전 +5

    I was a field engineer for Electronics Associates Inc., the largest manufacturer of analog computers in the 60's and 70's. I traveled all over, but the last year was at NASA Ames. Among other things, the navigation 8-ball used in the Apollo program was developed on our computers. They were state of the art at time time. We later combined them with digital computers. The complex computations were handled with ease on the analog portion and the raw number crunching was done on the digital computer. All together we had around 15 large scale analog computers on site at NASA Ames filling entire rooms and involved in all aspects of their various missions from spaceflight to life science studies. Analog computers speak to engineers in their language--mathematics. Digital computers require interpretation between languages.

  • @DashFlashTheLife
    @DashFlashTheLife 2 년 전 +613

    It's so crazy how adding or multiplying sine waves, something that's as simple as punching values into a calculator today, used to require some unbelievable engineering. I mean, just the notion of such an advanced mechanical computer makes my head hurt. The things we do today would be seen as magic many years ago. Great video!

    • @hemptipsco
      @hemptipsco 2 년 전 +9

      This comment sparked a big boy thought in my brain. Thank you!

    • @AndreVanKammen
      @AndreVanKammen 2 년 전 +22

      You need to punch in a whole lot of numbers in that calculator to do a fourier transformation. The fact that it was analog is ideal for fourier transformations instead of doing a lot of calculations the next calculation comes from turning the wheel slightly. No wonder these where still used in the 1960'ties.

    • @clairehuston9777
      @clairehuston9777 2 년 전 +14

      Any sufficiently advanced technology is indistinguishable from magic.
      (Science fiction writer Arthur C. Clarke's 3rd law)

    • @FireCrauter
      @FireCrauter 2 년 전 +1

      Obviously there must be an external input, but you don't necessarily need to do everything manually, like in a calculator.
      If you already know the formulas that you will follow, you can create a web panel / etc to facilitate it to the user.

    • @Phantaminium
      @Phantaminium 2 년 전 +7

      Isn't this undermining the fact that a calculator is an even greater feat of engineering?

  • @RabidMortal1
    @RabidMortal1 2 년 전 +596

    The analog computers used by navies during the First and Second World Wars are amazing technological feats. The inputs are the continuous, relative motions of opposing ships and the outputs are a synchronous stream of firing solutions.

    • @byrnemeister2008
      @byrnemeister2008 2 년 전 +25

      The Norden bomb site. The third most expensive weapons program of WW2. An analog computer with 50 variables.

    • @DoiInthanon1897
      @DoiInthanon1897 2 년 전 +7

      @@byrnemeister2008 It became a important piece of equipment to the Allies due to it’s increased accuracy with pinpointing the exact location for detonation.

    • @theflyingfool
      @theflyingfool 2 년 전 +1

      @@byrnemeister2008 that hole was filled in immediately the war ended...

    • @Shadow0fd3ath24
      @Shadow0fd3ath24 2 년 전 +1

      @@byrnemeister2008 different tech entirely

    • @glennrishton5679
      @glennrishton5679 년 전 +1

      The US Navy was still using pure analog computers for gun fire control into the 70s and possibly early 80s. In the early 70s I worked on the fire control radar for the Tartar missile system and at that time our system was a mixture of analog and digital.

  • @seanphurley
    @seanphurley 년 전 +22

    This video made me remember the clocktowers of Neal Stephensons Anathem.
    Still a favourite book.

  • @gregsheath7151
    @gregsheath7151 11 일 전

    Brilliant. As a retired computing science teacher I found this enthralling. Wish it was around about 10 years ago.
    Keep this stuff coming

  • @mstalcup
    @mstalcup 2 년 전 +506

    This presentation, on this channel, may be my all-time favorite. As a software engineer, I am blown away and humbled by the innovations of people like Lord Kelvin. I absolutely loved the organization and flow of this presentation.

    • @MrDAMS1963
      @MrDAMS1963 2 년 전 +3

      Agreed! Their entire production is the very highest in quality. Just reviewing the references on this 1 video alone says a lot. It really is one of the best science channels on KRplus.
      When I think about this other youtuber...a 20-something year old turd who's worth $20M from making imbecilic, "how dumb can we get in 20 minutes on this video?" while he's driving a Bently down Sunset Blvd in We-Ho, w/ his model girlfriend, who wouldn't give him the time of day except for his $20M, his Bently, his mansion & his fame. No wonder this country can't have nice things.

    • @MrBottlecapBill
      @MrBottlecapBill 2 년 전 +5

      @@MrDAMS1963 Which country are you talking about? If you're in the USA you already have some of the nicest things in history. If you want to make history, change the world. If you want to make money, appeal to the average masses.

    • @DendriticFractals
      @DendriticFractals 2 년 전

      Praise Bob

  • @overwerk
    @overwerk 2 년 전 +5308

    Your clarity and efforts are always appreciated. - When I see a new Veritasium video, I'm glued to my screen.

    • @TheRedstoneFactory
      @TheRedstoneFactory 2 년 전 +32

      Awesome to see an analog/digital artist like yourself appreciate the building blocks of what enables you to master your craft like you have :)

    • @homo_sapiens_sapiens
      @homo_sapiens_sapiens 2 년 전 +27

      Love your music!

    • @schlegelflegel
      @schlegelflegel 2 년 전 +16

      What a coincidence! Just this week I started listening to a few of your songs again :D But you're right, he does have a very good way of explaining and visualizing complex topics.

    • @rezcheddar8320
      @rezcheddar8320 2 년 전 +8

      Oh my god! I'm a huge fan of your work.

    • @randellreimer2877
      @randellreimer2877 2 년 전 +6

      @OVERWERK when are you gonna put the nth ° back up on spotify?

  • @jeshuruncarlos6649

    Amazing how much effort is put into your videos be it the history, working and structure behind complex machinery, the animations, editing and the list goes on....

  • @Iudicatio
    @Iudicatio 년 전 +21

    I am a meteorology student and my university is very old fashioned. I had to do a lab course for meteorological instruments, and one of them involved using an analog computer to measure the humidity. The device contained human hairs and the computer was able to measure how much the hairs stretch and draw a graph of the humidity. The tutor asked me beforehand what I expected to see, and I said an exponential curve, and the thing really did draw a perfect exponential curve. I remember both my partner and I were kind of fascinated by it even though nobody would ever actually use such an archaic device anymore.
    Thinking about analog computers reminds me of another professor who claimed that every single physical thing that happens is a measurement, which is why the wave function in quantum mechanics collapses when it's observed. Thinking about it, building devices to mimic these measurements that God and the universe is constantly making makes a lot of sense.

    • @drTobiasz
      @drTobiasz 9 개월 전 +1

      And now imagine that in your brain such images of the world are created by a variety of interactions between neurons. I think human brain is some kind of an analog computer, too. It's really fascinating! ❤

    • @neon-john
      @neon-john 7 개월 전 +1

      hair hygrometers are archaic? Out of the mouths of babes. Humidity transmitters using horse tail hair are still in use today and are generally more stable than the electronic sensors. The horse hair does not stretch. It elongates as it absorbs moisture. The hair bundle is maintained under a gentle stress, just enough to keep the hairs from becoming loose.
      The only one I know of that can rival a horse hair hygrometer is the chilled mirror technique. In this device colimated white light is directed at a 45 degree angle to a front surface mirror cooled by a Peltier junction. The light is reflected off the mirror to a photoelectric detector. The control circuitry controls the Peltier device to maintain a slight decrease in light which indicates a thin film of dew is on the mirror. The temperature of the mirror is the dew point. The (analog) electronics can convert the dew point into relative humidity when needed.
      I have a horse hair dew point transmitter in my display case that is 90s vintage. It's output is to control the current in a current loop to between 4 and 20ma. That's a standard analog measurement range. It used to be 10-50ma but to reduce power consumption in large control systems, the 4-20 ma was standardize. The compliance voltage is usually 45 volts so many consumers of the signal may be connected in series. Voltage operated instruments used dropping resistors across their terminals to develop the voltage. Most indicators and analog control elements use the current signal directly.
      The entire reactor control and protection system of the Sequoyah nuclear plant near Chattanooga, consisted of a large room full of racks of analog computing elements. Square root extractors to linearize the differential pressure signal across an orifice plate flow measurement. Integrators and differentiators. PID controllers. Alarms (devices which closed contacts when the current exceeded a setpoint, voters (selected the highest or lowest of several inputs) and so on. Construction was started in 1970 and it went commercial in about 1978. It was only 3 years ago that Westinghouse replaced the analog control system with a multiply redundant custom-designed computer system.

    • @beenschmokin
      @beenschmokin 6 개월 전

      Based on flat non moving earth. Same as astroLabe. FYI

  • @EEVblog
    @EEVblog 2 년 전 +1473

    I've done a teardown video of a B52 bomber astro compass analog computer and it's glorious how these thing can compute sinusoidals and do integration etc.

    • @dr.jonesmurphy5743
      @dr.jonesmurphy5743 2 년 전 +27

      Gonna have to watch that

    • @godfather7339
      @godfather7339 2 년 전 +9

      I rly love your videos.

    • @dr.jonesmurphy5743
      @dr.jonesmurphy5743 2 년 전 +5

      Oh shid you guys are the ones melting wrenches with the giant transformer. Good on you brethren

    • @wynfrithnichtwo8423
      @wynfrithnichtwo8423 2 년 전 +4

      Why destroy the old mechanism? None are being made any more today. Is there a security reason for it’s destruction? Or am I mistaken and you meant that you took it apart to learn about it’s function?

    • @gnarthdarkanen7464
      @gnarthdarkanen7464 2 년 전 +41

      @@wynfrithnichtwo8423 Yeah, you've missed a term... "Teardown" involves (specifically) taking carefully apart so that it can be rebuilt... including any and all repairs or replacements... so that when you are finished with a "full operation" you have two majority stages... "Teardown" and "Rebuild".
      If you'd like a specific reference in literature, Hayne's or Chilton's or "Climber" (for motorcycles) offer "Complete Teardown and Rebuild" Guides to automobiles, motorcycles, and ATV's... and there are probably other publications... SO you can order or download based on whatever vehicle you'd like by Manufacturer, Year, Model, and any additional nomenclature... AND read up on just about anything you'd ever want to know about it...
      Some of us "restorers" have to take things apart in a "teardown" operation, to study them. We usually have to take pictures prolifically of the project as we do so, and then study those pictures and the components to decipher how to get them back together to make them work "like new" again... and other times to simply fabricate a new one... occasionally (when we're lucky) better than the original.
      Nobody is willingly tossing one (essentially) into a chipper. I promise. We have more respect for the past and the heroes who lived it, than that. We're just as fascinated as you are! ;o)

  • @ori9761
    @ori9761 2 년 전 +327

    My grandad was a bomber pilot in the RAF in WW2, his crew was occasionally given new devices to test, one of them was a machine that contained a moving map that was small enough to strap to their thigh. This map would rotate around rollers and update to show the terrain he was flying over regardless of visibility to the ground. The whole crew thought it was incredible and provided great feedback to the engineers that developed it. But as was often the case it was taken away after testing and they never got it back for the rest of the war. Always been curious what that machine was, how it worked and why it was taken away if it seemed to be working.

    • @sinfinite7516
      @sinfinite7516 2 년 전 +20

      Sounds fascinating, commenting to see if anyone that knows replies.

    • @pratiklomte
      @pratiklomte 2 년 전 +7

      Analog computer

    • @notapplicable4637
      @notapplicable4637 2 년 전 +83

      Many incredible inventions and discoveries made during the war were never actually put into use with front line forces because it was feared they would do more harm than good if they fell into the hands of the Axis powers. This was especially true of inventions like the one you describe. A key part of the aerial defence of the UK was the use of decoys on the ground to send German bombers using visual navigation off-course - at various points during the Battle of Britain entire fake towns and other features were created for this purpose. If the device you describe were to found by the Germans in a crashed plane then it could be reverse engineered and the accuracy of their bombers would improve ten fold, even in weather conditions where our own fighters could not see the enemy.
      Worse still, what if these same computers were adapted into guidance systems for the German V1 and later V2 unmanned missile and rocket attacks? The navigation abilities of V1 were notoriously bad, which is why it was largely fired at targets so big that they were hard to miss, i.e. London. They weren't precision weapons, but what if this technology was available to the Germans? That development may have altered the outcome of the war.
      These are just hypothetical reasons, I'm sure someone knows the real reasons why the device your grandfather tested was never seen again. However these types of very real fears were the case for many inventions being kept on a shelf marked Top Secret instead of being used.

    • @omarpasha2968
      @omarpasha2968 2 년 전

      It was taken away and given to the Nazis to help them build up the Nazi War Machine! Then, our inventions that the Nazis was using made them look like a genius, when it was in fact American genius. There are spies in our Military Industrial Complex who sit in the highest military and civilian positions waiting to transfer American military and civilian secret to our enemies for a handsome price!

    • @iCore7Gaming
      @iCore7Gaming 2 년 전 +10

      I fail to see how that would work other than using air speed which would be pretty inaccurate considering air speed isn't the same as ground speed.

  • @David20092203
    @David20092203 년 전 +5

    I am constantly humbled by the enormous amount of work and ingenuity that went into machines I have taken for granted.

  • @alexandruturcan2632

    Your sentence about analog computer being "anaolg for only one type of problem" at min 17.24 just left me speechless. Great content, and amazing narration

  • @codediporpal
    @codediporpal 2 년 전 +402

    4:15 It's pretty mind boggling that a telegraph cable was laid across the Atlantic ocean in the 1850's. I'd love to learn the details of that endeavor someday.

    • @LinasVepstas
      @LinasVepstas 2 년 전 +62

      In brief - yes, it worked. But ... it was shoddily made, and leaked water. Thus, the signals were very weak. Two solutions were proposed. One was to use a mirror to amplify the weak signals by reflecting a dot on a wall. The second, advanced by an arch-rival, was to use high voltage. The arch-rival won the debate .. and burnt out the cable in a few days.
      This is in a short story is told by Neil Stephenson - "Mother Earth Mother Board" from 1996

    • @stringjazz2937
      @stringjazz2937 2 년 전 +5

      Before artificial satelites intercontinental telephone calls were possible thanks to cables lying deep at the bottom of the sea.

    • @adblockturnedoff4515
      @adblockturnedoff4515 2 년 전 +5

      Bet you can find at least half a dozen videos on this topic. Now is the time to pray 🙏🤞as my luck is usually terrible when it comes to winning bets (though logically speaking I should win).

    • @stringjazz2937
      @stringjazz2937 2 년 전

      @@adblockturnedoff4515 lo. You're right.

    • @LinasVepstas
      @LinasVepstas 2 년 전 +1

      @@adblockturnedoff4515 Except Neil Stephenson is a great writer. He even starts out the story with this convoluted Victorian introduction 'wherein it is explored...'

  • @arfloctions5313
    @arfloctions5313 2 년 전 +511

    So Lord Kelvin was the first guy to think of a system to compute the FFT! How come I never heard about this in engineering school. Before DFTs and FFTs, there existed AFT (Analog Fourier Transform). Mind blown...🤯. And what an elegant construction. These concepts should be used to teach mathematics and engineering in STEM. The genesis of the thinking behind any mathematical and engineering breakthrough goes way beyond equations and has real world analogies that are much easier to understand. Brilliant video. Thanks for everything you do, Veritasium. 🎉🙏🏽

    • @m1ndk1ller
      @m1ndk1ller 2 년 전 +42

      Precisely this, had they taught me the history behind the math in high school I would have been more interested. As opposed to asking the teachers what sine and cosine is actually used for and getting a non answer.

    • @anuragtekam9376
      @anuragtekam9376 2 년 전 +26

      @@m1ndk1ller My teacher used to say just study whatever is in your book dont ask useless questions, these people just don't know the importance of all this and just made us into calculators.

    • @pogunguskingofthemilk9529
      @pogunguskingofthemilk9529 2 년 전 +9

      @@anuragtekam9376 I need to understand the math not just how to do it.

    • @yw1971
      @yw1971 2 년 전 +5

      This should be the best (and maybe the only) way to teach math - with real world examples

    • @johnosman8971
      @johnosman8971 2 년 전 +1

      For those of us, who were never explained the reasonings of math, or having a dictionary/thesaurus, to find out what the differing parts of math are/were for, it is all but impossible to see something that does not have any tangible roots for yo draw an image within our minds, … I have never understood the practicality of algebra, any further than Einstein’s time x mileage, =‘s mph, … drawing a picture inside my mind of what something should look like, (such as using the “carpenter’s rule of thumb”), … is the one sure way, that I have used in creating doorway’s that are genuine in their appearance, & setting up a baseball/soccer field in proper angular accordance with the rules, … flat lining a parking lot, with a slope of 2 tenths of an inch from the highest point of the area, to the sewer drains, have ensured that water would not collect, and flood patrons vehicles in abundant rainstorms, … running a leveled string line, ensures grade at marked consideration points, for the backfill, grading, of stone, & legitimacy of pavement, whether poured, or heat adhered such as asphalt, … making an unbalanced wall look flat is also to be had, provided shims are properly placed, & utilized throughout construction, … painting said walls & ceilings can also be sight affected by how much paint is applied with a roller, & in what direction, it is rolled out, with textures, notwithstanding, …

  • @uniquelybe
    @uniquelybe 2 개월 전 +1

    Your videos are well done, entertaining and engagingly informative, Thanks 👍 Regarding analogue computing, good regarding unambiguous discrete phenomena

  • @alexgian9313
    @alexgian9313 년 전 +2

    Wonderful stuff!
    I also love the peculiar irony of all these ingenious analogue devices being modelled by (admittedly very fast) digital programs - all those composed graphs, ray-tracings and 3D models...
    Is that a positive feedback loop? LOL.
    As others have already remarked, we are really at the start of a new era of scientific understanding.
    Congratulations. See yourself as a pioneer!

  • @SRFriso94
    @SRFriso94 2 년 전 +538

    I do want to point out on the rather incredibly improvement of shells/kill ratios of Allied AA guns: that wasn't solely down to better maneuvering of the guns. Planes are fast and small, so hitting them in three dimensional space is really difficult. The Americans and the British jointly developed the proximity fuse, basically a way for the shell to detect when it was near an enemy plane and detonate, and this at least removed the third dimension from their aim, making them much more accurate.

    • @raifikarj6698
      @raifikarj6698 2 년 전 +20

      Oh from one of the Curious Droid channel video yeah it basically the fuse that make allied guna more accurate and with the additional improvement with equipment to calculate the trajectory it makes more accurate guns

    • @shayne7
      @shayne7 2 년 전 +3

      Just don't let it detect the ground!

    • @anticat900
      @anticat900 2 년 전 +31

      Proximity fuses were far more important than the rare analogue control of a aa gun. As you still had to aim the gun at the plane yourself for the analogue computer to attempt to correct for speed, distance and wind. Our own analogue computer in a trained operator (called a brain) did this just as well with some intermittent flack rounds for the adjustments to be made. Proximity rounds that actually went off weather they hit or just went near was a game changer (though these were only in use on the large calibre aa's not the light machine gun type).

    • @jrizos
      @jrizos 2 년 전 +6

      Right, we need a comparison of before/after the proximity fuse was implemented, which I understand to be very close to the end of the Pacific theater. I checked: first use January 1943.

    • @loganthesaint
      @loganthesaint 2 년 전 +3

      Germans invading:
      Allies with new proximity shells: laughs in galaga.

  • @martinstent5339
    @martinstent5339 2 년 전 +307

    My physics teacher used to tell us that digital computers would never catch on because of their limited accuracy, and those analog computers were going to be big. That was in the UK in the 1960s. Since then, I have been laughing about that and thinking “How wrong can you be!!”. But, well, maybe he knew something… let’s wait and see.

    • @fg8557
      @fg8557 2 년 전 +19

      @jshowa o Yeah, if a finite amount of frequencies is present. Even a simple step function has infinite amount of frequencies present. The Nyquist theorem is more about the resolution limit of discrete approximations

    • @lilsammywasapunkrock
      @lilsammywasapunkrock 2 년 전 +15

      I remember my teachers all tell me how important it is to understand basic math because we wouldn't be walking around with a calculator in our pocket...
      Growing up with computers, it's crazy how much it's changed, but also how much of it is still the same.

    • @ssquarepants04
      @ssquarepants04 2 년 전 +1

      maybe he was talking about quantum computers...

    • @MrrVlad
      @MrrVlad 2 년 전 +2

      currently optical "computers" seem to be the next thing for deep learning. Not because of accuracy, but because of power efficiency.

    • @JaceEntertainment
      @JaceEntertainment 2 년 전

      False like the y2k bug ...digital computers will always be key

  • @hardakml
    @hardakml 년 전

    Totally immersing Veritasium! Your graphics are world class and the concepts you introduce absolutely enthralling. Thank you.

  • @CharDhue
    @CharDhue 년 전 +1

    1) obviously the one who come up with this is genius
    2) the one who manages to crafting this computer with such precision is a hidden genius

  • @johnchessant3012
    @johnchessant3012 2 년 전 +307

    Analog devices like the Fourier analyzer are so astounding to me for how creative the inventor had to be. One of the coolest is a "planimeter", which measures the area of an arbitrary shape by tracing around its perimeter.

    • @LucasPlay171
      @LucasPlay171 2 년 전 +4

      That's possible?!!?!!!!

    • @StormWarningMom
      @StormWarningMom 2 년 전 +13

      Thus you could, in theory, calculate the area of an island by tracing the shore line, correct?

    • @TheREALMcChimp
      @TheREALMcChimp 2 년 전 +23

      @@LucasPlay171 Possible but not the easiest solution-it's much quicker and cheaper to cut the shape out and weigh it and then compare it with the weight of a unit square. Years ago one of my chemistry teachers explained to me that that's how they were taught to take the area beneath the graphs their instruments produced-as chemists they had high resolution, sensitive balances to hand.

    • @Airblader
      @Airblader 2 년 전 +9

      @@StormWarningMom Look up the "coastline paradox".

    • @fg8557
      @fg8557 2 년 전 +1

      Well, is a Planimeter really that awesome? I can accomplish the same thing with a string and a ruler

  • @codypendency9482

    as an instrumentation control technician it’s cool seeing my field of work and the fundamentals/history of instruments be talked about it gives you another level of understanding and interest

  • @crazysupernovagaming3638

    Okay, I really like the way this guy does sponsored content. Instead of slapping it in the middle where it interrupts content, he puts it at the end! That's a very respectable thing to do!
    And for my opinions on the rest, it's really interesting seeing how mechanical computers work! I've always had a fascination with stuff like clockwork, and what is a clock but a basic mechanical computer? Thank you for this video!

  • @Texasbluesalley
    @Texasbluesalley 2 년 전 +775

    This is my favorite of all the videos you've ever done.

    • @HolyPro7
      @HolyPro7 2 년 전 +9

      This is the best crossover.. SRV and Computer Science

    • @Terribleguitarist89
      @Terribleguitarist89 2 년 전 +1

      @@HolyPro7 I know right? Wasn't expecting to see him here haha

    • @gaslitworldf.melissab2897
      @gaslitworldf.melissab2897 2 년 전 +4

      So much goes over my head, b/c mathematics proved that my brain was deficient in something. I maxed out intellectually/academically at _pre_ Algebra. It was heartbreaking and I'll never be completely be rid of the shame and guilt, b/c I excelled at writing and English. Bc/ of my math and analytical weakness, my IQ is only 80, despite the fact that I managed to finish 2 college degrees. So, degrees don't really mean anything (unless they have ivy league backing).

    • @herds22
      @herds22 2 년 전

      600th like. 👍

    • @Ildskalli
      @Ildskalli 2 년 전

      Mine too! Fascinating subject, great editing, and plenty of real-world applications. A wonderful piece.

  • @DaltonChannel
    @DaltonChannel 2 년 전 +2640

    The problem with analog computers
    is that there will always be some slop in the connections between parts; the problem with digital computers is that always there will be cosmic particles to malfunction it. :-)

    • @BlastinRope
      @BlastinRope 2 년 전 +178

      The problem with the universe is

    • @iainbrady3629
      @iainbrady3629 2 년 전 +508

      Reminds me of that time in a Super Mario 64 speed run where Mario jumped extra high and the only explanation we have is cosmic particles lol

    • @arc8218
      @arc8218 2 년 전 +65

      @@iainbrady3629 lmao fr
      that escalated quick and make me laugh lol

    • @movement2contact
      @movement2contact 2 년 전 +12

      @@iainbrady3629 How do I Google it? 🤔🕵️‍♂️

    • @remyolschwang9795
      @remyolschwang9795 2 년 전 +69

      it would be interesting to see if you could create a computer partially analog and partially digital to create a computer free of all issues

  • @kevinbyrne4538
    @kevinbyrne4538 개월 전 +1

    Who created these animations? Very nice work.

  • @mattymerr701
    @mattymerr701 년 전 +3

    Analogue computers have never really died off. There are some great videos on old naval ship firing solution solvers and they are some awesome analogue computers.

  • @francisvaughan7460
    @francisvaughan7460 2 년 전 +382

    Kelvin's tide machines are my single most favourite things. I remember seeing them for the first time in the London Science Museum over 30 years ago.
    Small nitpick. The pics you show when mentioning Colossus are actually the Bombe machines used to crack Enigma, not the machine used to crack the Lorentz codes.
    Everyone forgets Konrad Zuse and his early computers. These were earlier and more advanced than the ENIAC. But since he was German, and developed them during WW2, history has not been kind.

    • @gregkrekelberg4632
      @gregkrekelberg4632 2 년 전 +11

      This comment really needs to be higher.

    • @blackjack4494
      @blackjack4494 2 년 전 +14

      There was more than just war as a reason why Zuse's computers didn't go thru the roof. However some companies used it back then and made big profits because of that and are still in business today.

    • @aodhanking2539
      @aodhanking2539 2 년 전 +2

      Das ist gut! Forgets? Who the hell is taught anything anymore?

    • @vigilantcosmicpenguin8721
      @vigilantcosmicpenguin8721 2 년 전 +10

      If I'm not mistaken, technically, Zuse's computer was not fully Turing-complete. Don't get me wrong, it was a miracle of engineering nonetheless, but I think it's rightful that ENIAC gets the credit for its achievement.

    • @anuarbin
      @anuarbin 2 년 전 +4

      Let's vote this to the top.

  • @johngrasso6224
    @johngrasso6224 2 년 전 +207

    As a person into computer science myself, I love looking at the old ways of doing things. Seeing the pulleys and the ball integrators was incredible, and I can't wait for the next video.

    • @Hshjshshjsj72727
      @Hshjshshjsj72727 2 년 전 +7

      I think it's also the new maybe cuz we wanna upload minds and brains are analog mostly not digital

    • @shamsow
      @shamsow 2 년 전

      @@Hshjshshjsj72727 There are actually continuous data structures in computer science research, so an analog system is not exactly necessary to store analog data.

    • @Hshjshshjsj72727
      @Hshjshshjsj72727 2 년 전 +1

      @@shamsow that's really cool thanks for letting me know :) I'm very interested in uploading the mind and immortality

  • @liangzh
    @liangzh 8 개월 전

    Vannevar Bush led the differential analyzer project at MIT and Claude Shannon was his student at the time, who also contributed greatly to the analog computer work. Shannon's work later at Bell Lab with his colleagues during WWII was actually on Fire Control (anti-aircraft gun aiming problem in the video). :)

  • @jwvandegronden
    @jwvandegronden 년 전

    I'm so impressed with your ability to disect any subject no matter how complex, like this one. My brain stumbles and spins trying to keep pace, but at leat I manage, only thanks to your excellent work! I was sure I already was subscribed, but I wasn't! I corrected that immediately!

  • @pillettadoinswartsh4974
    @pillettadoinswartsh4974 2 년 전 +129

    As an electrical engineering student in the early 80's, I worked at a steel plant where I helped fix an analog (tube) computer that controlled a mill which cold-rolled aluminum. Just when we figured out what was wrong with it, they decided to use digital instead.

    • @ClaudiaCarranza1
      @ClaudiaCarranza1 2 년 전 +3

      What was wrong with it? Did you get told?

    • @matthewyabsley
      @matthewyabsley 2 년 전

      I think that is partly your fault, in that you could have diagnosed it much quicker by declaring "it's fucked", lol.

  • @MathGeekQ
    @MathGeekQ 2 년 전 +205

    In absolute awe of these old computers. The Rotary Ball Integrator is beautiful. Back in college, it was all about learning the symbology of how to solve integral and differential equations, and although we were told we needed to understand conceptually what we were doing, we didn't spend any time on it.
    Seeing these machines add all those waves makes that visual representation all the more fascinating and gives you a sense "aha! so that's what it means to add waves and take the integral"

    • @SenatorNyxen
      @SenatorNyxen 2 년 전 +7

      I don't think I really appreciated what integration was doing until I took a chemistry lab in college with an outdated FTIR that could only print to paper. We had to cut different peaks and weigh them to compare against each other.

    • @jellysquiddles3194
      @jellysquiddles3194 2 년 전 +1

      @Grace Jackson I never get this about educational systems, they all start backwards and expect people to be good at grasping things out of a vacuum. I tought myself the most complex stuff possible without any help from teachers or experts. When I analysed how I did it it was always "backwards" to how school tought you: 1. I saw a problem, 2. I broke it down to the basic most important aspects and (...) then I calculated it. I was always very happy with my solutions (they worked perfectly).
      (...) = 1. as an amateur having absolutely no clue on deeper scientific stuff, 2. looking up the formulas necessary for the calculation (or in case of language learning - learning the grammar), 3. learning on my own how to apply the formulas, 4. adding formulas together to solve the problem.
      Why could I never do this stuff in school or university? Because I only had a fuckton of puzzle pieces and absolutely no picture in mind of what they are supposed to ressemble. If you have a problem - like the tidal waves - you very clearly have data on what to expect and compare to your solution.
      I wish school would start out teaching the actual real world application FIRST (yes, it is extremely complicated) and break it down in smaller and smaller parts that can be tought individually. You can always see that you are in "chapter 3" of the "tidal wave problem" and where this fits in the bigger picture and what is left to do. At first you think "Sh*t I'll never be able to learn this clusterf**k?!", but having this picture of what is expected is giving such a great motivational reward when you realize you solved this HUGE problem on your own.
      How does school do it? They teach you all the tiny pieces with NO explenation of what they are for. Then at the end you get to solve a problem that is laughably easier than tides calculation and you still don't know how to solve it, because you never had to apply the puzzle pieces to real world problems. School... every time... I hate it so much.

  • @sergiismirnov1505
    @sergiismirnov1505 3 개월 전

    Thank you for this. Super interesting and presented in a super engaging way, as it always is.

  • @AtariHPC004
    @AtariHPC004 년 전

    Now you touched one of the most fascinating topics for me. Thank you!!

  • @infinitonica2362
    @infinitonica2362 2 년 전 +1421

    Driving me crazy waiting for part 2 of this. This video has ignited my imagination like CRAZY. It is amazing to live in these times with such amazing learning resources.

  • @danielhernandezvallecillo2408

    The talent this guy has is just incredible, he can teach us some incredible stuff and at the same time making us enjoy the process.

    • @EverythingButSorted
      @EverythingButSorted 2 년 전 +9

      Totally, he has come so far from the early days! The new animated bits are a nice touch too.

    • @movement2contact
      @movement2contact 2 년 전 +8

      Except about how electricity in the wires works... 😏

    • @coolboy5428
      @coolboy5428 2 년 전 +3

      Scammers

    • @jaideepshekhar4621
      @jaideepshekhar4621 2 년 전 +8

      @just some guy tired of life Bro why would you expect someone to expect details on how an anti aircraft gun worked in literally 5 minutes? This video is NOT about teaching you how an anti aircraft gun works, there are other videos and books on the topic. Sine and Cosine waves are literally taught in school, you wouldn't expect him to teach us how to do carry division in a 20 minute video on analog and digital computers lol. He gave examples of analog and digital computers, which you can research yourself if you find them interesting. I don't think you understand the point of the video: Not to explain everything perfectly, but generate the interest in YOU to learn them yourself.

    • @danielhernandezvallecillo2408
      @danielhernandezvallecillo2408 2 년 전 +1

      @just some guy tired of life Well yes you're completely right, but I'm not expecting to learn all from a single video it's just that now I know stuff that didn't know it existed, in order to have deep knowledge about it I must investigate by myself....

  • @jacobblumin4260
    @jacobblumin4260 개월 전

    Wow! Lots of good info here, both the science and the history. Thanks.

  • @iam5085
    @iam5085 년 전

    This is a much better document than anything that is shown in my TV. Have been a bit busy but could not stop watching this, excellent video.
    Telling that one has to open KRplus to see stuff like this, clearly the times of TV broadcasts is about to end, who watches TV broadcasts anymore?

  • @johnqpublic2718
    @johnqpublic2718 2 년 전 +152

    A mechanical/analog integrater? That’s badass-level of genius!

    • @darkblaze1594
      @darkblaze1594 2 년 전 +10

      Now makes me wonder how a Differentiater would look like...🤔

    • @w.e.4277
      @w.e.4277 2 년 전 +2

      Ikr!!

    • @vaisakhkm783
      @vaisakhkm783 2 년 전 +1

      If he born today... Elon musk would have become 2 most richest person....
      Or at least, Nobal would have started giving Noval prized for maths and cs.... Just to give him....

    • @iankrasnow5383
      @iankrasnow5383 2 년 전 +5

      @@darkblaze1594 A differentiator would be relatively easy to design compared to an integrator. Without having any prior knowledge of such designs, I can imagine one possible way it would work. If you have a machine which plots waves on a chart, you attach a weight to the swinging arm which plots the line, in order to increase its inertia. Then you measure the force on that arm, which is proportional to the acceleration of the needle, which is of course its derivative or second derivative, depending on what you were measuring.

    • @BowlOfRed
      @BowlOfRed 2 년 전 +6

      @@iankrasnow5383 A speedometer is operating as a differentiator, showing the time variation of the distance (or the rotation of the cable).

  • @TheBlackhawk2399
    @TheBlackhawk2399 2 년 전 +205

    The rotary ball integrator, oh God, what a fascinating piece of machinery! Can someone guide me as to where I can get my hands on one?
    Not only would it be an amazing prop to have on my desk but it would serve well as a teaching aid to Calculus students so they can develop an appreciation for the physical "analog" of the integration process.

  • @crixtuxlox88
    @crixtuxlox88 년 전

    Please, wanna see that 2nd part! Keep it up. Great Channel!!

  • @kingbradley3402
    @kingbradley3402 년 전 +1

    This is amazing. Thompson's multiplier integral is very similar to how you would perform convolution of 2 analog signals on a paper. I remember my Uni prof. Teaching it as sliding one function across the other and taking the integral.

  • @syllphrena
    @syllphrena 2 년 전 +229

    Claude Shannon is by FAR my favourite mathematician, and, in my opinion, the single most underrated. Very happy to see him get a mention here! His work enabled the ENTIRETY of modern computing, communication, and information theory. Plus, he has a lot of other really cool work, such as the sampling theorem (bane of audiophiles everywhere). And better yet, he did a significant portion of his important work as a master's student!

    • @omniyambot9876
      @omniyambot9876 2 년 전 +18

      Boole? Turing? And many many others that we don't even know like engineers and scientists are god like on logics.. They should be credite.

    • @travelinman70
      @travelinman70 2 년 전 +4

      And, he went to Michigan!! Go Blue! BBA-Accounting '96

    • @tonycook7679
      @tonycook7679 2 년 전 +12

      And Shannon's Law is still used to analyse the capacity of an electronic communications channel C = W log2(1 + S/N ), where C is the channel capacity in bits per second, W is the bandwidth in hertz, and S/N is the signal-to-noise ratio

    • @cdorcey1735
      @cdorcey1735 2 년 전 +4

      There's a movie biography of Shannon, "Bit Player". Check it out.

    • @nijuyonkadesu
      @nijuyonkadesu 2 년 전 +2

      Hey brother, all these information theory I have those topics in my UG course... dumb faculties don't care about explaining how all equations are actally used in realworld... but I'm intrested in exploring on them to get a strong understanding.... where can I start exploring to understand everyting that Shannon presented?? can you point me to some direction ?

  • @Nonya111
    @Nonya111 2 년 전 +435

    I appreciate the compromise you’ve come to around clickbait. You use a clickbaity title, but not deceptively so. Rarely if ever do I feel like you’ve over promised. You’re really setting a gold standard in how to make great content on the internet today. Thank you for all your hard, and thoughtful work!

    • @Halolaloo
      @Halolaloo 2 년 전 +24

      There was a video where he explained that he switches thumbnail and title and measures which is the most effective (highest click rate)

    • @rajkundaliya7796
      @rajkundaliya7796 2 년 전 +5

      @@Halolaloo Yeah I have often noticed his videos changing the clickbaits. I will have to see this video you are talking about, thought I missed it

    • @pixeldimond
      @pixeldimond 2 년 전 +29

      That's the best way to use clickbait, when you actually deliver on it.

    • @aerowenn433
      @aerowenn433 2 년 전 +9

      In order to get popularity in the algorithm (and compete), clickbait is a necessary evil, sadly. I don't like it either, but I'm perfectly fine with channels I want to see succeed, using it to stay relevant and gain viewership, even if they (slightly) over-promise in the title. The more people that watch Veritasium, the better, at least in my opinion.

    • @jablue4329
      @jablue4329 2 년 전 +6

      I mean, is it really clickbait if it delivers? Clickbait has a connotation of deception, imo.

  • @guybedau
    @guybedau 개월 전

    Agreed, absolutely fascinating. Wish I had known this in high school as an excellent example of why its useful to know how functions work.

  • @otiebrown9999
    @otiebrown9999 5 개월 전

    Absolutely EXCELLENT.
    The best history that I have ever seen!

  • @kasonnara
    @kasonnara 2 년 전 +378

    As a computer engineer, I was always told that every one has always dreamed to build analog computer because of the enormous performance potential over digital computers. However, it's not that engineers are dumb, that's not that simple.
    There is the precision and noise problem that you pointed out, digital component can easily erase noise and restore a digital signal which is very interresting to transmit data over the distance. But in that's not the most important point. We are curently already creating quantum compter which require extreme precision, but there isn't any decisive project for analog computers yet.
    In fact in the case of computing the true game changer is timing! Most analog components have time based behaviours, they use analog values of physical constants like voltage, intensity, etc. that doesn't change instantly because they tightly binded to physics laws. When you have a few component moving over a few minutes like old computers presented in the video, it's no big deal, but the nightmare start when you try assembling million, billion or even more of them and syncronizing them at the micro-second or nano-second. And th is not a trivial problem.
    On the other side, the main advantage of digital gates is that they are syncronized on a clock. There is a regular clock in your computers (today usually around 4 GHz) and all the memory cells that store bits of data in your computer change there state at the same time when this clock tic. The clock period is designed to be long enough to be sure that every electronic component in the whole computer chip had the time it needed to update its electric state and stabilize its value. Some components would probably take less time than that, but in the end we are garanteed that all electronic signals are stable and reliable. Just with that hypothesis all simulation tools and computer designer can make an enormous simplification by just ignoring all time related physical behaviour and instead focus on a much much much simpler finit state automata. If you look at a processor simulation tool used by computer architects you would not see anything related to voltage, intensity, or physic equations, because all of that is neglected and instead we can focus on much simpler binary signals.
    In fact I lied a bit, in practice at the level of miniaturization we reached, we still had to deal with noise, interferance, etc. but that's mostly solved globaly by building robust components and adding shielding around chips when needed, an not by solving the exact physical equaltion between every single electronic components.
    It's not that no body tried to do analogus computer but, in history, since the transistor was invented, it has always been simpler and more efficient to reduce complexity with digital computing and compensating by an increased clock speed, adding more parallel transitors computation or a more optimized chip architecture, that trying to work out the complexe equations of billions of analogous electronic components.
    It's a little bit like an intersection with traffic lights. It's theoritically possible that everyone pass the intersection at almost full speed by precisely computing everyone's speed. But since cars became widely used, we all accepted that its safer to sync everybody using traffic lights in a binary way.

    • @areadenial2343
      @areadenial2343 2 년 전 +17

      What about optical computers? Some startups and research groups are investigating light as a signal and calculation medium, using wave interference to perform calculations. While most of these are digital, I think there's potential to make analog optical computers without as many of the downsides you mentioned. I wonder if that's what part 2 of this video will be about, but I could be wrong.

    • @FreakMeat74
      @FreakMeat74 2 년 전 +8

      @@areadenial2343 I'd like to hear this dudes opinion on this, educate us good sirs

    • @heybemyeyes
      @heybemyeyes 2 년 전

      @Kasonnara
      Do u think that there is problems today that could only be truly solved by some powerful analog computer?

    • @vivaselementum
      @vivaselementum 2 년 전 +8

      If I had a billion laying around I would simply start a non-profit organization to preserve and fund more of these analog computers. You know, just in case of... electronic doomsday, massive EMP's, GRB's or any of such.

    • @kylechin8706
      @kylechin8706 2 년 전 +8

      So round abouts are analog traffic lights?

  • @rajkundaliya7796
    @rajkundaliya7796 2 년 전 +234

    Man. The quality and exactness of your visuals have literally exponentially increased over time. New videos are simply amazing.... It always makes me wonder whether I should start a career in research

  • @dandan1364
    @dandan1364 년 전 +5

    Math cs major here … my head hurts. Wish there was more detail and examples. Will watch again.

  • @Agaures
    @Agaures 23 일 전

    This subject is wrinkling my brain. The intelligence and creativity of some of these folks is incredible.

  • @homomorphic
    @homomorphic 2 년 전 +56

    I come from at least 5 generations of clockmakers. My dad was the last generation to actually be a clockmaker and I am a software engineer. Perhaps my grandkids will be clockmakers again :-)

  • @aartim9809
    @aartim9809 2 년 전 +431

    I wonder what would have happened if the ship with the Antikythera device hadn't sunk... would it have inspired more technological advancement? Or would it have been melted down and forgotten, and only by it sinking was it preserved?

    • @steamcastle
      @steamcastle 2 년 전 +118

      it was likely just one of several such devices, it is only interesting because people had forgotten and reinvented the technology.
      more useful than the Rosetta Stone back then less useful now.

    • @thinkthing1984
      @thinkthing1984 2 년 전 +52

      I think it would in fact belong to the group of "that which could've furthened human knowledge, had it not been destroyed"- e.g. Alexandria's library, or Alan Turing's life

    • @Sashazur
      @Sashazur 2 년 전 +57

      It was definitely not a one-off, it is way too complex for that. Presumably there were at least dozens of preceding devices built over years, maybe centuries, as the creators learned and refined their craft. They were clearly rare and expensive - only toys for the rich or the ruling class. So the seeds of more technological advancement were available, but it obviously needed more than just those seeds to sprout into anything like an industrial revolution - the ancient world was just so different from western societies of the past few centuries; for one thing they had pervasive slavery so there was not much demand for machines to do work.

    • @joesterling4299
      @joesterling4299 2 년 전 +40

      Ancient Greece was the most dramatic Greek tragedy. Split into science and mysticism factions, the mystics eventually won. Makes me wonder if we're headed for the same fate today in this country. Ignorant mob rule destroys the educated intelligentsia that drives progress.

    • @hermannabt8361
      @hermannabt8361 2 년 전 +16

      We have documents of these devices being in the homes of rich Romans. It’s not a unique thing.

  • @jeb3358
    @jeb3358 년 전

    I had to come back and watch this one again after your recent video on FFTs. This is really fascinating.

  • @thomasnewbery7449
    @thomasnewbery7449 년 전 +2

    My first view of an analog computer was of a Central Air Data Computer (CADC) made by Bendix Corp. It was enclosed in a clear plastic bubble to show us (airmen in an Aircraft Instrument Systems class at Chanute AFB) back in '65-'66 what we would be dealing with in fixing the F105 fighter jet. It had about 4 to 8 (?) levels of gears, differentials, cams and dual-synchronous transmitters to perform calculations from inputs of airspeed, altitude, and temperature and send the results to various systems throughout. It was a cylinder about one foot in diameter and about 18" in length. About the only system it didn't affect was the ejection seat! AAAHHh, the good-ole days!!!

  • @GiovanniPuozzo
    @GiovanniPuozzo 2 년 전 +312

    The Antikythera mechanism and the so called ‘Hero’s engine’ make me think of a quote that read:
    “If ancient civilisations had any idea of how much potential their technologies held, we would already be exploring the neighbouring stars” (Arthur C. Clarke)

    • @MrUssy101
      @MrUssy101 2 년 전 +6

      Why obnoxious creator of this channel thinks that his audience have not heard of things and he the only one introduce us to it ???

    • @melonhusk6642
      @melonhusk6642 2 년 전 +43

      @@MrUssy101 Woah, easy there, easy. You've been out cold for a couple of days now. Why don't you just relax a second, get your bearings?

    • @RenoirThornwood
      @RenoirThornwood 2 년 전 +79

      @@MrUssy101 because the Entire point of his channel is to introduce people to things they might not have heard of...

    • @johnqpublic2718
      @johnqpublic2718 2 년 전

      It just wasn’t meant to be. Too many variables

    • @soggybiscotti8425
      @soggybiscotti8425 2 년 전 +9

      @@MrUssy101 your English is terrible. Perhaps you should go find some videos about that instead.

  • @kuykendallwebfamily
    @kuykendallwebfamily 2 년 전 +65

    If my old teachers/professors had led with this fascinating usage of Fourier Series I may have been far more enthralled for the process.

  • @LordGod
    @LordGod 3 개월 전

    Watching this while listening to "Rainy Jazz Cafe - Slow Jazz ..." music in the background is mint. Makes this so much more enjoyable!!!

  • @jameslovelady7751
    @jameslovelady7751 4 개월 전

    My first job at Lockheed in 1959 was to write the specifications and handle the selection of a supplier for an analog computer for a Navy radar plane. It was to convert the forward and sideways ground speed from the dappled radar into latitude and longitude. I got to visit companies that made all the precision components.

  • @elaicatubag8191
    @elaicatubag8191 2 년 전 +11

    13:24
    :"source?"
    :" I dreamt about it "

  • @Starphot
    @Starphot 2 년 전 +111

    When I joined the Navy in 1971, they still operated analog computers in some of their fire control systems. An entrance exam showed some simple gear output questions. I worked on a Norden system that was a true hybrid. It had a few analog computers that operated on gear ratios, electronic pots, accurate voltage references, relays, shaft encoders, etc. to a digital computer that had vacuum tubes, early 1960's transistors, late 1950's developed magnetic core memory, magnetic drum memory with about 2 dozen read/write heads in it. Not an integrated circuit chip in the whole system. This fit inside an attack aircraft that operated off of aircraft carriers plus ordinance and 2 crew. This unlike the aforementioned bombsight, actually got the job done. Yet these break down and needs constant maintenance and like the airframe it is attached to gets old and outdated.

    • @nunyabiznez6381
      @nunyabiznez6381 2 년 전 +2

      My grandfather built analog computers into battleships in WWII. He described one as being roughly 1000 cubic meters in size with the mechanical components weighing hundreds of tons. He also described them as being accurate to within 60 decimal places and I still don't have a pocket calculator that can do that.

    • @everready59
      @everready59 2 년 전 +1

      Cyperpunk in the theatre of the REAL.

    • @uncletiggermclaren7592
      @uncletiggermclaren7592 2 년 전 +1

      @@nunyabiznez6381 The one he described must have been on land. It couldn't have been additional *hundreds* of tonnes placed inside a WW2 battleship.
      The Mark 37 system fire control system in the Iowa class battleships, for example, weighed 1 400 kilogrammes.

    • @Starphot
      @Starphot 2 년 전 +1

      @@nunyabiznez6381 Yes, and these computers were in the training flicks we saw in avionics school.

    • @jamesbernards8409
      @jamesbernards8409 2 년 전 +1

      Thank you for sharing your story and insight sir

  • @umitdolap1733
    @umitdolap1733 년 전

    Wow! Now this is a great example of applying integrals. Thanks Veritasium!

  • @tomwithuhn9472
    @tomwithuhn9472 년 전

    Double thumbs up. I really appreciate the work you put into this. Thank you!

  • @chrisfromsouthaus2735
    @chrisfromsouthaus2735 2 년 전 +84

    I had never really thought about the digit in digital, so I had always considered digital to be synonymous with electrical, and analogue with mechanical. Your mechanical digital computer taught me something new today.

    • @AttilaAsztalos
      @AttilaAsztalos 2 년 전 +4

      Be amazed then - it simply comes from "digit" as in "finger". That which you use to count up to ten, for you have ten of them. Which made "digit" just another word for "number between one and ten, that we use to assemble really large numbers made of multiple digits". So "digital" is just another word for "numeric", as in "based on numbers".

    • @sixty2612
      @sixty2612 2 년 전 +1

      I always thought it had to do with the Greek prefix “di” meaning two or double (as in dichotomy or carbon dioxide) because 1/0 or true/false is a pair

    • @scurus11scurus
      @scurus11scurus 2 년 전

      @@AttilaAsztalos so “getting digital” is another term for “getting handsy”?…
      now i understand where “compute her” comes from…
      🤔😏

    • @socialist-strong
      @socialist-strong 2 년 전 +1

      Analogue means 1 to 1. Every button or input corresponds with a specific output.
      I don't understand the mechanical digital computer. If we didn't assign 1 and 0 to the outputs, would it still be digital?

    • @SToXC_.
      @SToXC_. 2 년 전 +1

      @@socialist-strong they just have to be 2 different states

  • @InssiAjaton
    @InssiAjaton 2 년 전 +120

    I had a lab exercise to simulate a control system stability with an analog computer. The analog computer was built using vacuum tube op-amps. Their signal range was +/- 100 V. A bit later, where I worked, my boss had also earlier used the same analog computer and we started discussing if we could build our own, but with recently introduced semiconductor op--amps. Well, that discussion resulted in a task for me to design and build one. What I ended putting together was a box with 10 op-amps, a bunch of stackable resistors and capacitors and a few special units, and a panel with banana sockets for the stackable components. All along with amplifier symbols on the panel. The signal range was reduced to just +/- 10 V. My boss was soon happily simulating not only his control systems, but also extrusion and cooling processes for high voltage cable insulations. That was just before I got transferred to another division of the company, where new challenges were waiting me in a new R&D lab. So I myself never had the opportunity of really learning to use "my" analog computer in anything but simple servo loop simulations (optimizations).

  • @shakti1528
    @shakti1528 년 전

    DUDE I LOVE THIS VIDEO IT HAS HELPED ME SO MUCH FOR MY COMPETTITION MAN THIS IS DOPE.

  • @someguydino6770

    thanks for canning the "mugging" (like that roper guy) and upping the quality of the graphics and for doing more in-depth research

  • @AtomicPunk23
    @AtomicPunk23 2 년 전 +44

    That was amazingly cool. Doing a discrete Fourier transform by hand is hard enough, but designing a machine to do it with nothing but gears and pullies just blows my mind. We have it so easy now with digital computers and software. We can program anything we want as sloppily as we want and a compiler will find a way to get a CPU to do the work. With analog you can't succeed without a complete understanding of every aspect of what you're building.

  • @thenotflatearth2714
    @thenotflatearth2714 2 년 전 +12

    6:10
    "Then he had a stroke"
    *sweating profusely*
    "of inspiration"

  • @catchthewave2172
    @catchthewave2172 9 개월 전

    Wow, this is so informinga and not one bit outdated

  • @mepacrina9291
    @mepacrina9291 년 전

    10:00
    For calculating harmonic component you need two multipliers ( sin and cos ) , not only one as shown (and some square / root / add) .
    Otherwise a very good explanation and well documented history .
    Not to mention a good animation describing the machines !

  • @tykjpelk
    @tykjpelk 2 년 전 +279

    Photonic computers is an interesting type of analog computer that's just taking off. By making a microchip with what can be described as tunable partially reflecting mirrors, we can make a system that's essentially a matrix multiplication. Because the chip only changes to be re-programmed, it can crunch through multiplications as fast as you can put them in. Constant time, or even faster depending on how you look at it.

    • @honkhonk8009
      @honkhonk8009 2 년 전 +30

      Even normal computers can crunch through multiplication/instructions as fast as you can put them in. problem is, they get hot LOL.
      photonic seems good tho for a certain types of calculations tho

    • @fiusionmaster3241
      @fiusionmaster3241 2 년 전 +5

      This is very interesting. Thanks for this info my bro.

    • @benjaminmuller9348
      @benjaminmuller9348 2 년 전 +28

      @@honkhonk8009 I mean you can't, the clock speed isn't only limited by the cooling system.

    • @Tyler11821
      @Tyler11821 2 년 전

      @@benjaminmuller9348 The point is information entropy produces heat

    • @felix-gena6595
      @felix-gena6595 2 년 전 +6

      @@benjaminmuller9348 Voltage and current is a problem since you need big power sources to run fast, moreover there is a point when it just too much voltage through the semi conductor and at that point you get a shortcircuit, so there is a physical limit that we are already hitting since our electronics are a few atoms wide now days.

  • @IvanHaboic
    @IvanHaboic 2 년 전 +49

    7:11 Tower's proposed solution is absolutely ingenious, it's mindblowing. Incredibly cool :D

  • @MAgy9ko
    @MAgy9ko 년 전

    It's one of the greatest videos I have ever seen.
    Well-done .

  • @steveswoodworking2504

    I've worked with computers my whole life. I had the first calculator of anyone at my high school. Then the first programmable calculator, then the first computer. I'd heard of analog computers, but I never knew anything about them. The tide calculations using the Fourier transform was brilliant!

  • @toastrecon
    @toastrecon 2 년 전 +223

    Reminds me of an internship I had while I was in engineering school: I worked for the Geophysical Institute in Alaska, with a group that analyzed synthetic aperture RADAR data. Back then, gigabyte file sizes were still pretty hard to work with and the data took hours to process, something that most SAR devices do in real time now (I think). They said that in the early days of SAR, they used some kind of optical analog computer that used lenses and mirrors to do all of the calculations. Fascinating.

    • @leif1075
      @leif1075 2 년 전 +4

      What is a synthetic aperture..like as opposed to an organic or naturally occuring aperture? Or wjat kind of radar technically has some kind kf aperture I'm curjous and not familiar? I'm only thinking of like a radar satellite dish or antenna I guess.

    • @youtubeuser206
      @youtubeuser206 2 년 전

      So in other words you're a liar liar pants on fire. Got it.

    • @leif1075
      @leif1075 2 년 전

      @@youtubeuser206 who's a liar David? If so why?

    • @toastrecon
      @toastrecon 2 년 전 +5

      @@leif1075 the “synthetic” means that it’s calculated rather than natural. Maybe a bad analogy would be: if you have a camera with a tiny lens but you moved it along a really accurate path while taking a thousand images, if you used computers to stitch them all together and overlay them, you could achieve an image that was larger than your mini camera could take.
      Radar images are way more accurate with a very large dish or antenna so they can “resolve” small targets. Well, big antennas and dishes like that are expensive and hard to put on airplanes and even harder to put into space. So, some smart people figured out that if you took a smaller antenna, and made send out radar pulses almost continuously, and then did some tricky math, you ended up being able to get really good resolution by “synthesizing” the “aperture” of the radar.

    • @leif1075
      @leif1075 2 년 전 +3

      @@toastrecon thanks what's the aperture though. The size of the antenna then or region it transmits across?

  • @JackGordon
    @JackGordon 2 년 전 +352

    Loved the animations. This was an amazing video

  • @pochiluis0570
    @pochiluis0570 년 전 +1

    Wait….. ¿You put a personalised AD in your video to promote a new channel? ¿¿¡¡HOW DID YOU DID THAT?? you genius!! ¡I never saw that before! that was very original and I specifically love how you did because you started the ad with “so it looks like you are about to watch a Veritasium video” using the 5 second wait to skip the AD to attract the interest of the viewer to listen to the ad and not skip the add immediately ¡I loved you guys a great! :D

  • @Ashikshanavas009

    Your contents are really good,nice work.Can you do a video on Cybersecurity?

  • @aphinion
    @aphinion 2 년 전 +31

    I'm totally fascinated by that analog pully frequency sumarization device and that mechanical fourier transformation. Such a beautifully simple solution.. and man, that was just 126 years ago... Mind=Blown.