Why the Future of AI & Computers Will Be Analog

Undecided with Matt Ferrell
9 Apr 202417:35

Summary

TLDRThe video script discusses the resurgence and potential of analog computing in a world dominated by digital technology. It highlights the energy efficiency of analog systems, which can be 1,000 times more efficient than digital counterparts, and how this could be part of the solution to the climate crisis. The script also touches on the limitations of digital computing, such as physical boundaries and energy consumption, and introduces companies like Mythic and Aspinity that are developing analog chips for modern applications. The potential for hybrid computers that combine the best of both worlds is also explored, hinting at a future where analog computing could play a significant role in our daily lives.

Takeaways

  • 📺 Analog computing, once overshadowed by digital, is experiencing a resurgence due to its potential energy efficiency and unique problem-solving capabilities.
  • 🌡️ Analog systems have an infinite number of states compared to digital systems, which rely on a finite number of states determined by bits or transistors.
  • 🚀 The Space Age and personal computers marked a decline in the size of computing devices, but analog computing might be reaching physical limits in terms of miniaturization.
  • 💡 Digital computing, particularly in areas like AI and cryptocurrencies, is increasingly energy-intensive, prompting interest in more efficient alternatives like analog computing.
  • 🌍 A return to analog computing could significantly reduce energy consumption, with analog processes sometimes being 1,000 times more efficient than digital ones.
  • 🛠️ Analog computers operate based on physical models that correspond to the values of the problem being solved, as opposed to digital computers that follow algorithms and discrete data.
  • 📉 The limitations of digital computing are being recognized, with experts like Bernd Ulmann suggesting that we are approaching the fundamental physical boundaries of digital elements.
  • 🔧 Analog computing's continuous data processing allows for real-time problem-solving and efficient parallel processing without the need for cooling facilities.
  • 🔄 Hybrid computers that combine the energy efficiency of analog with the precision of digital are being explored for future technology development.
  • 🏠 Everyday applications of analog computing could include low-power sensors for voice-enabled devices, environmental monitoring, and wearable technology.

Q & A

  • What is the fundamental difference between analog and digital computing?

    -Analog systems have an infinite number of states and can represent a continuous range of values, while digital systems rely on a finite number of states determined by the number of bits or transistors that can be switched on or off.

  • How has the advancement of digital computing impacted the size of computing devices?

    -Digital computing has led to a significant reduction in the size of computing devices, from large machines to personal computers and smartphones, following the predictions of Moore's Law which suggests a doubling of transistors on integrated circuits approximately every two years.

  • What are some of the environmental concerns associated with digital computing?

    -Digital computing, especially in data centers and power-hungry applications like cryptocurrencies and AI, is becoming increasingly energy-intensive, contributing to global energy consumption and carbon emissions. It also requires substantial cooling systems, which can strain water resources.

  • Why is analog computing considered more energy-efficient than digital computing?

    -Analog computing can perform the same tasks as digital computing with a fraction of the energy because it operates on a physical model corresponding to the problem being solved, which doesn't require the switching of transistors and can handle continuous data in real time.

  • What is the significance of the MONIAC computer in the history of analog computing?

    -The MONIAC (Monetary National Income Analogue Computer), created by economist Bill Phillips in 1949, is a classic example of analog computing. It was designed to simulate the Great British economy on a macro level using water to represent money flow, and it could function with an approximate accuracy of ±2%.

  • What are some practical applications of analog computing today?

    -Practical applications of analog computing today include flight computers used by pilots for manual calculations, as well as emerging technologies like low-power sensors for voice-enabled wearables, sound detection systems, and heart rate monitors.

  • How does the concept of Amdahl's law relate to the limitations of digital computing?

    -Amdahl's law suggests that the speedup of a system is limited by its sequential operations that cannot be parallelized. As a result, adding more processors does not always lead to proportional improvements in speed, which is a challenge for digital computers when trying to handle increasingly complex tasks efficiently.

  • What are some of the challenges in integrating analog and digital systems?

    -Integrating analog and digital systems requires seamless connectivity and synchronization between the two paradigms, which can be technically challenging. It also involves developing hybrid computers that combine the energy efficiency of analog with the precision and flexibility of digital computing.

  • What is the potential impact of analog computing on machine learning and AI?

    -Analog computing has the potential to significantly reduce the power consumption of machine learning and AI applications by offering a more energy-efficient computing method. Companies like Mythic are developing analog matrix processors that aim to deliver the compute resources of a GPU at a fraction of the power consumption.

  • How might analog computing change the devices we use in our daily lives?

    -As analog computing becomes more integrated with digital systems, we could see devices that are always on, like voice-enabled wearables and smart home sensors, consuming much less power. This could lead to longer battery life and reduced environmental impact without sacrificing functionality.

  • What are some ways for individuals to explore analog computing at home?

    -Individuals can explore analog computing at home through models like the Analog Paradigm Model-1, which is designed for experienced users to assemble themselves, or The Analog Thing (THAT), which is sold fully assembled and can be used for a variety of applications from simulating natural sciences to creating music.

Outlines

00:00

📺 The Resurgence of Analog Computing

This paragraph introduces the concept of analog computing and its resurgence in modern technology. It discusses the shift from analog to digital computing and the potential of analog computing to impact daily life. The speaker, Matt Ferrell, shares his curiosity about analog computing sparked by a Veritasium video and his subsequent exploration of the topic. The contrast between analog and digital systems is highlighted, emphasizing the infinite states of analog versus the finite states of digital, represented by bits. The energy efficiency of analog computing is also mentioned as a potential solution to the growing energy demands of digital computing, particularly in the context of cryptocurrencies and AI.

05:02

💡 Historical Analog Computers and Their Applications

This paragraph delves into the history and practical applications of analog computers. It mentions the Moniac National Income Analogue Computer (MONIAC) as a prime example, which was designed to simulate the British economy. The paragraph also discusses the accuracy of analog computers and their continued relevance, such as pilots using slide rules for calculations. The contrast between the convenience of digital devices and the specialized applications of analog computers is explored, highlighting the limitations of digital computing and the potential for analog computing to break through these barriers.

10:06

🚀 Pushing the Limits of Digital Computing

This paragraph examines the limitations of digital computing, referencing the predictions made by Gordon Moore, known as Moore's Law, and the physical boundaries that digital elements are reaching. It discusses the challenges of miniaturizing computer chips further and the heat generation and cooling requirements of dense components. The paragraph also touches on Amdahl's law and its implications for the efficiency of digital computers, especially when considering sequential operations and the diminishing returns of adding more processors. The potential of analog computing to offer a more parallel and energy-efficient approach is contrasted with the sequential nature of digital computing.

15:06

🌐 Future of Analog Computing in Everyday Life

The final paragraph explores the future possibilities of analog computing in everyday life, discussing the development of hybrid computers that combine the energy efficiency of analog with the precision of digital. It mentions companies like Mythic and Aspinity that are working on analog chips for machine learning and low-power sensors. The potential applications of analog computing in household devices are highlighted, such as voice-enabled wearables and heart rate monitoring. The paragraph also addresses the challenges of making analog programming more accessible and the need for seamless connectivity between analog and digital systems. It concludes with a call to action for the audience to consider the potential of analog computing and engage in further discussion.

Mindmap

Keywords

💡Analog computing

Analog computing refers to the use of continuous or non-discrete signals to represent information. In the video, it is presented as a potentially more energy-efficient alternative to digital computing, with examples such as the MONIAC machine simulating the British economy and slide rules used by pilots for calculations.

💡Digital computing

Digital computing involves the use of discrete values or a binary system (bits) to process information. It is the predominant computing method today, relying on transistors that can be switched on or off. The video contrasts digital computing with analog, discussing its energy consumption and the physical limits of transistor miniaturization.

💡Energy efficiency

Energy efficiency refers to the amount of energy used to perform a certain task or achieve a desired output. The video highlights that analog computing can be significantly more energy-efficient than digital computing, which is becoming increasingly important due to the growing energy demands of technologies like AI and cryptocurrencies.

💡Moore's Law

Moore's Law is a prediction made by Gordon Moore, co-founder of Intel, that the number of transistors on an integrated circuit would double approximately every two years, leading to increased computing power at a constant cost. The video discusses the impending limits of this law due to physical constraints of material and atomic sizes.

💡Amdahl's Law

Amdahl's Law is a formula that estimates the maximum improvement in the execution time of a program by adding more hardware resources, given a certain portion of the program that cannot be parallelized. The video uses the analogy of a digital clock to explain the discrete nature of digital information processing, which is subject to the limitations of Amdahl's Law.

💡Hybrid computing

Hybrid computing refers to the combination of analog and digital computing methods to leverage the strengths of both systems. The video suggests that hybrid computers could provide the precision of digital with the energy efficiency of analog, which is particularly relevant for power-hungry applications like machine learning.

💡Machine learning

Machine learning is a subset of artificial intelligence that allows computers to learn from and make predictions or decisions based on data. The video discusses the energy demands of machine learning, especially generative AI, and how analog computing could contribute to more energy-efficient solutions.

💡Data centers

Data centers are large facilities that house computer systems and associated components, such as servers, storage systems, and networking equipment. They are significant consumers of electricity and water for cooling. The video addresses the environmental and financial impact of data centers' energy consumption and the potential for analog computing to alleviate these concerns.

💡Differential equations

Differential equations are mathematical equations that describe the relationship between a function and its rates of change. They are essential in modeling dynamic systems or problems involving change over time. In the context of analog computing, differential equations are used to program analog machines by translating the equation into physical components of the computer.

💡Surfshark

Surfshark is a virtual private network (VPN) service provider mentioned as a sponsor in the video. VPNs offer security and privacy features, such as hiding one's IP address and bypassing geo-restrictions on content. The video discusses Surfshark's features, including its ability to unlock content and provide better prices by changing the user's perceived location.

💡Climate crisis

The climate crisis refers to the ongoing, significant changes in global weather patterns and room temperature caused by human activities, particularly the release of greenhouse gases like carbon dioxide. The video connects the energy efficiency of analog computing to the broader issue of the climate crisis, suggesting that more efficient technologies can help mitigate environmental impacts.

Highlights

Analog computing is making a comeback and is also something that never really left.

Analog systems have an infinite number of states, unlike digital systems which rely on a fixed number of states.

Digital computing is becoming increasingly energy intensive, with significant implications for global energy consumption.

Analog computing could be part of the solution to energy efficiency, as it can accomplish tasks for a fraction of the energy.

The MONIAC, created in 1949, is an example of an analog computer used to simulate the economy.

Pilots still use flight computers, a form of slide rule, for calculations without the need for electricity.

Digital devices provide convenience, but analog computing has its own strengths, such as energy efficiency.

Digital computers are hitting basic physical boundaries, limiting how much further they can be shrunk.

Moore's Law, which predicts the doubling of transistors on a chip, is nearing its limits.

The more components on a chip, the harder it is to cool, leading to significant energy and resource use.

Research on new approaches to analog computing has led to the development of materials that don’t need cooling facilities.

Amdahl's law suggests that there will always be operations that must be performed sequentially in digital computing.

Analog computers can work in parallel, allowing for more efficient problem-solving without the need for sequential operations.

Hybrid computers that combine the best features of both digital and analog computing may be the future.

Mythic's Analog Matrix Processor chip aims to deliver significant compute resources at a fraction of the power consumption.

Aspinity's AML100 chip can act as a low-power sensor for various applications, with potential energy savings of up to 95%.

Analog computing, with its potential for energy efficiency and real-time processing, could become more approachable and accessible.

Transcripts

00:00

If your taste in TV is anything like  mine, then most of your familiarity with  

00:03

what analog computing looks like probably  comes from the backdrops of something like

00:07

Columbo. Since digital took over the world,  analog has been sidelined into what seems  

00:12

like a niche interest at best. But this retro  approach to computing, much like space operas,  

00:16

is both making a comeback, and also something  that never really left in the first place.

00:21

I found this out for myself about a year  ago, when a video from Veritasium sparked  

00:24

my curiosity about analog computing. After that,  I started to read a few articles here and there,  

00:29

and I gotta say…it broke my brain a bit. What  I really wanted to know, though, was this:  

00:34

How can analog computing impact our  daily lives? And what will that look  

00:38

like? Because I definitely don’t  have room in my house for this.

00:42

I’m Matt Ferrell … welcome to Undecided. 

00:51

This video is brought to you by Surfshark and all  of my patrons on Patreon, but more on that later.

00:56

Depending on how old you are, you may remember  when it was the norm for a single computer to  

01:00

take up more square footage than your average  New York City apartment. But after the end of the  

01:04

Space Age and the advent of personal computers,  our devices have only gotten smaller and smaller.  

01:09

Some proponents of analog computing argue that  we might just be reaching our limits when it  

01:13

comes to how much further we can shrink. We’ll  get to that in a bit, though. Emphasis on bits.

01:18

Speaking of bits, this brings us to the  fundamental difference between analog  

01:22

and digital. Analog systems have an infinite  number of states. If I were to heat this room  

01:27

from 68 F to 72 F, the temperature would  pass through an infinite set of numbers,  

01:33

including 68.0000001 F and so on. Digital  systems are reliant on the number of “bits”  

01:41

or the number of transistors that are  switched either on or off. As an example,  

01:45

an 8-bit system has 2^8, or 256 states. That  means it can only represent 256 different numbers.

01:53

So, size isn’t the only aspect of the  technological zeitgeist that’s changed. Digital  

01:58

computers solve problems in a fundamentally  different way from analog ones. That’s led  

02:03

to some pretty amazing stuff in modern day…at  a cost. Immensely energy intensive computing  

02:09

is becoming increasingly popular. Just look at  cryptocurrencies and AI. According to a report  

02:13

released last year by Swedish telecommunications  company Ericsson, the information and  

02:18

communication technology sector accounted for  roughly 4% of global energy consumption in 2020.

02:23

Plus, a significant amount of digital  computing is not the kind you can take to  

02:27

go. Just among the thousands of data centers  located across the globe, the average campus  

02:32

size is approximately 100,000 square feet (or  just over 9,000 square meters). That's more  

02:37

than 2 acres of land! Data scientist  Alex de Vries estimates that a single  

02:42

interaction with a LLM is equivalent to “leaving  a low-brightness LED lightbulb on for one hour.”

02:48

But as the especially power-hungry data centers,  neural networks, and cryptocurrencies of the world  

02:53

continue to grow in scale and complexity…we still  have to reckon with the climate crisis. Energy  

02:58

efficiency isn’t just good for the planet,  it’s good for the wallet. A return to analog  

03:02

computing could be part of the solution. The  reason why is simple: you can accomplish the  

03:07

same tasks as you would on a digital setup  for a fraction of the energy. In some cases,  

03:12

analog computing is as much as 1,000 times  more efficient than its digital counterparts.

03:17

Before we get into exactly how it works and why  we’re starting to see more interest in analog  

03:21

computers again, I need to talk about another  piece of tech that can really help in your daily  

03:25

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03:30

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03:36

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03:49

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03:53

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03:57

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04:03

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Link is in the description below. Thanks  to Surfshark, for supporting the channel.  

04:23

And thanks to all of you, as well as my patrons,  who get early, ad-free versions of my videos. So  

04:28

back to how much more energy efficient analog  computing is from its digital counterparts.

04:32

To understand how that works, exactly, we  first need to establish what makes analog  

04:37

computing…analog. The same way you would make  a comparison with words using an analogy,  

04:42

analog computers operate using a physical  model that corresponds to the values of  

04:46

the problem being solved. And yeah,  I did just make up an analog analogy.

04:51

A classic example of analog computing is the  Monetary National Income Analogue Computer,  

04:56

or MONIAC, which sounds like a long forgotten car  brand, which economist Bill Phillips created in  

05:01

1949. MONIAC has a single purpose: to simulate  the Great British economy on a macro level.  

05:08

Within the machine, water represented money as  it literally flowed in and out of the treasury.  

05:13

Phillips determined alongside his colleague  Walter Newlyn that the computer could function  

05:16

with an approximate accuracy of ±2%. And  of the 14 or so machines that were made,  

05:22

you can still find the first churning away  at the Reserve Bank Museum in New Zealand.

05:26

It’s safe to say that the MONIAC worked  (and continues to work) well. The same goes  

05:31

for other types of analog computers, from  those on the simpler end of the spectrum,  

05:34

like the pocket-sized mechanical  calculators known as slide rules,  

05:38

to the behemoth tide-predicting  machines invented by Lord Kelvin.

05:43

In general, it was never that analog computing  didn’t do its job — quite the opposite. Pilots  

05:48

still use flight computers, a form of slide  rule, to perform calculations by hand,  

05:53

no juice necessary. But for more generalized  applications, digital devices just provide a level  

05:58

of convenience that analog couldn’t. Incredible  computing power has effectively become mundane.

06:04

To put things into perspective, an iPhone  14 contains a processor that runs somewhere  

06:08

above 3 GHz, depending on the model.  The Apollo Guidance Computer, itself a  

06:12

digital device onboard the spacecraft  that first graced the moon’s surface,  

06:16

ran at…0.043 MHz. As computer science  professor Graham Kendall once wrote,  

06:22

“the iPhone in your pocket has over 100,000 times  the processing power of the computer that landed  

06:27

man on the moon 50 years ago.” … and we use it  to look at cat videos and argue with strangers.

06:33

In any case, that ease of use is one of the  reasons why the likes of slide rules and  

06:37

abacuses were relegated to museum displays  while electronic calculators reigned king.  

06:42

So much for “ruling.” But, while digital  has a lot to offer, like anything else,  

06:48

it has its limits. And mathematician  and self-described “analog computer  

06:51

evangelist” Bernd Ulmann argues that we can’t  push those limits much further. In his words:

06:56

“Digital computers are hitting basic  physical boundaries by now. Computing  

07:00

elements cannot be shrunk much more than today,  

07:02

and there is no way to spend even more  energy on energy-hungry CPU chips today.”

07:08

It’s worth noting here that Ulmann said  this in 2021, years ahead of the explosion  

07:12

of improvements in generative AI we’ve  witnessed in just the past few months,  

07:17

like OpenAI’s text-prompt-to-video  model, Sora. Which, really disturbs  

07:22

me and I'm very excited by all at the same  time, I need to make a video about that.

07:25

But what did he mean by “physical  boundaries”? Well…digital computing  

07:29

is starting to bump up against the law.  No, not that kind…the scientific kind.  

07:36

There’s actually a few that are at play  here. We’ve already started talking about  

07:39

the relationship between digital computing  and size, so let’s continue down that track.

07:43

In a 1965 paper, Gordon Moore, co-founder of  Intel, made a prediction that would come to  

07:48

be known as “Moore’s Law.” He foresaw that  the number of transistors on an integrated  

07:51

circuit would double every year for the  next 10 years, with a negligible rise in  

07:56

cost. And 10 years later, Moore changed his  prediction to a doubling every two years.

08:01

As Intel clarifies, Moore’s Law isn’t a scientific  observation, and Moore actually isn’t too keen on  

08:06

his work being referred to as a “law.” However,  the prediction has more or less stayed true as  

08:11

Intel (and other semiconductor companies)  have hailed it as a goal to strive for:  

08:16

more and more transistors on smaller and  smaller chips, for less and less money.

08:21

Here’s the problem. What happens when we can’t  make a computer chip any smaller? According to  

08:26

Intel, despite the warnings of experts in the past  few decades, we’ve yet to hit that wall. We can  

08:31

take it straight from Moore himself, though,  that an end to the standard set by his law is  

08:35

inevitable. When asked about the longevity of his  prediction during a 2005 interview, he said this:

08:41

“The fact that materials are made of atoms is  the fundamental limitation and it's not that  

08:45

far away. You can take an electron micrograph from  some of these pictures of some of these devices,  

08:50

and you can see the individual atoms of  the layers. The gate insulator in the most  

08:54

advanced transistors is only about three molecular  layers thick…We're pushing up against some fairly  

08:59

fundamental limits, so one of these days we're  going to have to stop making things smaller."

09:04

Not to mention, the more components you cram  onto a chip, the hotter it becomes during use,  

09:08

and the more difficult it is to cool down. It’s  simply not possible to use all the transistors  

09:13

on a chip simultaneously without risking a  meltdown. This is also a critical problem  

09:17

in data centers, because it’s not only  electricity use that represents a huge  

09:21

resource sink. Larger sites that use liquid  as coolant rely on massive amounts of water  

09:26

a day — think upwards of millions of gallons.  In fact, Google’s data centers in The Dalles,  

09:31

Oregon, account for over a  quarter of the city’s water use.

09:34

Meanwhile, emerging research on new  approaches to analog computing has  

09:37

led to the development of materials that  don’t need cooling facilities at all.

09:41

Then there’s another law that stymies  the design of digital computers:  

09:44

Amdahl’s law. And you might be able to get a  sense of why it’s relevant just by looking at  

09:49

your wrist. Or your wall. Analog clocks, the kind  with faces, can easily show us more advantages of  

09:55

analog computing. When the hands move forward on  a clock, they do so in one continuous movement,  

10:00

the same way analog computing occurs in real time,  with mathematically continuous data. But when you  

10:05

look at a digital clock, you’ll notice that it  updates its display in steps. That’s because,  

10:10

unlike with analog devices, digital information  is discrete. It’s something that you count,  

10:14

rather than measure, hence the  binary format of 0s and 1s.

10:18

When a digital computer tackles a problem,  it follows an algorithm, a finite number  

10:21

of steps that eventually lead to an answer.  Presenting a problem to an analog computer is  

10:26

a completely different procedure, and this cute  diagram from the ‘60s still holds true today:

10:32

First, you take note of the physical laws  that form the context of the problem you’re  

10:35

solving. Then, you create a differential  equation that models the problem. If your  

10:40

blood just ran cold at the mention of  math, don’t worry. All you need to know  

10:44

is that differential equations model dynamic  problems, or problems that involve an element  

10:48

of change. Differential equations can be used  to simulate anything from heat flow in a cable  

10:53

to the progression of zombie apocalypses. And  analog computers are fantastic at solving them.

10:58

Once you’ve written a differential equation,  you program the analog computer by translating  

11:03

each part of the equation into a physical part of  the computer setup. And then you get your answer,  

11:07

which doesn’t even necessarily  require a monitor to display!

11:10

All of that might be tough to envision, so  here’s another analog analogy that hopefully  

11:17

is less convoluted than the labyrinth of wires  that make up a patch panel. Imagine a playground.  

11:22

Let’s say two kids want to race to the same  spot, but each one takes a different path.  

11:27

One decides to skip along the hopscotch court,  and the other rushes to the slide. Who will win?

11:32

These two areas of the playground are  like different paradigms of computing.  

11:36

You count the hopscotch spaces outlined on  the ground and move between them one by one,  

11:41

but you measure the length of a  slide, and reach its end in one  

11:44

smooth move. And between these two  methods of reaching the same goal,  

11:48

one is definitely a much quicker process than  the other…and also takes a lot less energy.

11:53

There are, of course, caveats to analog.  If you asked the children in our playground  

11:56

example to repeat their race exactly the same  way they did the first time, who do you think  

12:01

would be more accurate? Probably the one whose  careful steps were marked with neat squares,  

12:07

and whose outcomes will be the same — landing  right within that final little perimeter of  

12:11

chalk. With discrete data, you can make perfect  copies. It’s much harder to create copies with  

12:16

the more messy nature of continuous data. The  question is: do we even need 100% accurate  

12:21

calculations? Some researchers are proposing  that we don’t, at least not all the time.

12:27

That said, what does this have to do with Amdahl’s  law? Well, we can extend our existing scenario  

12:31

a little further. It takes time to remember  the rules of hopscotch and then follow them  

12:36

accordingly. But you don’t need to remember any  rules to use a slide — other than maybe “wait  

12:40

until there isn’t anybody else on it.” Comment  below with your favorite playground accidents!

12:45

In any case, because digital computers 1.  reference their memories and 2. solve problems  

12:50

algorithmically, there will always be operations  (like remembering hopscotch rules) that must be  

12:55

performed sequentially. As computer science  professor Mike Bailey puts it, “this includes  

13:00

reading data, setting up calculations, control  logic, storing results, etc.” And because you  

13:05

can’t get rid of these sequential operations,  you run into diminishing returns as you add  

13:10

more and more processors in attempts to speed up  your computing. You can’t decrease the size of  

13:15

components forever, and you can’t increase  the number of processors forever, either.

13:19

On the other hand, analog computers  don’t typically have memories they  

13:22

need to take time to access. This allows  them more flexibility to work in parallel,  

13:27

meaning they can easily break  down problems into smaller,  

13:29

more manageable chunks and divide them  between processing units without delays.

13:34

Here’s how Bernd Ulmann explains it In his 2023  textbook, Analog and Hybrid Computer Programming,  

13:39

which contributed a considerable  amount of research to this video:

13:42

“Further, without any memory there  is nothing like a critical section,  

13:45

no need to synchronize things,  no communications overhead,  

13:48

nothing of the many trifles that haunt  traditional parallel digital computers.”

13:52

So, you might be thinking: speedier, more  energy-efficient computing sounds great,  

13:56

but what does it have to do with me? Am I going to  have to learn how to write differential equations?  

14:01

Will I need to knock down a wall in my office  to make room for a retrofuturist analog rig?

14:05

Probably not. Instead, hybrid computers that  marry the best features of both digital and  

14:10

analog are what might someday be in vogue.  There’s already whisperings of Silicon Valley  

14:14

companies secretly chipping away at…analog  chips. Why? To conserve electricity … and  

14:21

cost. The idea is to combine the energy  efficiency of analog with the precision of  

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digital. This is especially important for  continued development of the power-hungry  

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machine learning that makes generative  AI possible. With any hope, that means  

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products that are far less environmentally  and financially costly, to maintain.

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And that’s exactly what Mythic, headquartered in  the U.S., is aiming for. Mythic claims that its  

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Analog Matrix Processor chip can “deliver the  compute resources of a GPU at 1/10th the power  

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consumption.” Basically, as opposed to storing  data in static RAM, which needs an uninterrupted  

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supply of power, the analog chip stores data  in flash memory, which doesn’t need power to  

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keep information intact. Rather than 1s and 0s,  the data is retained in the form of voltages.

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Where could we someday see analog computing  around the house, though? U.S.-based company  

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Aspinity has an answer to that. What it  calls the “world’s first fully analog  

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machine learning chip,” the AML100, can act as  a low-power sensor for a bunch of applications,  

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according to its website. It can detect a wake  word for use in voice-enabled wearables like  

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wireless earbuds or smart watch, listen for  the sound of broken glass or smoke alarms,  

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and monitor heart rates, just to name a few.

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For those devices that always need to be  on, this means energy savings that are  

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nothing to sneeze at (although I guess  you could program an AML 100 to detect  

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sneezes). Aspinity claims that its chip  can enable a reduction in power use of 95%.

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So, the potential of maximizing efficiency  through analog computing is clear,  

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and the world we interact with every day is itself  analog. Why shouldn’t our devices be, too? But to  

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say that analog programming appears intimidating  (and dated) is…somewhat of an understatement.

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It’ll definitely need an image upgrade  to make it approachable and accessible to  

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the public — though there are already models out  there that you can fiddle with yourself at home,  

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if you’re brave enough. German company  Anabrid, which was founded by Ulmann in 2020,  

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currently offers two: the Analog Paradigm  Model-1, and The Analog Thing (or THAT).

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The Model-1 is intended for more experienced  users who are willing to assemble the machine  

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themselves. Each one is produced on  demand based on the parts ordered,  

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so you can tailor the modules to your needs.

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THAT, on the other hand…and by THAT I mean THAT:  The Analog Thing, is sold fully assembled. You  

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could also build your own from scratch — the  components and schematics are open source.

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So what do you actually do  with the thing? Y’know…THAT?  

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I’ll let the official wiki’s FAQ answer that:

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“You can use it to predict in the natural  sciences, to control in engineering,  

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to explain in educational settings, to imitate in  gaming, or you can use it for the pure joy of it.”

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The THAT model, like any analog computer,  solves whatever you can express in a  

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differential equation. As a reminder, that’s  basically any scenario involving change,  

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from simulating air flow to solving  heat equations. You can also make music!

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But as analog computing becomes more  readily available, there’s still a  

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lot of work to be done. For one thing,  It’ll take effort to engineer seamless  

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connectivity between analog and digital  systems, as Ulmann himself points out.

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Until then, what do you think? Should we take  the word of analog evangelists as gospel? Or  

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are we better off waiting for flying cars?  Jump into the comments and let me know. Be  

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sure to check out my follow-up podcast, Still  To Be Determined, where we'll be discussing  

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some of your feedback. Before I go, I’d  like to welcome new Supporter+ patrons  

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Charles Bevitt and Tanner. Thanks so much for  your support. I’ll see you in the next one.

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AnalogComputingEnergyEfficiencyTechHistoryMoore'sLawAmdahl'sLawHybridSystemsMachineLearningSustainabilityInnovation
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