Lex Fridman Podcast - #486 – Michael Levin: Hidden Reality of Alien Intelligence & Biological Life
Episode Date: November 30, 2025Michael Levin is a biologist at Tufts University working on novel ways to understand and control complex pattern formation in biological systems. Thank you for listening ❤ Check out our sponsors: ht...tps://lexfridman.com/sponsors/ep486-sc See below for timestamps, transcript, and to give feedback, submit questions, contact Lex, etc. Transcript: https://lexfridman.com/michael-levin-2-transcript CONTACT LEX: Feedback – give feedback to Lex: https://lexfridman.com/survey AMA – submit questions, videos or call-in: https://lexfridman.com/ama Hiring – join our team: https://lexfridman.com/hiring Other – other ways to get in touch: https://lexfridman.com/contact EPISODE LINKS: Michael Levin’s X: https://x.com/drmichaellevin Michael Levin’s Website: https://drmichaellevin.org Michael Levin’s Papers: https://drmichaellevin.org/publications/ – Biological Robots: https://arxiv.org/abs/2207.00880 – Classical Sorting Algorithms: https://arxiv.org/abs/2401.05375 – Aging as a Morphostasis Defect: https://pubmed.ncbi.nlm.nih.gov/38636560/ – TAME: https://arxiv.org/abs/2201.10346 – Synthetic Living Machines: https://www.science.org/doi/10.1126/scirobotics.abf1571 SPONSORS: To support this podcast, check out our sponsors & get discounts: Shopify: Sell stuff online. Go to https://shopify.com/lex CodeRabbit: AI-powered code reviews. Go to https://coderabbit.ai/lex LMNT: Zero-sugar electrolyte drink mix. Go to https://drinkLMNT.com/lex UPLIFT Desk: Standing desks and office ergonomics. Go to https://upliftdesk.com/lex Miro: Online collaborative whiteboard platform. Go to https://miro.com/ MasterClass: Online classes from world-class experts. Go to https://masterclass.com/lexpod OUTLINE: (00:00) – Introduction (00:29) – Sponsors, Comments, and Reflections (10:09) – Biological intelligence (18:42) – Living vs non-living organisms (23:55) – Origin of life (27:40) – The search for alien life (on Earth) (1:00:44) – Creating life in the lab – Xenobots and Anthrobots (1:13:46) – Memories and ideas are living organisms (1:27:26) – Reality is an illusion: The brain is an interface to a hidden reality (2:13:13) – Unexpected Intelligence in sorting algorithms (2:38:51) – Can aging be reversed? (2:42:41) – Mind uploading (3:01:22) – Alien intelligence (3:16:17) – Advice for young people (3:22:46) – Questions for AGI
Transcript
Discussion (0)
The following is a conversation with Michael Levin, his second time on the podcast.
He is one of the most fascinating and brilliant biologists and scientists I've ever had the
pleasure of speaking with. He and his labs at Tufts University study and build biological systems
that help us understand the nature of intelligence, agency, memory, consciousness, and life
in all of its forms here on Earth and beyond.
And now a quick few second mention of each sponsor.
Check them out in the description or at Lexfredman.com slash sponsors.
It is, in fact, the best way to support this podcast.
We got Shopify for selling stuff online,
Code Rabbit for AI-powered code review,
element for electrolytes, uplift desk for my favorite office desks
that I'm sitting behind right now,
Miro for brainstorming ideas with your team and master class
for learning stuff from incredible people.
Choose wise and my friends.
And now, on to the full ad reads.
I try to make them interesting,
but if you must skip,
please still check out the sponsors.
I enjoy their stuff.
Maybe you will too.
To get in touch with me,
for whatever reason,
go to Lexfremant.com slash contact.
All right, let's go.
This episode is brought to you by Shopify,
a platform designed for anyone
to sell anywhere the great-looking online store with an engineering stack that utilizes the beauty
and the elegance of ruby on rails that DHS so beautifully articulated in my conversations with him.
I continue to tune in to DHS's tweets and posts on X.
Just a beautiful human being.
And it's just nice to know that he's a big supporter of Shopify.
him and Toby have been closed for years.
And it's just nice to know that great human beings
and great engineers can create great products
that also make a lot of money
and also bring a lot of usefulness to the world.
So I will forever be celebrating Shopify,
not just for the services that they create,
but for the people behind the scenes that are building it.
So sign up for a $1 per month trial period
shopify.com slash lex that's all lowercase go to shopify.com slash lex to take your business to the next
level today speaking of beautiful code and incredible people this episode is also brought to you by
code rabbit a platform that provides a i powered code reviews directly within your terminal
the thing i can definitively recommend especially is the cly version of code rabbit it's the most
installed AI app on GitHub and GitLab, 2 million repositories in review, 13 million
pull requests reviewed. Basically, a lot of you listening to this know how to generate a bunch
of code. Some of it is AI slop. Some of it is on the borderline. But what Code Ravis CLI does is, as they
put it, vibe check your code. So they do the review process to make sure you go from that AI
I generate code to something that's actually production ready by helping you catch errors.
And it supports all programming languages.
You absolutely must go now install CodeRabbit CLI at Codrabbit.a.i slash Lex.
That's code rabbit.com.A.I. slash Lex.
Please go support them.
Try it out. You will not regret it if you're at all a programmer or exploring programming.
friends don't let friends uh vibe code without vibe checking the code all right anyway this episode is also
brought you by element my daily zero sugar and delicious electrolyte mix that in all of my crazy
travel i always bring with me that's going to be tested when i go into the middle of nowhere for
multiple weeks at a time with just a backpack we'll see we'll see we'll see but it's so easy to bring
with you. It's light. It doesn't take much space. You just put it in some water. First of all,
it makes the water taste really good. Second of all, it just balances the nutritional value of the
water. So you don't want to overdrink water without any electrolytes. It just makes me feel so good to
get the right balance of sodium, potassium, and magnesium when I am doing fasting for one day or two
day at a time, or I'm doing crazy long distance runs. One of the things I learned actually is
you need to listen to your body. You need to understand your body. You need to understand what it
needs, what makes you feel good, mentally, physically. And sometimes outside advice is good to
incorporate, but really what you need to develop is the ability to sense deeply the state of
your body, what makes it feel good, what makes it feel bad, have a really nice internal
feedback controller that's able to establish a happy, stress-free existence.
Anyway, get a free eight-count sample pack with any purchase.
Try it to drink element.com slash Lex.
This episode is also brought to you by Uplift Desk, my go-to for all office and podcast studio
furniture.
I don't know if I want to say that all other desks suck, because that wouldn't be very nice,
but I really want to say that because I've tried other desks,
and uplift desks is what made me truly happy.
I now have six uplift desks for the podcast for my Windows machine for the video editing.
I have a bunch of Linux boxes.
I have the robotics desk with doing soldering, all this kind of stuff.
Anyway, all of these uplift desks, all that makes me happy.
You can customize the crap out of whatever you want.
It's over 200,000 possible desk combinations.
I'm pretty sure all of them are super sexy, super nice in both sitting and standing positions.
plus the people that come to install are just like really kind human beings.
I just had wonderful experiences all throughout this everything.
Everything involved with Uploved Desk has been really great.
So please go support them.
They're great.
And the fact that they are supporting this podcast is like, what?
I've been a fan of this for many years before they were supporting this podcast.
The fact they're doing that now is just please go buy all their stuff so they keep supporting
this podcast.
Anyway, go to UpliftDest.com slash Lex and use
code Lex to get four free accessories, free same-day shipping, free returns, a 15-year warranty,
and an extra discount off your entire order. That's U-P-L-I-F-D-E-S-K dot com slash Lex.
This episode is also brought to you by Miro, an online collaborative platform.
Miro's innovation workspace blends AI and human creativity to turn ideas into results.
Miro's innovation workspace blends AI and human creativity to turn ideas into results.
That's, by the way, friends, what I've been working on.
Human-Robot Interaction, HRI.
I'm actually interested in the general problem of heterogeneous systems
where you have both humans and AIs, and they have to work together,
they have to understand each other, and all of it fundamentally for the goal of the humans to flourish.
I'm forever humanity first.
So AI should be tools that make human lives better.
And of course, there's much longer and fascinating discussion about that topic on safety,
on security, and in general on human flourishing in this 21st century.
But that's friends for another time.
In fact, we can brainstorm about it using mirror, which converts sticky notes, screenshots,
all that kind of stuff into actual diagrams or prototypes and minutes.
It's perfect for processes.
ideation, or product launches.
Help your teams develop great ideas into results with Mero.
Go to Miro.com to find out how that's MIRO.com.
This episode is also brought to you by Masterclass,
where you can watch over 200 classes from the best people in the world
in their respective disciplines.
There's actually a few really nice classes from super famous people
that have been added that for me personally have been interesting to watch.
So Kevin Hart did one.
He's definitely a good example of somebody that you just can't look away.
There's something really charismatic and funny about their whole way of being.
Another guy like that is Will Ferrell.
In fact, they can both, I guess you could say, hold the stage presence.
There's a new one from Stephen Curry and Lewis Hamilton.
Both folks I should probably almost definitely talk to.
Serena Williams, Gordon Ramsey, John Legend,
the great Samuel Jackson, and the great Natalie Portman.
The list just keeps going.
Every topic you can think of, there's really nothing else like this on Earth.
I highly, highly recommend it.
It is one of the best ways to get to the essence of the thing
by learning from the people who have gotten to the very top of the world at that thing.
Get unlimited access to every matter.
Masterclass and get an additional 15% off and annual membership at Masterclass.com slash LexPod.
That's masterclass.com slash LexPod.
This is Alex Friedman podcast. To support it, please check out our sponsors in the description
where you can also find links to contact me, ask questions, get feedback, and so on.
And now, dear friends, here's Michael Levin.
You write that the central question at the heart of your work from biological systems to computational ones is how do embodied minds arise in the physical world and what determines the capabilities and properties of those minds?
Can you unpack that question for us?
maybe begin to answer it? Well, the fundamental tension is in both the first person, the second
person, and third person descriptions of mind. So in third person, we want to understand how do we
recognize them and how do we know looking out into the world what degree of agency there is and how
best to relate to the different systems that we find? And are our intuition is any good when we look
at something and it looks really stupid and mechanical versus it really looks like there's something
cognitive going on there. How do we get good at recognizing them? Then there's the second person,
which is the control, and that's both for engineering but also for regenerative medicine when you
want to tell the system to do something, right? What kind of tools are you going to use? And this is a
major part of my framework is that all of these kinds of things are operational claims that you're
going to use the tools of hardware rewiring, of control theory and cybernetics, of behavior
science, of psychoanalysis and love and friendship, like what are the interaction protocols that you
bring, right? And then in first person, it's this notion of having an inner perspective and being a
system that has valence and cares about the outcome of things, makes decisions and has memories
and tells a story about itself and the outside world. And how can all of that exist and still
be consistent with the laws of physics and chemistry and various other things that that we see
around us? So that I find to be maybe the most interesting and the most important mystery for all
of us to, well, on the science and also on the personal level. So that's what I'm interested.
So your work is focus on starting at the physics, going all the way to friendship and love and psychoanalysis.
Yeah, although actually I would turn that upside down.
I think that pyramid is backwards.
And I think it's behavior science at the bottom.
I think it's behavior science all the way.
I think in certain ways, even math is the behavior of a certain kind of being that lives in a latent space.
And physics is what we call systems that at least look to be amenable to a very simple, low agency kind of model.
on. But that's what I'm interested in is understanding that and developing applications because
it's very important to me that what we do is transition deep ideas and philosophy into
actual practical applications that not only make it clear whether we're making any progress
or not, but also allow us to relieve suffering and make life better for all sentient beings
and enable to, you know, enable us and others to reach their full potential. So these are,
These are very practical things, I think.
Behavioral science is supposed is more subjective, and mathematics and physics is more objective.
Would that be the clear difference?
The idea, basically, is that where something is on that spectrum, and I've called it the spectrum of persuadability,
and you could call it the spectrum of intelligence or agency or something like that.
I like the notion of the spectrum of persuadability because it's an engineering approach.
It means that these are not things you can decide or have feelings about from a philosophical,
armchair, you have to make a hypothesis about which tools, which interaction protocols you're
going to bring to a given system. And then we all get to find out how that worked out for you,
right? So you could be wrong in many ways. In both directions, you can guess too high or too low or
wrong in various ways. And then we can all find out how that's working out. And so I do think that
the behavior of certain objects is well described by specific formal rules. And we call those
things the subject of mathematics. And then there are some other things whose behavior really
requires the kinds of tools that we use in behavioral, cognitive neuroscience, and those
are other kinds of minds that we think we study in biology or in psychology or other sciences.
Why are you using the term persuadability? Who are you persuading and of what?
Well, in this context.
Yeah. The beginning of my work is very much in regenerative medicine, in bioengineering,
things like that. So for those kinds of systems, the question is always,
How do you get the system to do what you want it to do?
So there are cells, there are molecular networks, there are materials, there are organs and
tissues and synthetic beings and biobots and whatever.
And so the idea is if I want your cells to regrow a limb, for example, if you're injured
and I want your cells to regrow a limb, I have many options.
Some of those options are I'm going to micromanage all of the molecular events that have
to happen, right?
And there's an incredible number of those.
Or maybe I just have to micromanage the cells and the stem cell, the kinds of
signaling factors, or maybe actually I can give the cells a very high level prompt that says
you really should build the limb and convince them to do it, right? And so where, what, which of those is
possible? I mean, clearly people have a lot of intuitions about that. If you ask standard people
in regenerative medicine and molecular biology, they're going to say, well, that convincing thing is
crazy. What we really should be doing is talking to the cells or better yet the molecular networks.
And, in fact, all the excitement of the biological sciences today are at, you know, single molecule
approaches and big data and genomics and all of that. The assumption is that going down is
where the action is going to be, going down and scale. And I think that's wrong. But the thing that
we can say for sure is that you can't guess that. You have to do experiments and you have to see
because you don't know where any given system is on that spectrum of persuadability. And it turns out that
Every time we look and we take tools from behavioral science, so learning, different kinds of
training, different kinds of models that are used in active inference and surprise minimization
and perceptual multi-stability and visual illusions and all these kinds of interesting things,
you know, stress perception and memory, active memory reconstruction, all these interesting things.
When we apply them outside the brain to other kinds of living systems, we find novel discoveries
and novel capabilities actually being able to get the material to do new things that nobody
had ever found before. And precisely because I think that people didn't look at it from those
perspectives, they assume that it was a low level kind of thing. So when I say persuadability,
I mean different types of approaches, right? And we all know if you want to, if you want to
persuade your wind-up clock to do something, you're not going to argue with it or make it feel
guilty or anything. You're going to have to get in there with a wrench and you're going to
have to, you know, tune it up and do whatever. If you want to do that same thing, you're
to a cell or a thermostat or an animal or a human, you're going to be using other sets of tools
that we've given other names to. And so that's, now, of course, that spectrum, the important thing is
that as you get to the right of that spectrum, as the agency of the system goes up, it is no longer
just about persuading it to do things. It's a bidirectional relationship, what Richard Watson
would call a mutual vulnerable knowing. So the idea is that on the right side of that spectrum,
when systems reach the higher levels of agency, the idea is that you're willing to let that system
persuade you of things as well.
You know, in molecular biology, you do things.
Hopefully the system does what you want to do, but you haven't changed.
You're still exactly the way you came in.
But on the right side of that spectrum, if you're having interactions with even cells,
but certainly, you know, dogs, other other animals, maybe other other creatures soon,
you're not the same at the end of that interaction as you were going in.
It's a mutual bidirectional relationship.
So it's not just you persuading something else.
It's not you pushing things.
It's a mutual bidirectional set of persuasions.
whether those are purely intellectual or of other kinds.
So in order to be effective at persuading an intelligent being,
you yourself have to be persuadable.
So the closer in intelligence you are to the thing you're trying to persuade,
the more persuadable you have to become.
Hence the mutual, vulnerable knowing.
What a term.
Yeah, yeah, Richard, yeah, you should talk to Richard as well.
He's an amazing guy, and he's got some very interesting ideas
about the intersection of cognition and evolution.
But, you know, I think what you bring up is very important because there has to be a kind of impedance match between what you're looking for and the tools that you're using.
I think the reason physics always sees mechanism and not minds is that physics uses low agency tools.
You've got volt meters and rulers and things like this.
And if you use those tools as your interface, all you're ever going to see is mechanisms and those kinds of things.
If you want to see minds, you have to use a mind, right?
you have to have, there has to be some degree of resonance between your interface and the thing
you're hoping to find. You've said this about physics before. Can you just linger on that,
like expand on it, what you mean, why physics is not enough to understand life, to understand mind,
to understand intelligence? You make a lot of controversial statements with your work. That's one of
them, because there's a lot of physicists that believe they can understand life, the emergence of life,
the origin of intelligence using the tools of physics. In fact, all the other tools are the
distraction to those folks. If you want to understand fundamentally anything, you have to start
a physics to them. And you're saying, no, physics is not enough. Here's the issue. Everything here
hangs on what it means to understand. For me, because understand doesn't just mean have some
sort of pleasing model that seems to capture some important aspect of what's going on. It also
means that you have to be generative and creative in terms of capabilities. And so for me, that
means if I tell you this is what I think about cognition and cells and tissues, it means, for example, that I think we're going to be able to take those ideas and use them to produce new regenerative medicine that actually helps people in various ways, right? It's just an example. So if you think as a physicist you're going to have a complete understanding of what's going on from that perspective of fields and particles and then, you know, who knows what else is at the bottom there, does that mean then that when somebody is missing a finger or has a
psychological problem or, you know, has these other high-level issues that you have something
for them, that you're going to be able to do something because my claim is that you're not
going to. And even if you have some theory of physics that is completely compatible with
everything that's going on, it's not enough. That's not specific enough to enable you to solve
the problems you need to solve. In the end, when you need to solve those problems, the person
you're going to go to is not a physicist. It's going to be either a biologist or a psychiatrist
or who knows, but it's not going to be a physicist.
And the simple example is this, you know, let's say, let's say someone comes in here
and tells you a beautiful mathematical proof, okay, it's just really, you know, deep and beautiful.
And there's a physicist nearby, and he says, well, I know exactly what happened.
There were some air particles that moved from that guy's mouth to your ear.
I see what goes on.
It moved the cilia in your ear, and the electrical signals went up to your brain.
I mean, we have a complete accounting of what happened, done and done.
but if you want to understand
what's the more important aspect of that interaction
it's not going to be found in the physics department
it's going to be found in the math department
so that's my only claim is that is that physics is an amazing
lens with which to view the world
which are capturing certain things
and if you want to stretch to
sort of encompass these other things
it's just we just don't call that physics anymore
right that's we call that something else
okay but you're kind of speaking about
the super complex organisms
can we go to the simplest possible thing
where you first take a step over the line,
the Cartesian cut, as you've called it,
from the non-mind to mind, from the non-living to live.
The simplest possible thing,
isn't that in the realm of physics to understand?
How do we understand that first step
where you're like, that thing is no mind,
probably non-living,
and here's a living thing that has a mind, that line?
I think that's a really interesting line.
Maybe you can speak to the line as well, and can physics help us understand it?
Yeah, let's talk about it.
Well, first of all, of course it can help, meaning that I'm not saying physics is not helpful.
Of course it's helpful.
It's a very important lens on one slice of what's going on in any of these systems.
But I think the most important thing I can say about that question is I don't believe in any such line.
I don't believe any of that exists.
I think there is a, I think it's a continuum.
I think we as humans like to demarcate areas on that continuum and give them name.
because it makes life easier.
And then we have a lot of battles over, you know, so-called category errors when people
transgress those categories.
I think most of those categories at this point, they may have done some good service at
the beginning of when the scientific method was getting started and so on.
I think at this point, they mostly hold back science.
Many, many categories that we can talk about are at this point very harmful to progress.
Because what those categories do is they prevent you from porting tools.
If you think that living things are fundamentally different from non-living things, or if you think that cognitive things are these like advanced brainy things that are very different from other kinds of systems, what you're not going to do is take the tools that are appropriate to these kind of cognitive systems, right?
So the tools that have been developed in behavioral science and so on, you're never going to try them in other contexts because you've already decided that there's a categorical difference, that it would be a categorical error to apply them.
people say this to me all the time is that you're making a category error and as if these
categories were given to us, you know, from from on high and we have to, we have to obey them
forevermore. The category should change with the science. So yeah, I don't believe in any
such line. And I think, I think a physics story is very often a useful part of the story,
but for most interesting things, it's not the entire story. Okay. So if there's no line,
is it still useful to talk about things like the origin of life?
That's one of the big open mysteries before us as a human civilization,
as scientifically minded, curious, homo sapiens.
How did this whole thing start?
Are you saying there is no start?
Is there a point where you could say that invention right there
was the start of it all on Earth?
My suggestion is that much better than trying to,
in my experience, much better than trying to define any kind of a line, okay?
Because inevitably, I've never, I've never found, and people try to, you know, we play this
game all the time when I make my continuum claim, then people try to come, okay, well, what about
this, you know, what about this?
And I haven't found one yet that really shoots that down, that you can't zoom in and say,
yeah, okay, but right before then this happened.
And then if we really look close, like here's a bunch of steps in between, right?
Pretty much everything ends up being a continuum.
But here's what I think is much more interesting than trying to make that line.
I think what's really more useful is trying to understand the transformation process.
What is it that happened to scale up?
And I'll give you a really dumb example.
And we always get into this because people often really, really don't like this continuum view.
The word adult, right?
Everybody is going to say, look, I know what a baby is.
I know what an adult is.
You're crazy to say that there's no difference.
I'm not saying there's no difference.
What I'm saying is the word adult is really helpful in court because you just need to move things along.
And so we've decided that if you're 18, you're an adult.
However, what it hides is, what it completely conceals is the fact that, first of all,
nothing happens on your 18th birthday, right?
That's special.
Second, if you actually look at the data, the car rental companies actually have a much better estimate
because they actually look at the accident statistics and they'll say it's about 25 is really
what you're looking for, right?
So theirs is a little better.
It's less arbitrary.
But in either case, what it's hiding is the fact that we do not have a good story.
of what happened from the time that you were an egg to the time that you're the supposed
adult, and what is the scaling of personal responsibility, decision-making, judgment?
Like, these are deep fundamental questions.
Nobody wants to get into that every time somebody has a traffic ticket.
And so, okay, so we've just decided that there's this adult idea.
And, of course, it does come up in court because then somebody has a brain tumor or somebody's
eaten too many twinkies or something has happened.
And you say, look, that wasn't me.
whoever did that I was on drugs well why did you take the drugs well that was you know that was
yesterday me today this is something right so so we get into these very deep questions that are
completely glossed over by this idea of an adult so so I think once you start scratching the
surface most of these categories are like that they're convenient and they're good it's you know I get
into this with neurons all the time I'll ask people what's what's a neuron like what's really a neuron
and yes if you're if you're in neurobiology 101 of course you just say like these are what
neurons look like, let's just study the neuroanatomy and we're done. But if you really want to
understand what's going on, well, neurons develop from other types of cells, and that was a
slow and gradual process, and most of the cells in your body do the things that neurons do. So what really
is a neuron, right? So once you start scratching this, this happens. And I have some things that I think
are coming out of our lab and others that are, I think, very interesting about the origin of life,
but I don't think it's about finding that one boom, like this is, yeah, there'll be, there are
innovations, right? There are, there are innovations that, that allow you to scale in an amazing
way, for sure. And there are lots of people that study those, right? So, so things that thermodynamic
kind of metabolic things and, and all kinds of architectures and so on. But I don't think
it's about finding a line. I think it's about finding a scaling process. The scaling process,
but then there is more rapid scaling and there's slower scaling. So innovation, invention,
I think is useful to understand
so you can predict how likely it is
on other planets, for example,
or to be able to describe
the likelihood of these kinds of phenomena
happening in certain kinds of environments,
again, specifically in answering
how many alien civilizations there are.
That's why it's useful,
but it's also useful on a scientific level
to have categories,
not just because it makes us feel good
and fuzzy inside,
but because it makes conversation possible and productive, I think.
If everything is a spectrum, it becomes difficult to make concrete statements, I think.
But we even use the terms of biology and physics.
Those are categories.
Technically, it's all the same thing, really.
Fundamentally, it's all the same.
There's no difference in biology and physics, but it's a useful category.
If you go to the physics department and the biology department, those people are different.
in some kind of categorical way.
So somehow, I don't know what the chicken or the egg is, but the categories,
maybe the categories create themselves because of the way we think about them and use them
in language, but it does seem useful.
Let me make the opposite argument.
They're absolutely useful.
They're useful specifically when you want to gloss over certain things.
The categories are exactly useful when there's a whole bunch of stuff.
And this is what's important about science is like the art of being able to say something
without first having to say everything, right?
We should make it impossible.
So categories are great when you want to say, look, I know there's a bunch of stuff hidden here.
I'm going to ignore all that.
And we're just going to like, let's get on with this particular thing.
And all of that is great as long as you don't lose track of the stuff that you glossed over.
And that was what I'm afraid is happening in a lot of different ways.
And in terms of, look, I'm very interested in life beyond Earth and all of these kinds of things.
Although we should also talk about what I call SUTI, the search for unconvinful.
terrestrial intelligences. I think we got much bigger issues than actually recognizing aliens off Earth. But I'll make this claim. I think the categorical stuff is actually hurting that search. Because if we try to define categories with the kinds of criteria that we've gotten used to, we are going to be very poorly set up to recognize life in novel embodiments. I think we have a kind of mind blindness. I think this is really key. To me, to me, the cognitive spectrum is much more interesting.
than the spectrum of life. I think really what we're talking about is a spectrum of cognition.
And it's weird as a biologist to say, I don't think life is all that interesting a category.
I think the categories of different types of minds, I think is extremely interesting. And to the extent that
we think our categories are complete and are cutting nature at its joints, we are going to be
very poorly placed to recognize novel systems. So, for example, a lot of people will say, well,
this is intelligent and this isn't, right? And there's a binary.
thing and that's useful in occasionally that's useful for some things i would like to say instead of
that let's make us let's let's let's let's admit that we have a spectrum but instead of just saying
oh look everything's intelligent right because if you do that you're right you can't you can't do
anything after that what i'd like to say instead is no no you have to be very specific as to what
kind and how much in other words what problem space is it operating in what kind of mind does it
have what kind of cognitive capacities does it have you have to actually be much more specific and
And we can even name, right? That's fine. We can name different types of, I mean, this is doing predictive processing. This can't do that, but it can form memories. What kind? Well, habituation and sensitization, but not associative conditioning. Like, it's fine to have categories for specific capabilities. But it's, it actually, I think it actually makes for much more rigorous discussions because it makes you say, what is it that you're claiming this thing does? And it works in both directions. So, and so some people will say, well, that's a cell. That can't be intelligent. And I'll say, well, let's be very specific.
here are some claims about here is some problem solving that it's doing to tell me why that doesn't
you know why doesn't that match or in the opposite direction somebody comes to me he says you're right
you're right you know the whole the whole solar system and it's just like this amazing like okay
what is it doing like tell me tell me what tools of cognitive and behavioral science are you using
to reach that conclusion right and so i think i think it's actually much more productive to take
this operational stance and say tell me what protocols you think you can deploy with this thing
that would lead you to use these terms.
To have a bit of a meta conversation about the conversation,
I should say that part of the persuadability argument
that we two intelligent creatures are doing
is me playing devil's advocate every once in a while,
and you did the same,
which is kind of interesting,
taking the opposite view and see what comes out.
Because you don't know the result of the argument
until you have the argument,
and it seems productive to just take the other side of the argument.
For sure.
It's a very important,
thinking aid to, first of all, you know, what they call steel manning, right, to try to make
the strongest possible case for the other side and to ask yourself, okay, what are all the,
what are all the places that I'm sort of glossing over because I don't know exactly what to say
and where all the holes in the argument and what would, what would, you know, a really good
critique really look like. Yeah. Sorry to go back there, just to linger on the term, because it's
so interesting, persuadability. Did I understand correctly that you mean that it's kind of
synonymous with intelligence. So it's an engineering-centric view of an intelligence system,
because if it's persuadable, you're more focused on how can I steer the goals of the system,
the behaviors of the system, which meaning an intelligence system maybe is a goal-oriented,
goal-driven system with agency. And when you call it persuadable, you're thinking more
are like, okay, here's an intelligence system that I'm interacting with, that I would like
to get it to accomplish certain things.
But fundamentally, they're synonymous or correlated, persuadability and intelligence.
They're definitely correlated.
So let me, I want to preface this with one thing.
When I say it's an engineering perspective, I don't mean that the standard tools that we use
in engineering and this idea of enforced control and steering is how we should view.
all of the world. I'm not saying that at all. And I want to be very clear because people do email
me and say, ah, this engineering thing, you're going to drain the, you know, the life and the majesty
out of these high-end, like, human conversation. My whole point is not that at all. It's that,
of course, at the right side of the spectrum, it doesn't look like engineering anymore, right? It looks
like, it looks like friendship and love and psychoanalysis and all these other tools that we have.
But here's what I want to do. I want to be very specific to my colleagues in regenerative medicine.
And just imagine if I, you know, if I went to a bioengineering department or a genetics department and I started talking about high level, you know, cognition and psychoanalysis, right?
They didn't want to hear that.
So, so I bring my, I focus on the engineering approach because I want to say, look, this is not a philosophical problem.
This is not a linguistics problem.
We are not trying to define terms in different ways to make anybody feel fuzzy.
What I'm telling you is if you want to reach certain capabilities, if you want to reprogram cancer, if you want to re-program cancer, if you want to re-reform cancer, if you want to re-
grow new organs, you want to defeat aging, you want to do these specific things, you are leaving
too much on the table by making an unwarranted assumption that the low-level tools that we have,
so these are the rules of chemistry and the kind of remolecular rewiring, that those are going to be
sufficient to get to where you want to go. It's an assumption only, and it's an unwarranted
assumption. And actually, we've done experiments now, so not philosophy, but real experiments,
that if you take these other tools, you can in fact persuade the system in ways that has never
have been done before. And we can unpack all of that. But it is, it is absolutely correlated with
intelligence. So let me flesh that out a little bit. What I think is scaling in all of these things,
right, because I keep talking about the scaling. So what is it that scaling? What I think is
scaling is something I call the cognitive light cone. And the cognitive light cone is the size of the
biggest goal state that you can pursue. This doesn't mean how far do your senses reach. This doesn't
mean how far can you affect it. So the James Webb Telescope has enormous sensory reach,
but that doesn't mean that's the size of its cognitive Lycone. The size of the cognitive Lycone
is the scale of the biggest goal you can actively pursue. But I do think it's a useful concept
to enable us to think about very different types of agents of different composition, different
provenance, you know, engineered, evolved, hybrid, whatever, all in the same framework. And by the way,
the reason I use Lycone is that it has this idea from physics that you're putting space and time
kind of in the same diagram, which is, which I like here.
So if you tell me that all your goals revolve around maximizing the amount of sugar, the amount
of sugar in this, in this, you know, 10, 20 micron radius of space time, and that you have,
you know, 20 minutes memory going back and maybe five minutes predictive capacity going forward,
that tiny little cognitive lichen, I'm going to see probably a bacterium.
And if you say to me that, well, I, I'm able to care about several hundred yards,
sort of scale, I could never care about what happens three weeks from now, two towns over.
Just impossible. I'm saying, you might be a dog. And if, and if you say to me, okay, I care about
really what happens, you know, the financial markets on Earth, you know, long after I'm dead and
this and that, say you're probably a human. And if you say to me, I care in the linear range,
I actively, I'm not just saying that I can actively care in the linear range about all the
living beings on this planet. I'm going to say, well, you're not a standard human.
You must be something else because humans, I don't know these standard humans today, I don't think can do that.
You must be some kind of a body sat for some other thing that has these massive cognitive lichones.
So I think what's scaling from zero, and I do think it goes all the way down, I think we can talk about even particles doing something like this.
I think what scales is the size of the cognitive lichon.
And so now this is an interesting, here, I'll try for a definition of life or whatever, for whatever it's worth.
I spend no time trying to make that stick, but if we wanted to.
I think we call things alive to the extent that the cognitive light cone of that thing is bigger than that of its parts.
So in other words, rocks aren't very exciting because the things it knows how to do are the things that its parts already know how to do,
which is follow gradients and things like that.
But living things are amazing at aligning their competent parts so that the collective has a larger cognitive light cone than the parts.
I'll give you a very simple example that comes up in biology and that comes up in our cancer program all the time.
Individual cells have little tiny cognitive lichones.
What are their goals?
Well, they're trying to manage pH, metabolic state, some other things.
There are some goals in transcriptional space, some goals in metabolic space, some goals, and physiological state space.
But they're generally very tiny goals.
One thing evolution did was to provide a kind of cognitive glue, which we can also talk about.
that ties them together into a multicellular system.
And those systems have grandiose goals.
They're making limbs.
And if you're a salamander limb and you chop it off, they will regrow that limb with the right number of fingers.
Then they'll stop when it's done.
The goal has been achieved.
No individual cell knows what a finger is or how many fingers you're supposed to have.
But the collective absolutely does.
And that process of growing that cognitive lichone from a single cell to something much bigger.
And, of course, the failure mode of that process.
So cancer, right?
when cells disconnect, they physiologically disconnect from the other cells, their cognitive
lichone shrinks.
The boundary between self and world, which is what the cognitive lichone defines, shrinks.
Now they're back to an amoeba.
As far as they're concerned, the rest of the body is just an external environment.
And they do what amoebas do.
They go where life is good.
They reproduce as much as they can.
So that cognitive lichone, that is the thing that I'm talking about, that scales.
And so when we're looking for life, I don't think we're looking for specific materials.
I don't think we're looking for specific metabolic states.
I think we're looking for scales of cognitive lycone.
We're looking for alignment of parts towards bigger goals in spaces
that the parts could not comprehend.
And so cognitive lycone just to make clear
it's about goals that you can actively pursue now,
is it linear, like we'll then reach immediately.
No, I didn't, sorry, I didn't mean that.
First of all, the goal necessarily is often removed in time.
So in other words, when you're pursuing a goal, it means that you have a separation between current state and target state at minimum, your thermostat, right?
Let's just think about that.
There's a separation in time because the thing you're trying to make happen so that the temperature goes to a certain level is not true right now.
And all your actions are going to be around reducing that error, right?
That basic homeostatic loop is all about closing that gap.
When I said linear range, this is what I meant.
If I say to you, this terrible thing happened to, you know, 10 people.
And, you know, you have some degree of activation about it.
And then they say, no, no, no, actually it was 100, you know, 10,000 people.
You're not a thousand times more activated about it.
You're somewhat more activated, but it's not a thousand.
And if I say, oh, my God, it was actually 10 million people.
You're not a million times more activated.
You don't have that capacity in the linear range.
You sort of, right, if you think about that curve, we sort of, we reach a saturation point.
I have some amazing colleagues in the Buddhist community with whom we've written some papers about this, the radius of compassion.
is like, can you grow your cognitive system to the point that, yeah, it really isn't just
your family group. It really isn't just a hundred people you know in your, in your, you know,
circle. Can you grow your cognitive light cone to the point where, no, no, we care about the
whole, whether it's all of humanity or the whole ecosystem or the whole whatever, can you actually
care about that the exact same way that we now care about a much smaller set of people? That's
what I mean by linear range. But you said separated by time, like a thermostat, but a bacteria
I mean, if you zoom out far enough,
a bacteria could be formulated to have a goal state
of creating human civilization.
Because if you look at the, you know, bacteria
has a role to play in the whole history of Earth.
And so if you anthropomorphize the goals of bacteria enough,
I mean, it has a concrete role to play
in the history of the evolution of human
civilization. So you do need to, when you define a cognitive light cone, you're looking at
directly short-term behavior. Well, no, how do you know what the cognitive light cone of something
is? Because as you've said, it could be almost anything. The key is you have to do experiments.
And the way you do experiments is you put barrier, you have to do interventional experiments.
You have to put barriers between it and its goal. And you have to ask what happens.
and intelligence is the degree of ingenuity that it has in overcoming barriers between it and its goal.
Now, if it were to be that, now, this is, I think, a totally doable but impractical and very expensive experiment,
but you could imagine setting up a scenario where the bacteria were blocked from becoming more complex,
and you can ask if they were trying to find ways around it, or whether it's actually,
nah, their goals are actually metabolic, and as long as those goals are met,
they're not going to actually get around your barrier.
this business of putting barriers between things and their goals is actually extremely powerful
because we've deployed it in all kinds of, and I'm sure, I'm sure we'll get to this later,
but we've deployed it in all kinds of weird systems that you wouldn't think are goal-driven
systems. And what it allows us to do is to get beyond just the, what you call it anthropomorphizing
claims of saying, oh yeah, I think, you know, I think this thing is trying to do this or that.
The question is, well, let's do the experiment. And one other thing I want to say,
anthropomorphizing, people say this to me all the time. I don't think that exists. I think that's
kind of like, you know, and I'll tell you why. I think it's like heresy or like other other terms
that aren't really a thing. Because if you unpack it, here's what anthropomorphism means.
Humans have a certain magic and you're making a category error by attributing that magic somewhere else.
My point is we have the same magic that everything has. We have a
of interesting things besides the cognitive icon and some other stuff. And it isn't that you have to
keep the humans separate because there's some bright line. It's just, it's, it's that same old,
all I'm, all I'm arguing for is the scientific method, really. That's really all this is. All I'm
saying is you can't just make pronouncements such as the humans are this and let's not sort of
push that. You have to do experiments. After you've done your experiments, you can say either I've
done it and I found, look at that, that thing actually can predict the future for the next,
you know, 12 minutes, amazing. Or you say, you know what, I've tried all the things in the
behaviorist handbook. They just don't help me with this. It's a very low level of, like,
that's it. It's a very low level of intelligence. Fine. Right. Done. So that's really all I'm
arguing for is an empirical approach. And then things like anthropomorphism go away. It's just
the matter of, have you done the experiment? And what did you find? And that's actually one of the
things you're saying that if you remove the categorization of things, you can use the tool.
of one discipline on everything.
You can try.
To try and then see that's the underpaintings
of the criticism of anthropomorphization
because what is that?
That's like psychoanalysis of another human
could technically be applied to robots,
to AI systems,
to more primitive biological systems and so on.
Try.
Yeah.
We've used everything from basic habituation conditioning
all the way through anxiolytics, hallucinogens,
all kinds of cognitive modification on the range of things that you wouldn't believe.
And by the way, I'm not the first person to come up with this.
So there was a guy named Bose well over 100 years ago
who was studying how anesthesia affected animals and animal cells
and drawing specific curves around electrical excitability.
And he then went and did it with plants and saw some very similar phenomena.
And being the genius that he was, he then said,
well, I don't know when to stop, but there's no, there's no, you know, everybody thinks we should
have stopped long before plants because people made fun of them for that. And he's like, yeah,
but the science doesn't tell us where to stop. The tool is working. Let's keep going. And he showed
interesting phenomena on materials, metals and, and other kinds of materials, right? And so,
yeah, the interesting thing is that, yeah, there is no, there is no, you know, generic rule that
tells you when, when do you need to stop. We make those up. Those are completely made up.
You have to just, you have to do the science and find out.
Yeah, you will probably get to it.
You've been doing recent work on looking at computational systems,
even trivial ones like algorithms,
sorting algorithms, and analyzing the behavioral kind of way,
see if there's minds inside those sorting algorithms.
And, of course, I make a podhead statement question here,
that you can start to do things like trying to do psychedelics
with the sorting.
Yeah.
And what is that even?
look like. Yeah. It looks like a ridiculous question. It'll get you fired from most academic
departments, but it may be if you take it seriously, you could try and see if it applies.
Yeah. If it has, if a thing could be shown to have some kind of cognitive complexity, some kind
of mind, why not apply to it the same kind of analysis and the same kind of tools like psychedelics
that you would to a human mind? That's a complex human mind. It's at least might be a productive
question to ask, what, because you've seen like spiders on psychedelics, like more
primitive biological organisms on psychedelics. Why not try to see what an algorithm does
on psychedelics? Well, yeah, because you see, the thing to remember is we don't have a magic
sense or really good intuition for what the mapping is between the embodiment of something
and the degree of intelligence it has. We think we do because we have an N of one example on Earth
And we kind of know what to expect from cells, snakes, you know, primates.
But we really don't.
We don't have, and this is we'll get into more of the stuff on the platonic space.
But our intuitions around that stuff is so bad that to really think that we know enough not to try things at this point is, I think, really short-sighted.
Before we talk about the platonic space, let's lay out some foundations.
I think one useful one comes from the paper, technological approach to mind.
everywhere, an experimentally grounded framework for understanding diverse bodies and minds.
Could you tell me about this framework, and maybe can you tell me about figure one from this
paper that has a few components? One is the tiers of biological cognition that goes from group
to whole organism to whole tissue organ, down to neural network, down to the side of skeleton,
down to genetic network. And then there's layers of biological systems from,
ecosystem down to swarm, down to organism, tissue, and then finally cell. So can you explain
this figure and can you explain the tame so-called framework? So this is the version 1.0
and there's a kind of update at 2.0 that I'm writing at the moment trying to formalize in a
careful way all the things that we've been talking about here. And in particular, this notion of
having to do experiments to figure out where any given system is on a continuum. And we can let's just
start with figure two maybe for a second and then we'll come back to figure one. And first, just to
unpack the acronym, I like the idea that it spells out tame because the central focus of this is
interactions and how do you, how do you interact with a system to have a productive interaction with it?
And the idea is that cognitive claims are really protocol claims. When you tell me that something has
some degree of intelligence. What you're really saying is, this is the set of tools I'm going to
deploy, and we can all find out how that worked out for you. And so, technological, because I wanted
to be clear with my colleagues that this was not a project in just philosophy, this had very
specific empirical implications that are going to play out in engineering and regenerate medicine
and so on. Technological approach to mind everywhere, this idea that we don't know yet where
different kinds of minds are to be found, and we have to empirically figure that out.
And so what you see here in figure two is basically this idea that there is a spectrum,
and I'm just showing four waypoints along that spectrum, and as you move to the right of
that spectrum, a couple of things happen.
Persuidability goes up, meaning that the systems become more reprogramable, more plastic,
more able to do different things than whatever they're standardly doing.
So you have more ability to get them to do new and interesting things.
the effort needed to exert influence goes down
that is autonomy goes up
and to the extent that you are good at convincing
or motivating the system to do things
you don't have to sweat the details as much
right and this also has to do with
what I call engineering agential materials
so when you engineer wood, metal, plastic, things like that
you are responsible for absolutely everything
because the material is not going to do anything
other than hopefully hold its shape.
If you're engineering active matter
or you're engineering computational materials
or better yet, agential materials like living matter,
you can do some very high level prompting
and let the system then do very complicated things
that you don't need to micromanage.
And we all know that that increases
when you're starting to work with intelligent systems
like animals and humans and so on.
And the other thing that goes down as you get to the right
is the amount of mechanism or physics
that you need to exert the influence goes down.
So if you know how your thermostat is to be set,
as far as at set point, you really don't need to know much of anything else, right?
You just need to know that it is a homeostatic system and that this is how I change the set point.
You don't need to know how the cooling and heating plant works in order to get it to do complex things.
By the way, a quick pause.
Just for people who are listening, let me describe what's in the figure.
So there's four different systems going up the scale of persuadability.
So the first system was a mechanical clock.
Then it's a thermostat.
Then it's a dog that gets rewards and punishments.
Pavlov's dog.
and then finally, a bunch of very smart-looking humans
communicating with each other
and arguing, persuading each other,
using hashtag reasons.
And then there's arrows below that,
showing persuadability going up as you go up these systems
from the mechanical clock to a bunch of Greeks arguing
and then going down as the effort needed to exert influence
and once again going down is mechanism knowledge needed to exert that influence.
Yeah.
I'll give you an example about that.
that panel C here with a dog, isn't it amazing that humans have been training dogs and horses
for thousands of years knowing zero neuroscience? Also amazing is that when I'm talking to you right
now, I don't need to worry about manipulating all of the synaptic proteins in your brain
to make you understand what I'm saying and hopefully remember it. You're going to do that all
on your own. I'm giving you very thin in terms of information content, very thin prompt, and I'm
counting on you as a multi-scale agential material to take care of the chemistry underneath.
So you don't need a wrench to convince me.
Correct. I don't need, and I don't need physics to convince you, and I don't need to know how you work.
Like, I don't need to understand all of the steps.
What I do need to have is trust that you are a multi-scale cognitive system that already does that for yourself.
And you do, like, this is an amazing thing.
I don't, people don't think about this enough, I think, when you wake up in the morning and you have social goals, research goals, financial goals, whatever, whatever is that you have, in order for you to act on those goals, sodium and calcium and other,
ions have to cross your muscle membranes.
Those incredibly abstract goal states ultimately have to make the chemistry dance in a very
particular way, right?
Our entire body is a transducer of very abstract things.
And by the way, not just our brains, but other, you know, our organs have anatomical
goals and other things that we can talk about because all of this plays out in regeneration
and development and so on.
But the scaling, right, of all of these things, the way that, the, the,
The way you regulate yourself is not by, oh, my God, you don't have to sit there and think,
wow, I really have to push some, you know, some sodiums across this membrane.
All of that happens automatically.
And that's the incredible benefit of these multi-scale materials.
So what I was trying to do in this paper is a couple of things.
All of these were, by the way, drawn by Jeremy Gay, who's this amazing graphic artist that works with me.
First of all, in panel A, which is the spiral I was trying to point out, is that at every level of biological organization,
Like we all know we're sort of nested dolls of, you know, organs and tissues and cells and molecules and whatever.
But what I was trying to point out is that this is not just structural.
Every one of those layers is competent and is doing problem solving in different spaces.
And spaces that are very hard for us to imagine.
We humans are, because of our own evolutionary history, we are so obsessed with movement in three-dimensional space that even in AI you see this all the time.
They say, well, this thing doesn't have a robotic body.
It's not embodied.
Yeah, it's not embodied by moving around.
in 3D space, but biology has embodiments in all kinds of spaces that are hard for us to
imagine, right? So your cells and tissues are moving in high dimensional physiological
state spaces and gene expression state spaces, in anatomical state spaces. They're doing that
perception, decision-making action loop that we do in 3D space. When we think about robots
wandering around your kitchen, they're doing those loops in these other spaces. And so the first
thing I was trying to point out is that, yeah, every layer of your body has its own ability to solve
problems in those spaces. And then on the right, what I was saying is that this distinction between
people say, well, there are living beings and then there are engineered machines and then they
often follow up with all the things machines are never going to be able to do and whatever.
And so what I was trying to point out here is that it is very difficult to maintain those kind
of distinctions because life is incredibly interoperable. Life doesn't really care if the thing
it's working with was evolved through random trial and error or was engineered.
with a higher degree of agency, because at every level, within the cell, within the tissue,
within the organism, within the collective, you can replace and substitute engineered systems
with the naturally evolved systems. And that question of, is it really, you know, is it biology or
is it technology? I don't think it's a useful question anymore. So I was trying to warm people up
with this idea that what we're going to do now is talk about minds in general, regardless of
their history or their composition. It doesn't matter what you're made of. It doesn't matter how you got
here. Let's talk about what you're able to do and what your inner world looks like. That was the
goal of that. Is it useful as a thought experiment, as an experiment of radical empathy to try to
put ourselves in the space of the different minds at each stage of the spiral? It's like what
state space is human in civilization as a collective embodied? What is it operating? So humans,
individual organisms
operate in 3D space.
That's what we understand.
But when there's a bunch of us together,
what are we doing together?
It's really hard,
and you have to do experiments,
which at larger scales are really difficult.
But there is such a thing.
There may well be.
We have to do experiments.
I don't know.
There's an example.
Somebody will say to me,
well, you know,
with your kind of panpsychist,
you probably think the weather is a gential too.
I'm like, well, I can't say that,
But we don't know, but have you ever tried to see if a hurricane has habituation or sensitization?
Maybe we haven't done the experiment.
It's hard, but you could, right?
And maybe, maybe whether systems can have certain kinds of memories, I have no idea.
We have to do experiments.
So I don't know what the entire human society is doing, but I'll just give you a simple example of the kinds of tools.
And we're actively trying to build tools now to enable radically different agents to communicate.
So we are doing this using, using AI and other tools.
to try and get this kind of communication going across very different spaces.
I'll just give you a very kind of dumb example of how that might be.
Imagine that you're playing tic-tac-toe against an alien.
So you're in a room.
You don't see him.
So you draw the tic-tac-toe thing on the floor and you know what you're doing.
You're trying to make straight lines with X's and O's.
And you're having a nice game.
It's obvious that he understands the process.
Like sometimes you win, sometimes you lose like it's obvious.
In that one little segment of activity you guys are sharing a world, what's happening in the other room next door?
Well, let's say the alien doesn't know anything about geometry.
He doesn't understand straight lines.
What he's doing is he's got a box and it's full of basically billiard balls, each one of which has a number on it.
And all he's looking is he's doing is he's looking through the box to find billiard balls whose numbers add up to 15.
He doesn't understand geometry at all.
all he understands is arithmetic.
You don't think about arithmetic.
You think geometry.
The reason you guys are playing the same game is that there's this magic square, right,
that somebody constructed that basically is a three by three square where if you pick
the numbers right, they add up to 15.
He has no idea that there's a geometric interpretation to this.
He is solving the problem that he sees, which is totally algebra.
You don't know anything about that.
But if there is an appropriate interface like this magic square, you guys can share that
experience. You can have an experience. It doesn't mean you start to think like him. It means that
you guys are able to interact in a particular way. Okay, so there's a mapping between the two different
ways of seeing the world that allows you to communicate with each other. Of seeing a thin slice
of the world. Thin slice of the world. How do you find that mapping? So you're saying we're trying to
figure out ways of finding that mapping for different kinds of systems. So what's the process for
doing that. So, so the process, the process is twofold. One is to get a better, um, understanding of
what the system, what space is the system navigating? What goals does it have? What level of ingenuity
does it have to reach those goals? For example, xenobots, right? We make xenobots. This is, or anthropots,
these are biological systems that have never existed on Earth before. We have no idea what their
cognitive properties are. We're learning. We found some things. But you can't predict that from first
principles because they're not at all what their past history would, would inform you of.
Can you actually explain briefly what an enturbot is? So one of the things that we've
been doing is trying to create novel beings that have never been here before. The reason is
that typically when you have a biological system, an animal or a plant, and you say, hey, why does
it have certain forms of behavior, certain forms of anatomy, certain forms of physiology, why does it
have those? The answer is always the same.
well, there's a history of evolutionary selection, and there's a long, long history going
back of adaptation, and there are certain environments, and this is what survived, and so that's
why it has. So what I wanted to do was break out of that mold, and to basically force us
as a community to dig deeper into where these things come from, and that means taking away
the crutch where you just say, well, it's an evolutionary selection. That's why it looks
like that. So to do that, we have to make artificial synthetic beings. Now, to be clear, we are
starting with living cells. So it's not that they had no evolutionary history. The cells do. They
had evolutionary history in frogs or humans or whatever. But the creatures they make and the
capabilities that these creatures have were never directly selected for. And in fact, they never
existed. So you can't tell the same kind of story. And what I mean is we can take epithelial cells off
of an early frog embryo. And we don't change the DNA. No synthetic biology circuits. No material
scaffolds, no nanomaterials, no weird drugs, none of that. What we're mostly doing of
is liberating them from the instructive influences of the rest of the cells that they were in
in their bodies. And so when you do that, right, normally these cells are bullied by their
neighboring cells into having a very boring life. They become a two-dimensional outer covering
for the embryo, and they keep out the bacteria, and that's that. So you might ask, well,
what are these cells capable of when you take them away from that influence? So when you do
that they form another little life form we call a Zenobot. And it's this self-motile little thing that
has cilia covering its surface. The cilia are coordinated. So they row against the water and then the thing
starts to move and has all kinds of amazing properties. It has different gene expression. So it has
its own novel transcriptome. It's able to do things like kinematic self-replication, meaning make copies of
itself from loose cells that you put in its environment. It has the ability to respond to sound,
which normal embryos don't do.
It has these novel capacities, and we did that, and we said,
look, here are some amazing features of this novel system.
Let's try to understand where they came from.
And some people said, well, maybe it's a frog-specific thing, you know?
Maybe this is just something unique to frog cells.
So he said, okay, what's the furthest you can get from frog embryonic cells?
How about human adult cells?
And so we took cells from adult human patients who were donating tracheal epithelia
for biopsies and things like that.
And those cells in, again, no genetic change, nothing like that.
They self-organized into something we call anthropots, again, self-motile little creature,
9,000 different gene expressions.
So about half the genome is now different.
And they have interesting abilities.
For example, they can heal human neural wounds.
So in vitro, if you plate some neurons and you put a big scratch through it so you damage them,
anthropots can sit down and they will try, they will spontaneously, without
have us having to teach them to do it, they will spontaneously try to knit the neurons across.
What is this video that we're looking at here?
So this is an anthropot. So often when I give talks about this, I show people this video
and I say, what do you think this is? And people will say, well, it looks like some primitive
organism you got from the bottom of a pond somewhere. And I'll say, well, what do you think
the genome would look like? And is it, well, the genome would look like some primitive
creature. Right. If you sequence that thing, you'll get 100% homo sapiens. And that doesn't
look like any stage of normal human development. It doesn't act like, like any stage of human
development. It has the ability to move around. It has, as I said, over 9,000 differential
gene expressions. Also, interestingly, it is younger than the cells that it comes from. So it actually
has the ability to roll back its age. And we could talk about that and what the implications of
that are. But to go back to your original question, what we're doing with these kind of systems.
Try and talk to it. We're trying to talk to it. That's exactly right. And not just to this. We're
trying to talk to molecular networks. So we found a couple years ago, we found that gene
regulatory networks, never mind the cells, but the molecular pathways inside of cells can have
several different kinds of learning, including Pavlovian conditioning. And what we're doing now is
trying to talk to it. The biomedical applications are obvious. Instead of, hey, Siri, you want,
hey, liver, why do I feel like crap today? And you want an answer. Well, you know, your potassium levels
or this and that. And I don't feel, you know, I don't feel good for these reasons. And you should be able to
talk to these things, and there should be able to be an interface that allows us to communicate,
right? And I think AI is going to be a huge component of that interface of allowing us to talk
to these systems. It's a tool to combat our mind blindness to help us see diverse other
very unconventional minds that are all around us. Can you generalize that? Let's say we meet
an alien or an unconventional mind here on Earth. Think of it as a black box.
you show up, what's the procedure for trying to get some hooks into communication protocol
with the thing?
Yeah, that is exactly the mission of my lab.
It is to enable us to develop tools, to recognize these things, to learn to communicate
with them, to ethically relate to them, and in general, to expand our ability to do this
in the world around us.
I specifically chose these kinds of things
because they're not as alien as proper aliens would be.
So we have some hope.
I mean, we're made of them.
We have many things in common.
There's some hope of understanding them.
You're talking about xenobots and anthrobots and cells
and everything else.
But they're alien in a couple of important ways.
One is the space they live in is very hard for us to imagine.
What space do they live in?
Well, your body, your body cells,
long before we had a brain that was good for,
navigating three-dimensional space
was navigating the space of anatomical
possibilities. It was going from, you
start as an egg and you have
to become, you know, a snake
or a, or a, you know, a giraffe
or whatever, or a human, whatever, whatever we're going to be.
And I specifically
am telling you that
this general
idea, when people modeled that with
kind of cellular automata type of
ideas, this open loop kind of thing where
well, everything just follows local rules
and eventually there's complex city and
And here you go. Now you've got a giraffe or a human. I'm specifically telling you that that model is
totally insufficient to grasp what's actually going on. What's actually going on, and there have
been many, many experiments on is that the system is navigating a space. It is navigating a space
of anatomical possibilities. If you try to block where it's going, it will try to get around
you. If you try to challenge it with things it's never seen before, it will try to come up with a solution.
If you really defeat its ability to do that, which you can, you know, they're not infinitely
intelligent so you can you can defeat them you will either get birth defects or you will get
creative problem solving such as what you're seeing here with xenobots and anthropos if you can't be a
human you'll be some you can you'll find another way to be in you can be an anthropot for example
or you'll be something else just to clarify what's the difference between cellular automata
type of action where you're just responding to your local environment and creating some kind
of complex behavior and uh operating in the space of anatomical possibilities sure so
there's a kind of goal, I guess, your article?
There is some kind of thing.
There's a will to X, something.
The will thing, let's put that aside because that's it.
Well, it's fine.
There I go, Anthropa.
That's just always love to quote Nietzsche.
Yeah, yeah, yeah.
And I'm not saying, I'm not saying that's wrong.
I'm just saying I don't have data for that one,
but I'll tell you the stuff that I'm quite certain of.
There are a couple of different formalisms that we have in control theory.
One of those formalisms is open loop complex.
In other words, I've got a bunch of subunits, like a cellular automaton, they follow certain rules and you turn the crank, time goes forward, whatever happens, happens.
Now, clearly you can get complexity from this.
Clearly, you can get some very interesting looking things, right?
So the game of life, all those kinds of cool things, right?
You can get complexity, no problem.
But the idea that that model is going to be sufficient to explain and control things like morphogenesis is a high.
hypothesis. It's okay to make that hypothesis, but we know it's false, despite the fact that that is
what we learn, you know, in basic cell biology and developmental biology classes, when the first
time you see something like this inevitably, especially if you're an engineer in those classes,
you're raising you and you go, how does it know to do that? How does it know, four fingers instead
of seven? What they tell you is it doesn't know anything. That's very clear. They all insist.
When we learn these things, they and says, nothing here knows anything.
There are rules of chemistry.
They roll forward, and this is what happens.
Okay.
Now, that model is testable.
We can ask, does that model explain what happens?
Here's where that model falls down.
If you have that model and situations change, either there's damage or something in the environment that's happened, those kind of open-loop models do not adjust to give you the same goal by different means.
means. This is William James' definition of intelligence, his same goal by different means. And in
particular, working them backwards, let's say you're in regenerative medicine and you say,
okay, but this is the situation now. I want it to be different. What should the rules be? It's not
reversible. So the thing with those kind of open loop models is they're not reversible. You don't know
what to do to make the outcome that you want. All you know how to do is roll them forward. Right.
Now, in biology, we see the following. If you have a developmental system and you
put barriers between, so I'm going to give you two pieces of evidence that suggest that there
is a goal. One piece of evidence is that if you try to block these things from the outcome
that they normally have, they will do some amazing things, sometimes very clever things,
sometimes not at all the way that they normally do it. Right. So this is William James's
definition by different means, by following different trajectories, they will go around various
local maxima and minima to get to where they need to go. It is navigation of a space. It is
nod blind turn the crank and wherever we end up is where we end up. That is not what we see
experimentally. And more importantly, I think what we've shown, and this is something that I'm
particularly happy with in our lab, over the last 20 years, we've shown the following. We can
actually rewrite the goal states because we found them. We have shown through our work on
bioelectric imaging and bioelectric reprogramming, we have actually shown how those goal
memories are encoded, at least in some cases. We certainly haven't got them all, but we have
Some. If you can find where the goal state is encoded, read it out, reset it, and the system will now implement a new goal based on what you just reset. That is the ultimate evidence that your goal directed model is working. Because if there was no goal, that shouldn't be possible. You shouldn't be, right? Once you can find it, read it, interpret it, and rewrite it, it means that by any engineering standard, it means that you're dealing with a homeostatic mechanism.
How do you find where the goal is encoded?
So through lots and lots of hard work.
The barrier thing is part of that, creating barriers and observing.
The barrier thing tells you that you should be looking for a goal.
So step one when you approach the genetic system is create a barrier of different kinds
until you see how persistent it is at pursuing the thing it seemed to have been pursuing originally.
And then you know, okay, cool, this is a, this thing has agency, first of all.
And then second of all, like you start to build an intuition about exactly.
which goal is pursuing. Yes. The first couple of steps are all imagination. You have to ask yourself,
what space is this thing even working in? And you really have to stretch your mind because we can't
imagine all the spaces that systems work in, right? So step one is what space is it? Step two,
what do I think the goal is? And let's not mistake. Step two, you're not done. Just because you
haven't made a hypothesis, that doesn't mean you can say, well, there, I see it doing this,
therefore that's the goal. You don't know that. You have to actually do experiments. Now,
once you've made those hypotheses, now you do the experiments, you say, okay, if I want to block it from
reaching its goal. How do I do that? And this, by the way, is exactly the approach we took with
the sorting algorithms and with everything else. You hypothesize the goal, you put a barrier in,
and then you get to find out what level of ingenuity it has. Maybe what you see is, well,
that derailed everything. So probably this thing isn't very smart. Or you see, wow, it can go around
and do these things. Or you might see, wow, it's taking a completely different approach using its
affordances in novel ways. That's a high level of intelligence. You will find out what the answer is.
Another pot had a question, is it possible to look at,
speaking of unconventional organisms and going to wish your darkness,
for example, with memes, is it possible to think of things like ideas?
Like, how weird can we get?
Can we look at ideas as organisms, then creating barriers for those ideas,
and seeing are the ideas themselves,
if you take the actual individual ideas
and trying to empathize and visualize what kind of space them,
be operating in can they be seen as organisms that have a mind yeah um okay if you want to get
really weird we can we can get we can get really weird here uh think about the uh caterpillar butterfly
transition okay so you got a caterpillar soft-bodied kind of creature has a particular controller
that's suitable for running a soft body you know kind of robot it has a brain for that task and then
it has to become this butterfly hard-bodied creature flies around you during the process of metamorphosis
its brain is basically ripped up and rebuilt from from scratch, right?
Now, what's been found is that if you train the caterpillar,
so you give it a new memory,
meaning that if the caterpillar sees this color or disc,
then it crawls over and eats some leaves.
Turns out the butterfly retains that memory.
Now, the obvious question is,
how the hell do you retain memories when the medium is being refactored like that?
Let's put that aside.
I'm going to get somewhere even weirder than that.
There's something else that's even more interesting than that.
It's not just that you have to retain the memory.
You have to remap that memory onto a completely new context, because guess what?
The butterfly doesn't move the way the caterpillar moves, and it doesn't care about leaves.
It wants nectar from flowers.
And so if that memory is going to survive, it can't just persist.
It has to be remapped.
Be remapped into a novel context.
Now, here's where things get weird.
We can take a couple of different perspectives here.
We can take the perspective of the caterpillar.
facing some sort of crazy singularity and say my god i'm gonna i'm gonna cease to exist but but you know i'll
sort of be reborn in this new higher dimensional world where i'll fly okay so that's one thing
we can take the perspective of the butterfly and say that well here i am but you know i seem to be
saddled with some some tendencies and some memories and i don't know where the hell they came from
and and i don't remember exactly how i got them and they seem to be a core part of my psychological
makeup and, you know, they come from somewhere. I don't know where they come from. Right. So you can
take that perspective. But there's a third perspective that I think is really interesting and useful.
And the third perspective is that of the memory itself. If you take a perspective of the memory,
which, so what is a memory? It is a pattern. It is an informational pattern that was
continuously reinforced within one cognitive system. And now here I am, I'm this memory.
What do I need to do to persist into the future? Well, now I'm facing the paradox of
change. If I try to remain the same, I'm gone. There's no way the butterfly is going to retain me
in the original form that I'm in now. What I need to do is change, adapt, and morph. Now, you might
say, well, that's kind of crazy. Well, how are you taking the perspective of a pattern within an
excitable medium, right? Agents are physical things. You're talking about the, you're talking about
information. So let me tell you another quick science fiction story. Imagine that some creatures come out
from the center of the earth.
They live down in the core.
They're super dense.
Okay, they're incredibly dense because they live down in the core.
They have gamma ray vision for, you know, and so on.
So they come out to the surface.
What do they see?
Well, all of this stuff that we're seeing here, this is like a thin plasma to them.
They are so dense.
None of this is solid to them.
They don't see any of this stuff.
So they're walking around, you know, the planet is sort of, you know, covered in
it's like thin gas, you know.
And one of them is a scientist and he's taken,
measurements of the gas. And he says to the others, you know, I've been watching this gas. And they're
like these little whirlpools in this gas. And they almost look like agents. They almost look
like they're doing things. They're moving around. They kind of hold themselves together for a little
bit and they're trying to make stuff happen. And, and the others say, well, that's crazy.
Patterns in the gas can't be agents. We are agents. We're solid. This is just patterns in an
excitable medium. And by the way, how long do they hold together? He says, well, about a hundred years.
Well, that's crazy. Nothing. No real agent can can exist to be that dissipate that fast.
Okay. We are all metabolic patterns among other things, right? And so one of the things that, and so you see what I'm warming up to do here. So one of the things that we've been trying to dissolve, and this is like some work that I've done with Chris Fields and others, is this distinction between thoughts and thinkers. So all agents are patterns within some excitable medium. We could talk about what that is. And they can spawn off others. And now you can have a really interesting spectrum. Here's the, here's the spectrum.
you can have fleeting thoughts, which are like waves in the ocean when you throw a rock in, you know, they sort of go through the excitable medium and then they're gone. They pass through and they're gone, right? So those are kind of fleeting thoughts. Then you can have patterns that have a degree of persistence. So they might be hurricanes or solitons or persistent thoughts or earworms or depressive thoughts. Those are harder to get rid of. They stick around for a little while.
They often do a little bit of niche construction, so they change the actual brain to have to make it easier to have more of those thoughts, right?
Like that's a thing.
And so they stay around longer.
Now, what's further than that?
Well, fragments, personality fragments of a dissociative personality disorder, they're more stable and they're not just on autopilot.
They have goals and they can do things.
And then pass that as a full-blown human personality.
and who the hell knows what's past that?
Maybe some sort of transhuman, you know, transpersonal, like, I don't know, right?
But this idea, again, I'm back to this notion of a spectrum.
There is not a sharp distinction between, you know, we are real agents and then we have
these thoughts.
Yeah, patterns can be agents too, but again, you don't know until you do the experiment.
So if you want to know whether a soliton or a hurricane or a thought within a cognitive
system is its own agent, do the experiment.
See what it can do.
Can it learn from experience?
Does it have memories?
Does it have goal states?
Does it, you know, what can it do, right?
Does it have language?
So, so coming back to then,
during the original question,
yeah, we can definitely apply this methodology
to ideas and concepts and social,
you know, whatever's,
but you've got to do the experiment.
That's such a challenging thought experiment
of like thinking about memories
from the caterpillar to the butterflies and organism.
I think at the very basic,
level intuitively we think of organisms as hardware yeah and software is not
possibly being able to be organisms but right what you're saying is that it's
all just patterns in an excitable medium and it doesn't really matter what the
pattern is we need to and what the excitable medium is we need to do the
testing avoid how persistent is it how goal-oriented is
visit and there's certain kind of tests to do that and you can apply that to memories you can
apply that to ideas you can apply that to anything really i mean you could probably think about
like consciousness you could there's really no um boundary to what you can imagine probably really
really wild things could be could be minds yeah stay tuned i mean this is exactly what we're doing
we're getting progressively like more and more unconventional i mean so so
So this whole distinction between software and hardware, I think it's a super important concept to think about.
And yet, the way we've mapped it onto the world, I would like to blow that up in the following way.
And again, I want to point out, so I'll tell you what the practical consequences are because this is not just, you know, of fun stories that we tell each other.
These have really important research implications.
Think about a Turing machine.
So one thing you can say is the machine's the agent, it has passive data, and it operates on the data.
And that's it.
The story of agency is the story of whatever that machine can and can't do.
The data is passive and it moves it around.
You can tell the opposite story.
You can say, look, the patterns on the data are the agent.
The machine is a stigmergic scratch pad in the world of the data doing what data does.
The machine is just the consequences, the scratch pad of it working itself out.
And both of those stories make sense, depending on what you're trying to do.
Here's the biomedical side of things.
So our program in bioelectrics and aging, okay?
One model you could have is the physical organism is the agent,
and the cellular collective has pattern memories,
specifically what I was saying before, goals, anatomical goals.
If you want to persist for 100 plus years,
your cells better remember what your correct shape is
and where the new cells go, right?
So there are these pattern memories that exist during embryogenesis,
during regeneration, during resistance to aging, we can see them, we can visualize them.
One thing you can imagine is, fine, the physical body, the cells are the agent, the electrical
pattern memories are just data, and what might happen during aging is that the data might get
degraded, they might get fuzzy.
And so what we need to do is reinforce the memories, reinforce the pattern memories.
That's one specific research program, and we're doing that.
But that's not the only research program, because the other thing you might imagine,
mention, is that what if the patterns are the agent in exactly the same sense as we think
in our brains, it's the patterns of electrophysiological, you know, computations and whatever
else that is the agent, right, and that what they're doing in the brain are the side
effects of the patterns working themselves out. And those side effects might be to fire off
some muscles and some glands and some other things. From that perspective, maybe what's actually
happening is maybe the agent's finding it harder and harder to be embodied in the physical
world. Why? Because the cells might get less responsive. In other words, the cells are sluggish. The
patterns are fine. They're having a harder time making the cells do what they need to do. And that maybe
what you need to do is not reinforce the memories. Maybe what you need to do is make the cells more
responsive to them. And that is a different research agenda, which we are also doing. We have evidence
for that as well, actually, now. And then we published it recently. And so my point here is,
when we tell these crazy sci-fi stories, the only worth to them and the only reason I'm talking about them now, and I hadn't been up, you know, a year ago I wasn't talking about this stuff, is because these are now actionable in terms of specific experimental research agendas that are heading to the clinic, I hope, in some of these biomedical approaches. And so now here we can go beyond this and we can say, okay, so up until now, we've considered, what are disease states? Well, we know there's organic disease. Something is physically broken. We can see the tissue is breaking down. There's this damage in the joint, you know, what?
what the liver is doing whatever, you know, we can see these things.
But what about disease states that are not physical states, they're physiological states
or informational states or cognitive problems?
So, in other words, in all of these other spaces, you can start to ask, what's a barrier
in gene expression space?
What's a local minimum that traps you in physiological state space?
And what is a stress pattern that keeps itself together, moves around the body, causes damage,
tries to keep itself going, right?
What level of agency does it have?
This suggests an entirely different set of approaches to biomedicine.
And, you know, anybody who's, let's say, in the alternative medicine community is probably
yelling at the screen and I've been saying this for hundreds of years.
And yeah, but, but, but, and I'm well aware, these are not, the ideas are not new.
What's new is being able to now take this and make them actionable and say, yeah, but we can
image this now.
I can now actually see the bioelectric patterns and why they go here and not there.
And we have the tools that now hopefully will get us to therapeutics.
So this is very actionable stuff.
And it all leans on not assuming we know minds when we see them because we don't.
And we have to do experiments.
To return back to the software hardware distinction,
you're saying that who can see the software as the organism and the hardware is just the scratch pad.
or you can see the hardware is the organism
and the software is the thing that the hardware generates.
And in so doing, we can decrease the amount of importance
we assign to something like the human brain,
where it could be the activations,
it could be the electrical signals that are the organisms,
and the brain is the scratch pad.
And by saying scratch pit, I don't mean it's not important.
When we get to talking about the platonic space,
we have to talk about how important the interface
actually is. The scratch bite isn't unimportant. The scratch pad is critical. It's just that my only
point is that when we have these formalisms of software, of hardware, of other things, the way we
map those formalisms onto the world is not obvious. It's not given to us. We get used to certain
things, right? But who's the hardware? Who's the software? Who's the agent and who's the excitable
medium is to be determined? So this is the good place to talk about the increasingly radical
weird ideas that you've been writing about.
You've mentioned it a few times, the platonic space.
Sir, there's this ingressing minds paper where you describe the platonic space.
You mentioned there's an asynchronous conference happening, which is a fascinating concept
because it's asynchronous, people are just contributing asynchronously.
So what happened was this crazy notion, which I'll describe momentarily, I have given a couple
talks on it. I then found a couple
papers in the machine learning community
called the Platonic
representation hypothesis. And I said,
that's pretty cool. These guys are climbing
up to the same point where I'm getting at it
from biology and philosophy and whatever.
They're getting there from computer science
and machine learning. We'll take a couple hours. I'll give
a talk. They'll give a talk. We'll talk about it. I thought there
were going to be three talks at this thing.
Once I started reaching out to
people for this,
everybody sort of said,
you know, I know somebody who's really into the
stuff, but they never talk about it because there's no audience for this.
So I reached out to them.
And then they said, yeah, I know this mathematician or I know this, you know,
economist, whatever, who has these ideas and there's nowhere we can have or talk about
them.
So I got this whole list, and it became completely obvious that we can't do this in a normal,
you know, we're now booked up through December.
So every week in our center, somebody gives a talk.
We kind of discussed it.
It all goes on this thing.
I'll give you a link to it.
And then there's a huge running discussion after that.
And then in the end, we're all going to get together for an actual real-time discussion section and talk about it.
But there's going to be probably 15 or so talks about this from all kinds of disciplines.
It's blown up in a way that I didn't realize how much undercurrent of these ideas had already existed that we're ready.
Like now is the time.
And I think this is like I've been thinking about these things for, I don't know, 30 plus years.
I never talked about them before because they weren't actionable before.
There wasn't a way to actually make empirical progress with this now.
You know, this is something that Pythagoras and Plato and probably many people before
them talked about, but now we're to the point where we can actually do experiments and
they're making a difference in our research program.
You can just look at a Platonic Space Conference.
There's a bunch of different fascinating talks, yours first on the patterns of forms and
behavior beyond emergence, then radical platonist.
and radical empiricism from Joe Dietz and patterns and explanatory gaps in psychotherapy.
Does God play dice from Alexi Tolchinsky and so on?
So let's talk about it.
What is it?
And it's fascinating that the origins of some of these ideas are connected to ML people thinking about representation space.
Yeah.
The first thing I want to say is that while I'm currently calling it,
the platonic space, I'm in no way trying to stick close to the things of Plato actually thought
about it. In fact, to whatever extent we even know what that is, I think I depart from that in
quite in some ways. And I'm going to have to change the name at some point. The reason I'm using the
name now is because I wanted to be clear about a particular connection to mathematics, which a lot
of mathematicians would call themselves Platonist because what they think they're doing is discovering,
not inventing as a human construction,
but discovering a structured,
ordered space of truths.
Let's put it this way.
In biology, as in physics,
there's something very curious that happens
that if you keep asking why,
then something interesting goes on.
Let's, well, I'll give you two examples.
First of all, imagine tucatus.
So the cicadas come out at 13 years and 17 years.
Okay.
And so if you're a biologist,
and you say, so why is that?
And then you get this explanation for, well,
it's because they're trying to be off cycle from their predators.
Because if it was 12 years, then every two year, every three year, every four year,
every six year a predator would eat you when you come on, right?
And you say, okay, okay, cool, that makes sense.
What's special about 13 and 17?
Oh, they're prime.
Uh-huh.
And why are they prime?
Well, now you're in the math department.
You're no longer in the biology department.
You're no longer in the physics department.
You're now in the math department to understand why the distribution of primes is what it is.
another example, and I'm not a physicist, but what I see is every time you talk to a physicist
and you say, hey, why do the, you know, leptons do this or that, or the fermions are doing whatever,
eventually the answer is, oh, because there's this mathematical, you know, this SU8 group or whatever
the heck it is, and it has certain symmetries and these certain structures. Yeah, great.
Once again, you're in the math department. So something interesting happens is that there are
facts that you come across. Many of them are very surprising. You don't get to design them. You get more
route than you put in in a certain way because you make very minimal assumptions and then
certain facts are thrust upon you. For example, the value of Feigenbaum's constant, the value
of natural algorithm E, these things you sort of discover, right? And the salient fact is this. If those
facts were different, then biology and physics would be different, right? So they matter. They
they impact, instructively, functionally,
they impact the physical world.
If the distribution of primes was something else,
well, then the cicadas would have been coming out at different times.
But the reverse isn't true.
What I mean is, there is nothing you can do in the physical world
to change E, as far as I know, to change E
or to change Feigenbaum's constant.
You could have swapped out all the constants at the Big Bang,
you can change all the different things.
You are not going to change those things.
So this, I think, Plato and Pythagoras understood very clearly
that there is a set of truths which impact the physical world,
but they themselves are not defined by and determined by what happens in the physical world.
You can't change them by things you do in the physical world.
And so I'll make a couple of claims about that.
One claim is I think we call physics those things that are constrained by those patterns.
When you say, hey, why is this the way it is?
Ah, it's because this is how symmetries or topology or whatever.
biology are the things that are enabled by those.
They're free lunches.
Their biology exploits these kinds of truths.
And really it enables biology and evolution to do amazing things without having to pay for it.
I think there's a lot of free lunches going on here.
And so I show you a xenobot or an anthropot.
And I say, hey, look, here are some amazing things they're doing that tissue has never done before in their history.
You say, first of all, where did that come from?
And when did we pay the computational cost for it?
Because we know when we paid the computational cost to design a frog or a human,
it was for the eons that the genome was bashing against the environment getting selected, right?
So you paid the computational cost of that.
There's never been any anthropots.
There's never been any xenobots.
When do we pay the computational cost for designing kinematic self-replication and, you know,
all these things that they're able to do?
So there's two things people say.
One is, well, it's sort of, you got it at the same.
time that they were being selected to be good humans and good frogs. Now, the problem with that is
it kind of undermines the point of evolution. The point of evolutionary theory was to have a very
tight specificity between how you are now and the history of selection that got you here, right?
The history of environments that got you to this point. If you say, yeah, okay, so this is what your
environmental history was, and by the way, you got something completely different. You got these
other skills that you didn't know about that. That's really strange, right? And so then what people say
is, well, it's emergent.
And they say, what's that?
What does that mean?
And they say, besides the fact that you got surprised, right?
Emergence is often just means I didn't see it coming.
You know, there was something happened.
I didn't know that was going to happen.
So, what does it mean that it's emergent?
And people say, well, and there are many emergent things like this.
For example, the fact that gene regulatory networks can do associative learning.
Like, that's amazing.
And you don't need evolution for that.
Even random genetic regulatory networks can do associative learning.
I say, why does that happen?
And he said, well, it's just a fact that holds in the world, just a fact.
that holds. So, so now you have a, you have, you have an option and you can go one of two ways.
You can either say, okay, look, I like my sparse ontology. I don't want to think about weird
platonic spaces. I'm a physicalist. I want the physical world, nothing more. So what we're going
to do is when we come across these crazy things that are very specific, like, you know,
anthropobots have four specific behaviors that they switch around. Why four? Why four? When we come
across these things, just like when we come across the value of E or Feigenbaum's number or whatever,
what we're going to do is we're going to write it down in our big book of emergence and that's it.
We're just going to have to live with it.
This is what happens.
We're just, you know, there's some cool surprises.
You know, when we come across them, we're going to write them down.
Great.
It's a random grab bag of stuff.
And when we come across and we'll write them down.
That's one.
The upside is you get to be a physicalist, then you get to keep your sparse ontology.
The downside is, I find it incredibly pessimistic and mysterian because you're basically then just willing,
to make a catalog of these amazing patterns. Why not instead, and this is why I started with
this platonic terminology, why not do what the mathematicians already do? A huge number of them
say, we are going to make the same optimistic assumption that science makes, that there's an
underlying structure to that latent space. There's not a random grab bag of stuff. There's a space
to it, which, where these patterns come from, and by studying them systematically, we can get from one
to another. We can map out the space. We can find out the relationships between them. We can get an
idea of what's in that space. And we're not going to assume that it's just random. We're going to
assume there's some kind of structure to it. And you'll see all kinds of people, I mean, you know,
well-known mathematicians that talk about this stuff, you know, Penrose and lots of other people
who will say that, yeah, there's another space physically. And it has spatial structure. It has
components to it and so on. We can traverse that space in various ways. And then there's the
physical space. So I find that much more appealing because it suggests a research program,
which we are now undergoing in our lab. The research program is everything that we make,
cells, embryos, robots, biobots, language models, simple machines, all of it. They are interfaces.
They are interfaces. All physical things are interfaces to these patterns. You build an interface.
Some of those patterns are going to come through that interface, depending on what you build,
some patterns versus others are going to come through.
The research program is mapping out that relationship between the physical pointers that we make
and the patterns that come through it, right?
Understanding what is the structure of that space, what exists in that space,
and what do I need to make physically to make certain patterns come through?
Now, when I say patterns, now we have to ask, what kinds of things live in that space?
Well, the mathematicians will tell it.
We already know.
We have a whole list of objects, you know, the ampletohedrons and all this crazy stuff that lives in that space.
Yeah, I think that's one layer.
of stuff that lives in that space, but I think those patterns are the lower agency kinds of
things that are basically studied by mathematicians. What also lives in that space are much more
active, more complex, higher agency patterns that we recognize as kinds of minds. That behavioral
scientists would look at that pattern and say, well, I know what that is. That's the competency for
delayed gratification or problem solving of certain kinds or whatever. And so what I end up with right now is a
model in which that latent space contains things that come through physical objects, so simple
patterns, right? So facts about triangles and Fibonacci, you know, patterns and fractals and
things like that. But also, if you make more complex interfaces such as biologicals and, but importantly,
not just biologicals, but let's say cells and embryos and tissues, what you will then pull down is
much more complex patterns that we say, ah, that's a, that's a mind, that's a human mind or that's
the, you know, snake mind or whatever.
So I think the mind-brain relationship is exactly the kind of thing that the math physics
relationship is, that in some very interesting way, there are truths of mathematics
that become embodied and they kind of haunt physical objects, right, in a very specific
functional way.
And in the exact same way, there are other patterns that are much more complex, higher agency
patterns that basically
in form, in
form, living things that we see
as obvious embodied minds.
Okay, given how weird and complicated
this we're describing is,
we'll talk about it more, but you got an
ELI-5, the basics
to a person has never seen
this. So, again,
you mentioned things like
pointers, so the physical object
themselves or the brain is a
pointer to that platonic
space. What
is in that platonic space?
What is the platonic space?
What is the embodiment?
What is the pointer?
Yeah.
Okay, let's try it this way.
There are certain facts of mathematics.
So the distribution of prime numbers, right?
That if you map them out, they make these nice spirals.
And there's an image that I often show, which is a very particular kind of fractal.
And that fractal is the Halley map, which is, it's pretty awesome that it actually looks very
organic. It looks very biological. So if you look at that thing, that image, which has a very
specific complex structure, it's a map of a very compact mathematical object. That formula is like,
you know, Z cube plus seven. It's something like that. That's it. So now, so now you look at that
structure and you say, where does that actually come from? It's definitely not packed into the Zcube
plus seven. It's not, there's not enough bits in that to give you all of that. There's no fact
of physics that determines this. There's no evolutionary history. It's not like we selected this
based on some, you know, from a larger set over time, where does this come from?
Or the fact that I think about, think about the way that biology exploits these things.
Imagine a world in which the highest fitness belonged to a certain kind of triangle, right?
So evolution cranks a bunch of generations and it gets the first angle right and cranks a bunch
more generations, gets the second angle, right?
Now there's something amazing that happens.
It doesn't need to look for the third angle because you already know.
If you know to, you get this magical free gift from geometry that says, why, I already know what
the third one should be. You don't have to go look for it. Or as evolution, if you invent a voltage
gated ion channel, which is basically a transistor, and you can make a logic gate, then all the
truth tables and the fact that NAND is special and all these other things, you don't have to
weave all those things. You get those for free. You inherit those. Where do all those things
live? These mathematical truths that you come across it, you don't have any choice about, you can't,
you know, once you've committed to certain axioms, there's a whole bunch of other stuff that is now
just it is what it is. And so what I'm saying is, and this is what Pythagoras was saying, I think,
that there is a whole space of these kinds of truths. Now, he was focused on mathematical ones,
but he was embodying them in music and in geometry and things like that. There are the space of
patterns and they make a difference in the physical world to machines, to sound, to things like
that. What I'm extending it. And what I'm saying is, yeah, and so far we've only been looking at the
low agency inhabitants of that world.
There are other patterns that we would recognize as kinds of minds and that you don't see
them in this space until there's an interface, until there's a way for them to come through
the physical world.
That interface, the same way that you have to make a triangular object before you can actually
see the rule of, you know, what you're going to gain, right, out of the rules of geometry
and whatever, or you have to actually do the computation on the fractal before you actually
see that pattern.
If you want to see some of those minds, you have to build an interface.
face, right? At least, at least if you're going to interact with them in the physical world, the way we normally do science. As Darwin said, mathematicians have their own new sense and like a different sense than the rest of us. And so that's right. You know, mathematicians can perhaps interact with these patterns directly in that space. But for the rest of us, we have to make interfaces. And when we make interfaces, which might be cells or robots or, you know, embryos or whatever, what we are pulling down our minds that are fundamentally not.
produced by physics. So I don't believe that. I don't know if we're going to get into the
whole consciousness thing, but I don't believe that we create consciousness, whether we make
babies or whether we make robots. Nobody's creating consciousness. What you create is an
interface, a physical interface through which specific patterns, which we call kinds of minds,
are going to ingress, right? And consciousness is what it looks like from that direction looking
out into the world. It's what we call the view from the perspective of the platonic patterns.
Just to clarify, what you're saying is a pretty radical idea here.
So if there's a mapping from mathematics to physics,
okay, that's understandable, intuitive, as you described.
But what you're suggesting is there's a mapping from some kind of abstract mind object
to an embodied brain that we...
think of as a mind.
Yeah.
As us fellow humans.
What is that, what exactly, because you said interface, you've also said pointer.
So the brain, and I think you said somewhere, a thin interface.
A thin client.
Yeah, the brain is a thin client, yeah.
Thin client, okay.
So you're, a brain is a thin client to this other world.
Yeah.
Can you just lay out very clearly how radical the idea is.
Sure.
Because you're kind of dancing around.
I think you'd also point to Donald Hoffman and kind of who speaks of an interface to a world.
So we've only interacted with the quote unquote real world through an interface.
What is the connection here?
Yeah.
Okay.
A couple of things.
First of all, when you said it makes sense for physics, I want to show that it's not as simple as it sounds.
Because what it means is that even in Newton's,
boring sort of classical universe long before quantum anything newton's world physicalism was
already dead in in in by in Newton's world i mean think about what that means this is this is
nuts because because already he knew perfectly well i mean pythagoras and plato knew that even in
a totally classical deterministic world already you have the ingression of information that
determines what happens in what's possible and what's not possible in that world from a space that
itself not physical. In other words, it's something like the natural logarithm E, right? Nothing in
Newton's world is set the value of E. There is nothing you could do to set the value of E in that world.
And yet, that fact that it was that and not something else governed all sorts of properties
of things that happen. That classical world was already haunted by patterns from outside that
world. This should be like, this is, this is wild. This is not saying that, okay, everything was, was cool,
Physicalism was great up until, you know, maybe we got quantum interfaces or we got, you know, consciousness or whatever, but originally it was fine. No, this is saying that it was, that, that worldview was already impossible, really. Since, from, from a very long time ago, we already knew that there are non-physical properties that matter in the physical world. This is a chicken or the egg question. You're saying Newton's laws are creating the physical world?
That is a very deep follow-on question that we'll come back to in a minute.
All I was saying about Newton is that you don't need quantum anything.
You don't need to think about consciousness.
You already, long before you got to any of that, as Pythagoras, I think, knew,
already we have the idea that this physical world is being strongly impacted by truths that do not live in the physical world.
Which truth that we're referring to?
Are we talking about Newton's law, like mathematical equations?
Mathematical facts.
So, for example, the actual value of E or...
Oh, like very primitive mathematical facts.
Yeah, yeah.
I mean, some of them are, you know, I mean, if you ask Don Hoffman, there's this like
amplitude hedron thing that is a set of mathematical objects that determines all the
scattering amplitudes of the particles and whatever, right?
They don't have to be simple.
I mean, the old ones were simple now.
They're like crazy.
I can't imagine this amplitude heedron thing that maybe they can.
But all of these are mathematical structures that,
explain and determine facts about the physical world, right?
If you ask physicists, hey, why, you know, this many of this type of particle?
Because this mathematical thing has these symmetries, that's why.
So Newton is discovering these things.
They're not, he's not inventing.
This is very controversial, right?
And there are, of course, physicists and mathematicians who disagree with what I'm saying, for sure.
But what I'm leaning on is simply this.
I don't know if anything you can do in the physical world at the big, you're around at the
Big Bang, you get to set all the constants.
Set physics however you want.
Can you change E?
Can you change Feigenbaum's constant?
I don't think you can.
Is that an obvious statement?
I don't even know what it means to change the parameters at the start of the Big
Bang.
So physicists do this, they'll say, okay, you know, if we made the, if we made the ratio
between the, you know, the gravitation and the electromagnetic force different, would we
have matter?
Would we, how many dimensions would we have?
Would there be inflation?
would there be this or that, right?
You can imagine playing with there.
There are however many unitless constants of physics.
These are the kind of like knobs on the universe
that you could have, in theory, be different,
and then you'd have different physical properties.
You're saying that's not going to change
the axiomatic systems that mathematics has.
What I'm not saying is that every alien everywhere
is going to have the exact same math that we have.
That's not what I'm claiming, although maybe,
but that's not what I'm claiming.
What I'm saying is you get more out than you put in.
Once you've made a choice, and maybe some aliens somewhere made a different choice
of how they're going to do their math, but once you've made your choice, then you get saddled
with a whole bunch of new truths that you discover that you can't do anything about.
They are given to you from somewhere, and you can say they're random, or you can say,
no, there's a space of these facts that they're pulled from.
There's a latent space of options that they come from.
So when you get, so when your E is exactly 2.7,18, and so on, there is nothing you can do in
physics to change it. And you're saying that space is immutable. I'm not saying it's immutable.
So, so I think Plato may or may not have thought that these forms are eternal and
unchanging. That's one place we differ. I actually think that space has some action to it,
maybe even some computation to it. But we're, we're just pointers.
Well, so let's, okay, so I'll circle us. I'll circle back around to that, to that whole thing.
So, so the only thing I was trying to do is blow up the idea that we're cool with how it works in
physics, no problem there.
Like, I don't, like, I think that's a much bigger deal than, than people normally think
it is.
I think already there, you have this weird haunting of, of the physical world by patterns that
are not coming from the physical world.
The reason I emphasize is because now what I'm going to, when I amplify this into
biology, I don't think it sort of jumps as a new thing.
I think it's just a much more, I think what we call biology is our systems that exploit the
hell out of it.
I think physics is constrained by it.
but we call biology those things that make use of those kinds of things and run with it.
And so, again, I just think it's a scaling.
I don't think it's a brand new thing that happens.
I think it's a scaling, right?
So what I'm saying is we already know from physics that there are non-physical patterns,
and these are generally patterns of form, which is why I call them low agency,
because they're like fractals that stand still and they're like prime number distributions,
although there's a mathematician that's talking in our symposium that's telling me that actually
I'm too chauvinistic even there.
Actually, even those things have more oomph than even I gave them credit for, which I love.
So what I'm saying is those kind of static patterns are things that we typically see in physics,
but they're not the full extent of what lives in that space.
That space is also home to some patterns that are very high agency.
And if we give them a body, if we build a body that they can inhabit,
then we get to see different behavioral competencies that the behavior scientists say,
oh, I know what that looks like.
That's this kind of behavioral, you know, this kind of mind or that kind of mind.
In a certain sense, I mean, yes, what I'm saying is extremely radical, but it is a very old idea.
It's an old idea of a dualistic worldview, right, where the mind was not in the physical body
and that it in some way interacted with the physical brain.
So I just want to be clear, I'm not claiming that this is fundamentally a new idea.
This has been around forever.
However, it's mostly been discredited, and it's a very unpopular view nowadays.
There are very few people in the, for example, cognitive science community or anywhere else in science that like this kind of view.
Primarily, and already Descartes was getting crap for this when he first trotted out as this interaction problem, right?
So the idea was, okay, well, if you have this non-physical mind and then you have this brain that presumably obeys conservation of mass energy and things like that, how are you supposed to interact with it?
There are many other problems there.
So what I'm trying to point out is that, first of all, physics already had this problem.
You didn't have to wait until you had biology and cognitive science to ask about it.
And what I think is happening in the way, the way we need to think about this is coming back to my point, that I think the mind-brain relationship is basically of the same kind as the math physics relationship.
The same way that non-physical facts of physics haunt physical objects is basically.
basically how I think different kinds of patterns
that we call kinds of minds
are manifesting through interfaces like brains.
How do we prove or disprove the existence of that world?
Because it's a pretty radical one.
Well.
Because this physical world can poke.
It's there.
It feels like all the incredible things
like consciousness and cognition
and all the goal-oriented behavior and agency
all seems to come from this.
3D entity.
Yeah, I mean.
And so like, we can test it, we can poke it,
we can hit it with a stick.
Yeah, sort of.
Makes noises.
Sort of.
I mean, the one, so Descartes got some stuff wrong, I think,
but one thing that he did get right,
the fact that, yeah, actually, you don't know what you can poke and what you can't poke.
The only thing you actually know are the contents of your mind and everything else might
be, and in fact, what we know from Anil Seth and Don Hoffman and various other people,
it's definitely a construct.
You might be on drugs.
and you might wake up tomorrow and say,
my God, I had the craziest dream of being Lex Reedman amazing.
It's a nightmare.
Yeah, who knows?
It's a ride.
Right?
But you see, it's not clear at all that the physical poking is your primary reality.
That's not clear to me at all.
I don't know.
That's an obvious thing that a lot of people can show is true to take a step to the cart.
I think, therefore, I am.
That's the only thing you know for sure and everything else could be.
be an illusion or a dream, that's already a leap.
I think from a basic caveman science perspective,
the repeatable experiment is the one that most of intelligence comes from here.
The reality is exactly as it is.
To take a step towards the Donald Hoffman worldview takes a lot of guts and imagination
and stripping away of the ego and all these kinds of processes.
I think you can get there more easily by synthetic bioengineering in the following sense.
Do you feel a lack of x-ray perception?
Do you feel blind in the x-ray spectrum or in the ultraviolet?
I mean, you don't.
You have absolutely no clue that stuff is there.
And all of your reality, as you see it, is shaped by your evolutionary history.
It's shaped by the cognitive structure that you have, right?
there are tons of stuff going on around us right now
of which we are completely oblivious
there's equally all kinds of other stuff
which we construct and this is just
modern cognitive science that says that
a lot of what we think is going on
is a total fabrication constructed by us
so I think this is not a
I don't think this is a philosophy
I mean Descartes got there from a philosophical point
that's not what I'm, that's not the leap I'm asking us to make
I'm saying that depending on your embodiment
depending on your interface
and this is increasingly going to be more relevant
as we make first augmented humans
that have sensory substitution.
You're going to be walking around,
your friend's going to be like,
oh, man, I have this primary perception
of the solar weather and the stock market
because I got those implants and what do you see?
Well, I see the traffic of the internet
through the, you know, Trans-Pacific channel.
We're all going to be living in somewhat different worlds.
That's the first thing.
The second thing is we're going to become better attuned
to other beings, whether they be cells,
tissues, you know, what's, what's it like to be a cell living in a 20,000 dimensional
transcriptional space, okay, to novel beings that have never been here before that have
all kinds of crazy spaces that they live in. And that might be AIs, it might be cyborgs,
it might be hybrots, it might be all sorts of things. So this idea that we have a consensus
reality here that's independent of some very specifically chosen aspects of our brain and
our interaction, we're going to have to give that up no matter what.
to relate to these other beings.
I think the tension is, and absolutely,
and this idea that you're talking about,
of sort of almost, I think you've termed a cognitive prosthetics,
which is different ways of perceiving
and interacting with the world.
But I guess the question is,
is our human experience, the direct human experience,
is that just a slice of the real world,
or is it a pointer to a different world?
That's what I'm trying to figure out,
Because the claim you're making is a really fascinating one, compelling one.
There's a pretty strong one, which is there's another world into which our brain is an interface to,
which means you could theoretically map that world systematically.
Yeah, which is exactly what we're trying to do.
Right, right.
But it's not clear that that world exists.
Yeah, yeah.
Okay.
I mean, so that's the beautiful part about this.
And this is why I'm talking about this now, where I wasn't, you know,
about a year ago, up until a year ago, I was never talking about this, because I think this is
now actionable. So there's this diagram that's called a map of mathematics, and they basically
try to show how all the different pieces of math linked together, and there's a bunch of different
versions of it. So there's two features to this. One is that, what is it a map of? Well, it's a map of
various truths. It's a map of facts that are thrust on you. You don't have a choice. Once you've
picked some axioms, you just, you know, here's some surprising facts that are just going to
be given to you. But the other key thing about this is that it has a metric. It's not just a
random heap of facts. They are all connected to each other in a particular way. They literally
make a space. And so when I say it's a space of patterns, what I mean is it is not just a
random bag of patterns such that when you have one pattern, you are no closer to finding any other
pattern. I'm saying that there's some kind of a metric to it so that when you find one,
others are closer to it and then you can get there. So that's the claim. And obviously,
this is not everybody buys this and so on. This is one idea. Now, how do we know that this exists? Well,
I'll say a couple of things. If that didn't exist, what is that a map of? If there is no space,
if you don't want to call it a space, that's okay, but you can't get away from the fact that as a matter
of research, there are patterns that relate to each other in a particular way. What's, you know,
the final step of calling it a space is minimal. The biggest,
the bigger issue is what the hell is it a map of then if it's not a space so that's that's the first
thing now that that's that's that's it plays out i think in math and physics now in biology here's
here's how we're going to know if this makes any sense what we are doing now is trying to map out
that space by saying look we we we we we know that the frog genome maps to one thing and that's a
frog turns out that exact same genome if you if you just if you just take a take the slightest step with the
exact same genome, which you just take some cells out of their environment, they can also make
xenobots with very specific different transcriptomes, very specific behaviors, very specific shapes.
It's not just, oh, well, you know, they do whatever, and they have very specific behaviors, just like
the frog had very specific properties. We can start to map out what all those are, right? Make that
latent, basically try to draw the latent space from which those things are pulled. And one of two things
is going to happen in the future. And so this is, you know, come back in 20 years, and we'll, and we'll
see how this worked out. One thing that could happen is that we're going to see, oh yeah, just like
the map of mathematics, we made a map of the space. And we know now that if I want a system that
acts like this and this, here's the kind of body I need to make for it, because those are the patterns
that exist. The anthropots have four different behaviors, not seven and not one. And so that's what
I can pull from. These are the options I have. Is it possible that there's varying degrees of
grandeur to the space that you're thinking about mapping, meaning it could be just, just like with
the space of mathematics, might it strictly be just the space of biology versus a space of
like minds, which feels like it could encompass a lot more than the just biology?
Yeah, except that. I don't see how it would be separate because I'm not just talking about
an anatomical shape and transcriptional profile.
I'm also talking about behavioral competencies.
So when we make something and we find out that, okay,
it does habituation,
sensitization, it does not do Pavlovian conditioning,
and it does do delay gratification,
and it doesn't have language,
that is a very specific cognitive profile.
That's a region of that space,
and there's another region that looks different,
because I don't make a sharp distinction between biology and cognition.
If you want to explain behaviors,
they are drawn from some,
distribution as well. So I think in 20 years or however long it's going to take, one of two things
will happen. Either we and other people who are working on this are going to actually produce a map
of that space and say, here's why you've gotten systems that work like this and like this and
like this, but you've never seen any that work like that, right? Or we're going to find out that
I'm wrong and that basically it's not worth calling it a space because it is so random and so jumbled
that we've been able to make zero progress
in linking the embodiments that we make
to the patterns that come through.
Yeah, just to be clear,
I mean, from your blockpost on this,
from the paper, I mean, we're talking about
a space that includes a lot of stuff.
Yeah, yeah.
Includes human, what is it, meditating, Steve.
Hello, my name is Steve, AI systems,
so all the space of computational systems,
objects, biological systems.
concepts. It includes everything. Well, it includes specific patterns that we have given names to.
Some of those patterns we've named mathematical objects. Some of those patterns we made,
we've named anatomical outcomes. Some of those patterns we've made psychological types.
So every entry in an encyclopedia, old school Britannica, is a pointer to this space.
There is a set of things that I feel very strongly about because the research is
telling us that's what's going on.
And then there's a bunch of other stuff that I see as hypotheses for next steps,
the guide experiment.
So what I'm about to tell you, I don't know, these are things I don't actually know.
These are just guesses that, you know, you need to make some guesses to make progress.
I don't think that there are specific, or I don't know, but it doesn't mean that there are
going to be specifically tonic patterns for this is the Titanic and this is the sister of the
Titanic and this is some other kind of boat.
this is not what I'm saying. What I'm saying is in some way that we absolutely need to work out
when we make minimal interfaces, we get more than we put in. We get behaviors, we get
shapes, we get mathematical truths, and we get all kinds of patterns that we did not have to
create. We didn't micromanage them. We didn't know they were coming. We didn't have to put any
effort into making them. They come from some distribution that seems to exist that we don't have to
create. And exactly whether that space is sparse or dense, I don't know. So, for example, if there is
some kind of a, you know, a platonic form for the movie The Godfather, if it's surrounded by a bunch
of crappy versions and then crappier versions still, I have no idea, right? I don't know if the
space is sparse or not. I, you know, I don't know if it's finite or infinite. These are all things
I don't know. What I do know is that it seems like physics and for sure biology and cognition are the
benefits of ingressions that are free lunches in some sense. We did not make them calling them
emergent does nothing for a research program. Okay, that just means you got surprised. I think,
I think it's much better if you say, if you make the optimistic assumption that they come from a
structured space that we have a prayer and hell of actually exploring. And in some decades,
if I'm wrong, and it says, you know what, we tried, it looks like it really is random to bad,
fine. Is there a difference between, like, can we one day prove the existence?
of this world is and is there a difference between it being a really effective model
for connecting things explaining things versus like an actual place where the information about
these distributions that we're sampling actually exists that we can hit with a stick you
yeah you can you can you can try to make that distinction yeah but i think i think modern cognitive
neuroscience will tell you that whatever you think this is, at most, it is a very effective
model for predicting the future experiences you're going to have.
So all of this that we think about is physical reality is just as a nice convenient model.
I mean, that's not me.
That's predictive processing and active infrared.
Like, that's modern neuroscience telling you this, that this isn't anything that I,
that I'm particularly coming up with.
All I'm saying is the distinction, the distinction you're trying to make, which is like an old
school, like realist, you know, kind of view that is it, is it, is it, is it, is it metaphorical or
is it real? All we have in science are metaphors, I think, and the only question is how good are
your metaphors? And I think as agents act, living in a world, all we have are models of what we
are and what the outside world is. That's it. And the question is, how good is it a model? And,
and, and my claim about this is in some small number of decades, either, this will either give rise to a very
enabling mapping of the space for for AI, for bioengineering, for biology, whatever,
or we are going to find out that it really sucks because it really is a random grab bag of
stuff and we tried the optimistic research program.
It failed and we're just going to have to live with surprise.
I mean, I doubt that's going to happen, but it's a possible outcome.
But do you think there is some place where the information is stored about these distributions
that were being sampled through the thin interfaces?
like actual place
place is weird
because it isn't the same
as our physical space time
okay I don't think it's that
so calling it a place is a little
weird
no but like physics
general relativity
describes a space time
could other physics theories
be able to describe
this other space
where information is stored
that we can apply
maybe different
but in the same spirit
laws about
information
I definitely think
they're going to be
systematic laws
I don't think they're going to look anything like physics.
You can call it physics if you want, but I think it's going to be so different that that probably just, you know, cracks the word.
And whether information is going to survive that, I'm not sure.
But I definitely think that it's going to be, there are going to be laws.
But I think they're going to look a lot more like aspects of psychology and cognitive science than they're going to look like physics.
That's my guess.
So what does it look like to prove that world exists?
What it looks like is a successful research program that explains how you pull particular patterns when you need them and why some patterns come and others don't and show that they come from an ordered space.
Across a large number of organisms?
Well, it's not just organisms.
I mean, I think it's going to end up.
And, I mean, you can talk to the machine learning people about how they got to this point again, because this is, this is not just me.
There's a bunch of, there are a bunch of different disciplines that are converging on this now simultaneously.
you're going to you're going to find again just like in mathematics where from from from different directions everybody sort of is looking at different things and oh my god this is one underlying structure that seems to like inform all of this so in physics in mathematics in computer science machine learning possibly in economics certainly in biology possibly in you know cognitive science we're going to find these structures it was already obvious in pathagoras this time that that there are these patterns the only remaining
in question is, are they part of an ordered structured
or space? And are we up to the task of
mapping out the relationship between what we build and the patterns
that come through it? So from the machine learning perspective,
is it then the case that even something as simple as
LLMs are sneaking up onto this world?
The representations that they form are sneaking up to it?
I've given this talk to some audiences and especially in the organicist community, people like the first part where it's like, okay, now there's an idea for what the magic, quote, unquote, is that's special about the living things and so on.
Now, now if we could just stop there, we would have dumb machines that just do what the algorithm says, and we have these magical living interfaces that can be the recipient.
for these ingressions.
Cool, right?
We can cut up the world in this way.
Unfortunately, or fortunately, I think, that's not the case.
And I think that even simple minimal computational models are, to some extent,
beneficiaries of these free lunches.
I think that the theories we have, and this goes back to the thin client interface kind of idea,
the theories we have of both of physical.
physics and computation. So theory of algorithms, you know, touring machines, all that good stuff.
Those are all good theories of the front end interface. And they're not complete theories of the
whole thing. They capture the front end, which is why they get surprised, which is why these things
are surprising when they happen. I think that when we see embryos of different species,
we are pulling from well-trodden, familiar regions of that space. And we know what to expect,
frog, you know, snake, whatever. When we make cyborians,
orgs and hybrots and biobots, we are pulling from new regions of that space that look a little
weird and they're unexpected, but you know, we can still kind of get our mind around them.
When we start making AIs, like proper AIs, we are now fishing in a region of that space that we may,
that may never have had bodies before. It may have never been embodied before. And what we get
from that is going to be extremely surprising. And the final thing, just to mention on that,
is that because of this, because of the inputs from this platonic space,
some of the really interesting things that artificial constructs can do
are not because of the algorithm.
They're in spite of the algorithm.
They are filling up the spaces in between.
There's what the algorithm is forcing you to do,
and then there's the other cool stuff it's doing,
which is nowhere in the algorithm.
And if that's true, and we think it's true even of very minimal systems,
then this whole business of language models and AIs in general,
watching the language part may be a total red herring because the language is what we force them
to do the question is what what else are they doing that we are not we are not good at noticing
and this is you know this this this this is something that we are i think um as a as a kind of
uh existential um step for humanity is to is to become better at this because we are not good
at recognizing these things now you got to tell me more about uh this behavior that is
observable that is unrelated to the explicitly stated goal of a particular algorithm. So you looked
at a simple algorithm of sorting. Can you explain what was done? Sure. First, just the goal of the
study. There are two things that people generally assume. One is that we have a pretty good
intuition about what kind of systems are going to have competencies. So from observing biologicals,
we're not terribly surprised when biology does interesting things. Everybody always says, well, it's
biology, you know, of course, it does all this cool stuff.
And yeah, but we have these machines and the whole point of having machines and
dumb and algorithms and so on is they do exactly what you tell them to do, right?
And people feel pretty strongly that that's a binary distinction and that that's what,
that's, we can carve up the world in that way.
So I wanted to do two things.
I wanted to, first of all, explore that and hopefully break the assumption that we're good
at seeing this because I think we're not.
And I think it's extremely important that we understand.
very soon that we need to get much better at knowing when to expect these things.
And the other thing I wanted to do was to find out, you know, mostly people assume that you
need a lot of complexity for this. So when somebody says, well, the capabilities of my mind
are not properly encompassed by the rules of biochemistry. Everybody is like, yeah, that makes
sense where, you know, you're very complex and, okay, your, you know, your mind does things that
that you can't, you couldn't, you couldn't see that coming from the rules of biochemistry,
right? Like, we know that. Um, so mostly people think that has to do with complexity. And,
and what I would like to find out is, as part of understanding what kind of interfaces
give rise to what kind of ingressions, is it really about complexity? How much complexity do
actually need? Is there some threshold after which this happens? Is it really specific
materials? Is it biologicals? Is it something about evolution? Like, what is it about these
kinds of things that allows this this surprise right allows this idea that we are more than the
sum of our parts and so and and i had a strong intuition that none of those things are actually
required that this is this kind of magic so to speak seeps into pretty much everything and uh and so to
to look at that i wanted also to uh have an example that had significant shock value because the thing
with biology is there's always more mechanism to be discovered right like there's infinite depth of what the
materials are doing what the, you know, somebody will always say, well, there's a mechanism
by that I just haven't found it yet. So I wanted an example that was simple, transparent, so you
could see all the stuff. There was nowhere to hide. I wanted it to be deterministic because I don't
want it to be something around unpredictability or stochasticity. And I wanted to be something familiar
to people, minimal. And I wanted to use it as a model system for honing our abilities to take a new
system and looking at it with fresh eyes. And that's because these sorting algorithms have been studied for
over 60 years. We all think we know what they do and what their properties are. The algorithm
itself is just a few lines of code. You know, you can, you can see exactly what's there. It's
deterministic. And that's, so that that's why. That's why, right? I wanted, I wanted the most
shock value out of a system like that if we were to find anything and to use it as an example of
taking something minimal and seeing what can be gotten out of it. So I'll describe two interesting
things about it. And then we have lots of other work coming in the next, in the next year,
about even simpler systems.
I mean, it's actually crazy.
So the very first thing is this.
The standard sorting, so let's take bubble sort, right?
And all these sorting algorithms, you know,
what you're starting out with is an array of jumbled up digits.
Okay, so integers.
It's an array of mixed up integers.
And what the algorithm is designed to do is to eventually arrange them all into order.
And what it does generally is compare some pieces of that array
and based on which one is larger than which it swaps them around.
And you can imagine that if you just keep doing that
and you just keep comparing and swapping,
then eventually you can get all the digits in the same order.
So the first thing I decided to do,
and this is the work of my student, Taining Zhang,
and then Adam Goldstein on this paper.
This goes back to our original discussion
about putting a barrier between it and its goals.
And the first thing I said, okay, how do we put a barrier in?
Well, how about this?
The traditional algorithm assumes that the hardware is working correctly.
So if you have a seven and then the five, and you tell them to swap, the lines of swap the, swap the five and the seven, and then you go on, you never check, did it swap?
Because you assume that it's reliable hardware.
Okay.
So what we decided to do was to break one of the digits so that it doesn't move.
When you tell it to move, it doesn't move.
We don't change the algorithm.
That's really key.
We do not put anything new in the algorithm that says, what do you do if the damn thing didn't move?
just run it exactly the same way
what happens
turns out something very interesting happens
it still works
it still so it still sorts it
but
it eventually sorts it by moving
all the stuff around the broken number
okay that makes sense
but here's something interesting
suppose we plot at any given moment
we plot the degree of sortedness
of the string as a function of time
if you run the normal algorithm
and sort it's guaranteed to get where it's going.
That's the, you know, it's got a sort and it will always reach the end.
But when it encounters one of the broken digits, what happens is the actual sortedness
goes down in order to then recoup and get better order later.
What it's able to do is to go against the thing that it's trying to do to go around in order
to meet its goal later on.
Now, if I didn't, if, if I showed.
this to a behavior scientist, and I didn't tell them what this, what system was doing is,
they will say, well, we know what this is. This is delayed gratification. This is the ability of a
system to go against its gradient and get what it needs to do. Now imagine two magnets, imagine
you take two magnets and you put a piece of wood between them and they're like this. What the magnet
is not going to do is to go around the barrier and get to its goal. They're not smart enough
to go against their gradient. They're just going to keep doing this. Some animals are smart enough,
right, they'll go around, and the sorting algorithm is smart enough to do that, but the trick is
there are no steps in the algorithm for doing that. You could stare at the algorithm all day long.
You would not see that this thing can do delay gratification. It isn't there. Now, there's two ways
to look at this. On the one hand, you could say, the reductionist physics approach, you could say,
did it, did it follow all the steps in the algorithm? And say, yeah, it did. Well, then,
there's nothing to see here. There's no magic. This is, you know, it does what it does.
It didn't disobey the algorithm.
Right.
I'm not claiming that this is a miracle.
I'm not saying it disobeys the algorithm.
I'm saying it's not failing to sort.
I'm saying it's not doing some sort of crazy quantum thing.
Not saying any of that.
What I'm saying is other people might call it emergent.
What it has is are properties that are not complexity, not unpredictability, not perverse
instantiation, as in sometimes in a life.
What it has are unexpected competencies recognizable by behavioral scientists, meaning
meaning different types of cognition, primitive,
well, we want it primitive, so there you go, it's simple,
that you didn't have to code into the algorithm.
That's very important.
You get more than you start with,
than you put in, you didn't have to do that.
You get these surprising behavioral competencies,
not just complexity.
That's the first thing.
The second thing, which is also crazy,
but it requires a little bit of explanation.
The second thing that we said is,
okay, what if, instead of in the typical sorting algorithm,
you have a single controller top-down.
I'm sort of godlike looking down at the numbers
and I'm swapping them according to the algorithm.
What if, and this goes back to actually the title of the paper
talks about agential data, self-sorting algorithms.
This is back to like who's the pattern and who's the agent, right?
He said, what if we give the numbers a little bit of agency?
Here's what we're going to.
We're not going to have any kind of top-down sort.
Every single number knows the algorithm
and he's just going to do whatever the algorithm says.
So if I'm a five, I'm just going to execute the algorithm
and the algorithm will try to make sure that to my right is the six
and to my left is a four. That's it. That's it. So every digit is, so it's like a
distributed, you know, it's like an ant colony. There is no central planner. Everybody
just does their own algorithm. Okay. We're just going to do that. Once you've done
that, and by the way, one of the values of doing that is that you can simulate biological
processes because in biology, you know, if I have like a frog face and I scramble it
with all the different organs, every, every tissue is going to rearrange itself so that
ultimately you have, you know, nose, eyes, you know, you're going to have, you know,
have an order, right? So you can do that. Okay, fine. But you can do something else cool. Once you've
done that, you can do something cool that you can't do with a standard algorithm. You can make a
chimiric algorithm. What I mean is not all the cells have to follow the same algorithm. Some of them
might follow bubble sort. Some of them might follow selection sort. It's like in biology, what we do
when we make chimeras, we make frog allotles. So frog allotles have some frog celles. They have some
axolotel cells. What is that going to look like? Does anybody know what a frog allotel is going to look
like. It's actually really interesting that despite all the genetics and the developmental
biology, you have the genomes, you have the frog genome, you have the axololid genome. Nobody can tell
you what a frog allot is going to look like, even though you have, this is the, this is
the, back to your question about physics and chemistry. Like, yeah, you can know everything
there is to know about how, you know, how the physics and the genetics work. But the decision
making, right, is like baby axolotles have legs. Tapos don't have legs. It's a frog allotol going to
have legs, right? Can you predict that from, from understanding?
the physics of transcription and all of that.
Anyway, so we made some,
so you see this is like an intersection
of biology, physics, cognition.
So we made chimeric algorithms.
And we said, okay, half the digits randomly.
We assigned them randomly.
So half the digits are randomly doing bubble sort.
Half the digits are randomly doing,
I don't know, selection sort or something.
But that once you choose bubble sort,
that digit is sticking with bubble sort.
It's sticking.
We haven't done the thing where they can swap between,
no, they're sticking to it, right?
You label them and they're sticking to it.
The first thing we learned is that distributed sorting still works.
It's amazing.
You don't need a central planner when every number is doing its whole thing still gets sorted.
That's cool.
The second thing we found is that when you make a chimeric algorithm where actually the
algorithms are not even matching, that works too.
The thing still gets sorted.
That's cool.
But the most amazing thing is when we looked at something that had nothing to do with sorting,
and that is we asked the following question.
We defined Adam Goldstein actually named.
this property, and I think it's well-named. We define the algotype of a single cell. It's not
the genotype. It's not the phenotype. It's the algotype. The algotype is simply this.
What algorithm are you following? Which one are you? Are you a selection sword or a bubble
sort? Right? That's it. There's two algotypes. And we simply ask the following question.
During that process of sorting, what are the odds that whatever algotype you are,
the guys next to you, are your same type? It's not the same as asking how the numbers are
sorted because it's got nothing to do with the numbers.
It's actually, it's just whatever type you are.
It's more about clustering than sorting.
Clustering.
Well, that's exactly what we call it.
We call it clustering.
And at first, so now think of what happens.
And you can see this on that graph, it's the red.
You start off, the clustering is at 50%.
Because as I told you, we assign the alotypes randomly.
So the odds that the guy next you is the same as you is half, 50%.
There's only two algorithms.
In the end, it is also 50%.
Because the thing that dominates is actually the sorting algorithm.
And the sorting element doesn't care what type you are.
You've got to get the numbers in order.
So by the time you're done, you're back to random algotypes because you have to get the number sorted.
But in between, in between, you get some amount of increased, very significant, because look at the control is in the middle, the pink is in the middle.
In between, you get significant amounts of clustering, meaning that certain algotypes like to hang out with their buddies for as long as they can.
Now, here's one more thing, and then I'll kind of give a philosophical significance.
of this. And so we saw this and I said that's nuts because the algorithm doesn't have any provisions for asking what algotype am I, what algotype is my neighbor. If we're not the same, I'm going to move to be next to, like if you wanted to implement this, you would have to write a whole bunch of extra steps. There would have to be a whole bunch of observations that you would have to take of your neighbor to see how he's acting. Then you would infer what algotype he is. Then you would go stand next to the one that seems to have the same algotype as you. You would have to take a bunch of measurements to say, wait, is that guy doing bubbles or is he doing selections? Sorry.
Like, if you want to implement this, it's a whole bunch of algorithmic steps.
None of that exists in our algorithm.
You don't have any way of knowing what algorithm
you are or what anybody else is.
Okay, we didn't have to pay for that at all.
So notice a couple of interesting things.
The first interesting thing is that this was not at all obvious from the algorithm itself.
Album doesn't say anything about algorithms.
Second thing is we paid computationally for all the steps needed to have the numbers sorted, right?
Because we know, you know, you pay for a certain computations.
cost. The clustering was free. We didn't pay for that at all. There were no extra steps. So this gets
back to your other question of how do we know there's a platonic space? And this is kind of like one of
the craziest things that we're doing. I actually suspect we can get free compute out of it. I suspect
that one of the things that we can do here is use these ingressions in a useful way that don't
require you to pay cost, to pay physical cost. Like we know every bit has an energy cost that
you have to get. The clustering was free. Nothing extra was done.
this plot
for people who are just listening
on the X axis
is the percentage
of completion
of the sorting process
and the Y axis
is the sortedness
of the list of numbers
and then also
in the red line
is basically the
degree to which they're clustered
and you're saying
that there's this
unexpected competence
of clustering
and I should comment
that I'm sure
there's a theoretical computer scientist listening to this saying, I can model exactly what
is happening here and prove that the cluster increasing decreases. So taking the specific
instantiation of the thing you've experimented with and prove certain properties of this. But the
point is that there's a more general pattern here of probably other that you haven't discovered
unexpected competencies that emerge from this, that you could get free
amputation out of this thing. So this goes back to the very first thing you said about
physicists thinking that physics is enough. You're 100% correct that somebody could look at this
and say, well, I see exactly why this is happening. We can track, we can track through the
algorithm. Yeah, you can. There's no miracle going on here, right? The hardware isn't doing
some crazy thing that it wasn't supposed to do. The point is that despite following the algorithm
to do one thing, it is also at the same time doing other things that are neither prescribed nor
forbidden by the algorithm. It's the space between the chance and necessity, which is how a lot of
people, you know, see these things. It's that, it's that free space. We don't really have a good
vocabulary for it where the interesting things happen. And to whatever extent, it's doing other
things that are useful, that stuff is, is computationally without extra cost. Now, there's one
other cool thing about this. And this is the beginning of a lot of thinking that I've done about
when this relates to AI and stuff like that, intrinsic motivations. The,
sorting of the digits is what we forced it to do. The clustering is an intrinsic motivation.
We didn't ask for it. We didn't expect it to happen. We didn't explicitly forbid it, but we didn't, you know, we didn't know, we didn't know. This is a great definition of the intrinsic motivation of a system.
So when people say, oh, that's a machine. It only does what you programmed it to do. I, you know, I as a human have intrinsic motivation. You know, I'm creative and I have intrinsic motivation. Machines don't do that. Even even even this minimal
thing has a minimal kind of intrinsic motivation, which is something that is not forbidden by
the algorithm, but isn't prescribed by the algorithm either. And I think that's an important,
you know, third thing besides chance and necessity. Something else that's fun about this is
when you think about intrinsic motivations, think about a child, if you make him sit in math
class all day, you're never going to know what the other intrinsic motivations are that he might be doing,
right? Who knows what else he might be interested in? So,
We, so I wanted to ask this question, I want to say, if we let off the pressure on the sorting, what would happen? Now, that's hard because, because if you mess with the algorithm, now it's no longer the same algorithm. So you don't want to do that. So we did something that I think was kind of clever. We allowed repeat digits. So if you allow repeat digits in your, in your array, you can still have all the fives can still be after all the fours and after all the sixes, but you can keep them as clustered as you want. So this thing at the end where they get.
have to get declustered in order for the sorting to happen, we thought maybe we could let off
the pressure a little bit. If you do that, all you do is allow some extra repeat digits,
the clustering gets bigger. It will cluster as much as you let it. The clustering is what it wants
to do. The sorting is what we're forcing it to do. And my only point is if the bubble sword,
which has been gone over and gone over how many times has these kinds of things that we didn't
see coming, what about the AIs, the language model, everything else, not be. If the bubble,
because, not because they talk, not because they say that they're, you know, have an inner
perspective or any of that, but just from the fact that this thing is even, even the most
minimal system surprises with what happens. And I frankly, when I see this, tell me if this
doesn't sound like all of our existential story, for the brief time that we're here, the universe
is going to grind us into dust eventually. But until then, we get to do some cool stuff that
is intrinsically motivating to us, that is neither forbidden by the laws of physics nor determined
by the laws of physics, but eventually it kind of comes to an end. So I think that aspect of it,
right, that there are spaces, even in algorithms, there are spaces in which you can do other new
things, not just random stuff, not just complex stuff, but things that are easily recognizable
to a behavior scientist. You see, that's the point here. And I think that kind of
intrinsic motivation is what's telling us that this idea that we can carve up the world,
we can say, okay, look, biology is complex, cognition, who knows what's responsible for that,
but at least we can take a chunk of the world aside, and we can cut it off and we can say,
these are the dumb machines. These are just algorithms, whereas we know the rules of biochemistry
don't explain everything we want to know about how psychology is going to go,
but at least the rules of algorithms tell us exactly what the machine is.
are going to do, right? We have, we have some hope that we've, we've carved off a little part of the
world, and everything is nice and simple, and it is exactly what we said it was going to be.
I think that failed. I think it was a good try. I think we have good theories of interfaces,
but even the simplest algorithms have these kinds of things going on. And so that's why I think
something like this is significant. Do you think that there is going to be, in all kinds of systems,
of varying complexity, things that the system wants to do, and things that is forced to do.
So are there these unexpected competencies to be discovered in basically all algorithms and
all systems?
That's my suspicion.
And I think that it is extremely important for us as humans to have a research program
to learn to recognize and predict and recognize.
We make things, never mind something as simple as this.
We make, you know, social structures, financial structures,
Internet of things, robotics, AI, so we make all this stuff.
And we think that the thing we make it do is the main show.
And I think it is very important for us to learn to recognize the kind of stuff that
that sneaks in into the spaces.
What, what?
It's a very counterintuitive notion.
By the way, I like the word emergent.
I hear your criticism and it's a really strong one that emergent is like you toss your hands up,
but I don't know, the process.
but it's just a beautiful word because it is I guess it's a synonym for surprising and I mean this
is very surprising but just because it's surprising doesn't mean there's not a mechanism that explains
it mechanism and explanation are both uh not all they're cracked up to be in the sense that
you know anything you and I do we could we could come up with the most beautiful the theory we
paint a painting anything we do somebody could say well I was watching the biochemistry
and the Schrodinger equation playing out.
And it totally described everything that was happening.
You didn't break even a single law of biochemistry.
Nothing to see here.
Nothing to see.
Right?
Like, okay, you know, consistent with the low-level rules, you can do the same thing here.
You can look at the machine code and say, yeah, this thing is just executing machine code.
You can go further and say, oh, it's quantum foam.
It's just doing the thing that quantum foam does.
You're saying that's what physicists miss.
And I'm not saying they're unaware.
of that. I mean, they're generally a pretty sophisticated bunch. I just think they've picked a
level and they're going to discover what is to be seen at that level, which is a lot. And my point
is the stuff that the behavior scientists are interested in shows up at a much lower level than you
think. How often do you think there's a misalignment of this kind between the thing that a system
is forced to do and what it wants to do? And it's particularly, I'm thinking about various
levels of complexity of AI systems.
So right now we've looked at
like five other systems.
That's a small N, okay?
But just looking at that,
I would find it very surprising
if Bubble Sort was able to do this
and then there was some sort of
valley of death where nothing showed up
and then blah, blah, living things.
Like, I can't imagine that.
I'm going to say that if something,
and we actually have a system that's even simpler than this,
which is one decollular automata
that's doing some weird stuff,
if these things are to be found in this kind of simple system
I mean they just have to be showing up in
in these other more complex AIs and things like that
the only thing what we don't know but we're going to find out
is to what extent there is interaction between these
so I call these things side quests you know it's like
they're like in a game you know whether it's the main thing
you're supposed to do and as long as as you still do it
the thing about this is you have to sort you have to sort
there's no miracle you're going to sort but
But as long as you can do other stuff while you're sorting, it's not forbidden.
And what we don't know is to what extent are the two things linked?
So if you do have a system that's very good at language, are the other, the side quests that it's capable of, do they have anything to do with language whatsoever?
We don't know the answer to that.
The answer might be no, in which case, all of the stuff that we've been saying about language models because of what they're saying, all of that could be a total red herring and not really important.
and the really exciting stuff is what we never looked for.
Or in complex systems, maybe those things become linked.
In biology, they're linked.
In biology, evolution makes sure that the things you're capable of
have a lot to do with what you've actually been selected for.
In these things, I don't know.
And so we might find out that they actually do give the language some sort of leg up,
or we might find that the language is just, you know,
that's not the interesting part.
Also, it is an interesting question of this intrinsic motivation.
of clustering. Is this a property of the particular sorting algorithms? Is this a property of
all sorting algorithms? Is this a property of all algorithms operating on lists, on numbers? How big
is this? So, for example, with LOMs, is it a property of any algorithm that's trying to model
language, or is it very specific to transformers? And that's all to be discovered.
We're doing all that. We're doing all that. We're testing the stuff in other algorithms.
we're looking for, we're developing suites of code to look for other properties.
We, you know, to some extent, it's very hard because we don't know what to look for,
but we do have a behaviorist handbook, which tells you what all kinds of things to look for,
the delay gratification, the, you know, problem solving.
Like, we have all that.
I'll tell you, an end of one of an interesting biological intrinsic motivation because people,
so in like the alignment community and stuff, there's a lot of discussion about,
like, what are the intrinsic motivations going to be of AIs?
what are their goals going to be, right?
Well, what are they going to want to do?
Just as an end of one observation,
anthropots, the very first thing we checked for,
so this is not experiment number 972 out of 1,000 things.
This is the very first thing we checked for.
We put them on a plate of neurons with a big wound through him,
a big scratch.
First thing they did was heal the wound.
Okay, so it's an end of one,
but I like the fact that the first intrinsic motivation
that we noticed out of that system was benevolent and healing.
Like, I thought that was pretty cool.
And we don't know.
maybe the next 20 things we find are going to be some sort of, you know, damaging effect.
I can't tell you that.
But the first thing that we saw was kind of a positive one.
And I don't know, that makes me feel better.
What was the thing you mentioned with the anthropots that they can reverse aging?
There's a procedure called an epigenetic clock where what you can do is look at a particular
epigenetic states of cells and compare to a curve that was built from humans of known age.
you can guess, you can guess what the age is.
Okay, so we can take now, and this is Steve Havrath's work and many other people that
when you take a set of cells, you can guess what their biological age is.
Okay.
So we make the anthropots from cells that we get from human tracheal epithelium.
We collaborated with Steve's group, the Clock Foundation.
We sent them a bunch of cells, and we saw that if you check the anthropots themselves,
they are roughly 20% younger than the cells they come from.
And so that's amazing.
And I can give you a theory of why that happens,
although we're still investigating.
And then I can tell you the implications for longevity and things like that.
My theory for why it happens, I call this age evidencing.
And I think that what's happening here, like with a lot of biology,
is that cells have to update their priors based on experience.
And so I think that they come from an old body.
They have a lot of priors about how many years they've been around and all that.
But their new environment screams, I'm an embryo.
Basically, there's no other cells around.
You're being bent into a pretzel.
They actually express some embryonic genes.
They say, you're an embryo.
And I think it's not enough new evidence to roll them like all the way back,
but it's enough to update them to about 28% back.
Yeah, so it's similar to like when older adult gives birth to a child.
So you're saying you can just fake it until you make it with age?
Like the environment convinces the cell that is young?
Well, first of all, yes, yes.
And that's my hypothesis.
And we have a whole bunch of research being done on this.
There was a study where they went into an old age home.
and they redid the decor like 60s style when all these folks were really young and they found
all kinds of improvements in blood chemistry and stuff like that because they say it was sort of
mentally taking them back to when you know when they were the way they were at that time
I think this is a basal version of that that basically if if you're finding yourself in an embryonic
environment what's more plausible that you're young or or what you know like I think I think this is
this is the basic feature of biology is to update priors based on experience.
Do you think that's actually actionable for longevity?
Like you can convince cells that they're younger and thereby extend the lifespan?
This is what we're trying to do.
Yeah.
Could it be as simple as that?
Why, that's not, well, I'm not claiming it's simple.
That is in no way simple.
But because, because again, you have to, all of this, all of the regenerate medicine stuff that we do balances on
one key thing, which is learning to communicate to the system.
We have to, if you're going to convince that system, you know, so when we make a gut tissue
into an eye, you have to convince those cells that they're priors about, we are, we are gut
precursors, those priors are wrong, and you should adopt this new worldview that you're going to be,
you know, you're going to be an eye. So being convincing and figuring out what,
what kind of messages are convincing to two cells and how to speak the language and how to make
them take on new, new beliefs, literally, is at the root of all of these future advances in birth
defects and regenerate medicine and cancer. And that's what's going on here. So I'm not saying it
simple, but I can see the, I can see the path. Going back to the platonic space, I have to ask if
if our brains are indeed thin client interfaces to that space, what does that mean for our mind?
Like, can we upload the mind, can we copy it, can we ship it over to other planets?
Like, how, what does that mean for exactly where the mind is stored?
Yeah, a couple of things.
So we are now beyond anything that I can say with any certainty, this is total, total conjecture.
Okay, so because we don't know yet.
The whole point of this is we actually don't really understand very well the relationship
between the interface and the thing.
And the thing you're currently working on is to map this space.
Correct, and we are beginning to map it, but you know, this is a massive effort.
So a couple of a couple of conjectures here.
One is that I strongly suspect that the majority of what we think of as the mind is the pattern in that space.
Okay. And one of the interesting predictions from that model, which is not a prediction of modern neuroscience, is that there should be cases where there's very minimal brain and yet normal IQ function.
This has been seen clinically. We just, Karina Kaufman and I reviewed this in a paper recently, a bunch of cases of humans where there's very little brain tissue and they have normal or sometimes above normal intelligence. Now, things are not simple because that obviously doesn't happen all.
the time, right? Most of the time that doesn't happen. So, so what's going on? We don't understand.
But it is a very curious thing that is not a prediction of, I'm not saying, I'm not saying it can't,
you know, you can take modern neuroscience and sort of bend it into a pretzel to accommodate it.
You can say, well, there are these, you know, kind of redundancies and things like this, right?
So you can accommodate it, but it doesn't predict this. So, uh, there, there are these incredibly
curious cases. Now, do I think you can copy it? No. I don't think you.
can because what you're going to be copying is the, is the interface, the front end, the brain
or the whatever.
The action is actually the pattern in the platonic space.
You're going to be able to copy that, I doubt it.
But what you could do is produce another interface through which that particular pattern
is going to come through.
I think that's probably possible.
I can't say anything at this point about what that would take, but my guess is that that's possible.
Is your guess, your gut, is that that problem?
process, if possible, is different than copying.
Like, it looks more like creating a new thing versus copying.
For the interface. So if you could, so, so, so, so here's my prediction for Star Trek
transporter. For whatever reason, right now, your brain and body are very attuned and attractive
to a particular pattern, which is your set of psychological propensities. If we could, if we could
rebuild that exact same thing somewhere else, I don't see any reason why that same pattern
wouldn't come through it the same way it comes through this one. That would be a guess,
you know? So I think what you will be copying is the physical interface and hoping to
maintain whatever it is about that interface that was appropriate for that pattern. We don't really
know what that is at this point. So when we've been talking about mind, in this particular case,
is the most important to me
because I'm a human.
Does self come along with that?
This
the feeling
like this mind belongs to me.
Yeah.
Does that come along with all minds?
The subjective,
not the subjective experience.
The subjective experience is important too,
consciousness, but like the ownership.
I suspect so.
and I think so because of the way we come into being.
So one of the things that I should be working on
is this paper called Booting Up the Agent,
and it talks about the very earliest steps
of becoming a being in this world.
Kind of like you can do this for a computer, right?
And before you switch the power on,
it belongs to the domain of physics, right?
It obeys the laws of physics.
You switch the power on some number of, what, nanoseconds,
microseconds, I don't know, later,
you have a thing that, oh, look, it's taking instructions off the stack and doing them, right?
So now it's executing an algorithm.
How did you get from physics to executing an algorithm?
Like, what was happening during the boot up exactly before it starts to run code or whatever, right?
And so we can ask that same question in biology.
What are the earliest steps of becoming a being?
Yeah, that's a fascinating question.
Through embryogenesis, at which point is the, are you booting on?
Yeah, yeah, yeah, yeah.
Exactly.
Do you have a hope of an answer to that?
Well, I think so.
I think so in two ways.
The first thing is just physically what happens.
So I think that your first task as a being, and again, I don't think this is a binary thing.
I think this is a positive feedback loop that sort of cranks on up and up.
Your first task as a being coming into this world is to tell a very compelling story to your parts.
As a biological, you are made of a genital parts.
Those parts need to be aligned, literally, into a goal they have no comprehension of.
If you're going to move through anatomical space by means of a bunch of cells which only know physiological and, you know, metabolic spaces and things like that, you are going to have to develop a model and give them, bend their action space.
You're going to have to deform their option space with signals, with behavior-shaping cues, with rewards and punishments, whatever you got.
Your job as an agent is ownership of your parts, is alignment of your parts.
I think that fundamentally is going to give rise to this ability.
Now, that also means having a boundary saying, okay, this is the stuff I control.
This is me.
This other stuff over here is outside world.
I have to figure out.
You don't know where that is, by the way.
You have to figure it out.
And in embryogenesis, it's really cool.
you can as a as a as a as a as a grad student I used to do this experiment with duck embryos with a flat blast it is you can take a needle and put some scratches into it and every every island you make for a while until they heal up thinks it's the only embryo there's nothing else around so it becomes an embryo and eventually you get twins and triplets and quadruplets and things like that but each one of them at the border you know they're joined well where do i end and where does where does he begin you have to you know you have to know what your borders are so um that and
action that action of aligning your parts and coming to be this, this, I mean, I'm even going to say
this emergence, we just not have a good vocabulary for it, this, this emergence of a model that
aligns all the parts is really critical to keep that thing going. There's something else that's
really interesting. And I was thinking about this in the context of, of, of, of, like, you know,
these beautiful kind of ideas, you know, that there's this amazing thing that we found, and this is,
This is largely the work of Federico Pagosi in my group.
So a couple of years ago, we saw that networks of chemicals can learn.
They have five or six different kinds of learning that they can do.
And so what I asked them to do was to calculate the causal emergence of those networks while they're learning.
And what I mean by that is this, if you're a rat and you learn to press a lever and get a reward,
there's no individual cell that had both experiences.
The cells at your paw have touched the lever,
the cells in your gut got the delicious reward.
No individual cell has that both experiences.
Who owns that associative memory?
Well, the rat.
So that means you have to be integrated, right?
If you're going to learn associative memories from different parts,
you have to be an integrated agent that can do that.
And so we can measure that now with metrics of causal emergence like phi
and things like that.
So we know that in order to learn,
you have to have significant
phi, but I wanted to ask the
opposite question, what does learning
do for your phi level? Does it do
anything? For your degree of being
an agent that is more than the sum of its parts?
So we train the networks,
and sure enough, some of them, not all of them,
but some of them, as you train them,
their phi goes up.
And so basically, what we were able to find
is that
there is this
positive feedback loop
between every time you learn something
you become more of an integrated agent
and every time you do that
it becomes easier to learn
and so it's this
it's a virtuous cycle
it's a virtuous cycle
it's an asymmetry that points
upwards for agency and intelligence
and now back to our platonic space stuff
where does that come from?
It doesn't come from evolution
you don't need to have any evolution for this
evolution will optimize the crap out of it for sure
but you don't need evolution to have this
doesn't come from physics
it comes from the rules of information
to causal information
theory and the behavior of networks.
The mathematical objects.
It has, it's, this is not anything that, uh, that was, you know, was, was, was, was given to
you by physics or by a history of selection.
It's a free gift for math.
And the, and, and, and, and, and, and, and, and, and, and, and, uh, free, uh,
gift, uh, locked together into a spiral that, I think causes simultaneously arise
in intelligence and arise in, uh, collective agency.
And I think that's just, uh, you know, that's been, you know, just, just, just amazing to think
about. Well, that free gift from, I think, is extremely useful in biology. When you have small
entities, forming networks, hierarchy that builds more and more complex organisms. That's obvious.
I mean, this speaks to embryogenesis, which I think is one of the coolest things in the universe.
And in fact, you acknowledge its coolness in Ingressing Minds paper, writing, quote,
most of the big questions of philosophy are raised by the process of embryogenesis,
right in front of our eyes.
A single cell multiplies and self-assembles into a complex organism,
with order on every scale of organization and adaptive behavior.
Each of us takes the same journey across the Cartesian cut,
starting off as a quiescent human oocyte,
a little blob thought to be well described by chemistry and physics.
Gradually, it undergoes metamorphosis and eventually becomes a mature human with hopes, dreams,
and a self-reflective metacognition that can enable it to describe itself as not a machine.
It's more than its brain, body, and underlying molecular mechanisms and so on.
What in all of our discussion can we say, as the clear intuition,
how it's possible to take a leap from a single cell to a fully functioning organism
full of dreams and hopes and friends and love and all that kind of stuff
in everything we've been talking about which has been a little bit technical
like how how do we understand because that's one of the most magical things the universe
is able to create perhaps the most magical from simple physics and chemistry create this
us too talking about ourselves.
I think we have to keep in mind
that physics and chemistry are not real things.
They are lenses that we put on the world,
that they are perspectives where we say
we are, for the time being,
for the duration of this chemistry class or career or whatever,
we are going to put aside all the other levels
and we're going to focus on this one level.
And that what is fundamentally going to,
on during that process is an amazing positive feedback loop of collective intelligence for
the interface. It's the physical interface is scaling. It's the cognitive light cone that
it can support. So it's going from a molecular network. The molecular network can already do
things like Pavlovian conditioning. You don't start with zero. When you have a simple molecular
network, you are already hosting some patterns from the platonic space that look like Pavlovian
conditioning. You've already got that and starting out.
That's just a molecular network.
Then you become a cell, and then you're many cells, and now you're navigating anatomical
morphos space, and you're hosting all kinds of other patterns.
And eventually you, and I think, again, I think there's, and this is like what, you know,
all the stuff that we're trying to work out now, there's a consistent feedback between
the ingressions you get and the ability to have new ones, which again, I think it's this
like positive feedback cycle, where the more of these free gifts you pull down, they allow you
physically to develop to a ways where, oh, look, now, now, now we're suitable for more and higher
ones. And this continuously goes and goes and goes until, you know, until you're able to pull
down a full human set of behavioral capacities. What is the mechanism of such radical scaling
of the cognitive cone? Is it just this kind of, the same thing that you were talking about
with the network of chemicals being able to learn? I'll give you two mechanisms that we found.
But again, just to be clear, these are mechanisms of the physical interface.
what we haven't gotten is a mature theory of how they map onto the space.
That's just like just beginning.
But I'll tell you what the physical side of things look like.
The first one has to do with stress propagation.
So imagine that you've got a bunch of cells and there's a cell down here that needs to be up there.
All of these cells are exactly where they need to go.
So they're happy.
Their stress is low.
This cell, now let's imagine stress is basically a...
it's a it's a it's a physical implementation of the error function it's basically the amount of stress is basically the delta between where you are now and where you need to be not necessarily in physical position this could be an anatomical space and physiological space and in transcriptional space whatever right it's just the delta from your set point so so you're stressed out but these guys are happy they're not moving you can't get past them now imagine if what you could do is you could leak your stress whatever your stress molecule is and the cool thing is that evolution has actually conserved these highly
so these are all, and we're studying all of these things,
they're actually highly concerned.
If you start leaking your stress molecules,
then all of this stuff around here is starting to get stressed out.
When things get stress, starting to get stressed out,
their temperature, not physical temperature,
but in the sense of like simulated annealing or something, right?
Their ability to, their plasticity goes up
because they're feeling stressed.
They need to relieve that stress.
And because all the stress molecules are the same,
they don't know it's not their stress.
They are equally irritated by them as if it was their own stress.
So they become a little more plastic.
They become ready to kind of, you know, adopt different fates.
You get up to where you're going and then everybody's stress can drop.
So notice what can happen by a very simple mechanism.
Just be leaky for your own stress.
My problems become your problems.
Not because you're altruistic.
Not because you actually care about my problems.
There's no mechanism for you to actually care about my problems.
But just that simple mechanism means that far away regions are now responsive to the needs of other regions,
such that complex rearrangements and things like that can happen.
It's alignment of everybody to the same goal
through this very dumb, simple stress sharing thing.
Via leaky stress, right?
So there's another one,
there's another one which I call memory anonymization.
So imagine here are two cells,
and imagine something happens to this cell,
and it sends a signal over to this cell.
Traditionally, you send a signal over,
this cell receives it.
It's very clear that it came from outside.
So this cell can do many things.
It could ignore it.
It could take on the information.
It could just ignore it.
It could reinterpret.
It could do whatever.
But it's very clear that came from outside.
Now imagine the kind of thing that we study, which is called gap junctions.
These are electrical synapses that could directly link the internal millionaires of two cells.
If something happens to this cell, let's say it gets poked and there's a calcium spike or something.
That propagates through the gap junction here.
This cell now has the same information.
but this cell has no idea, wait a minute,
is that my memory or is that his memory?
Because it's the same, right?
It's the same, it's the same components.
And so what you're able to do now is to have a mind melt.
You can have a mind melt between the two cells
where nobody's quite sure whose memory it is.
And when you share memories like this,
it's harder to say that I'm separate from you.
If we share the same memories, we're kind of,
and I don't mean every single memories, right?
So they still have some identity.
But to a large extent, they have a little bit of a mind melt.
And there's many complexities.
you can lean on top of it.
But what it means is that if you have a large group of cells,
they now have joint memories of what happened to us,
as opposed to you know what happened to you
and I know what happened to me.
And that enables a higher cognitive light cone
because you have greater computational capacity,
you have a greater area of concern of things you want to manage.
I don't just want to manage my tiny little memory states
because I'm getting your memories.
Now I know I've got to manage this whole thing.
So both of these things end up scaling
the size of things you care about
and that is a major ladder
for cognition. It's scale
the degree of, you know, the size of
concern that you have. It'd be fascinating
to be able to engineer that scaling.
Probably applicable to AI
systems. How do you rapidly
scale the cognitive
cone? Yeah, we have
some collaborators in a company called
Softmax that we're working with to do
some of that stuff. In biology,
that's our cancer
therapeutic, which is that what you
see in cancer literally is cells electrically disconnect from their neighbors when they were part
of a giant memory that was working on making a nice organ well now they can't remember any of that
now they're just amoebas and the rest of the body is just external environment and what we found
is if you then physically reconnect them to the to the network you don't have to fix the DNA you
don't have to kill the cells with chemo you can just reconnect them and they go back to because
they're now part of this larger collective they go back to what they were working on
And so, yeah, I think we can intervene at that scale.
Let me ask you more explicitly on the search, the sooty, the search for unconventional
terrestrial intelligence, what do you hope to do there?
How do you actually find, try to find unconventional intelligence all around us?
First of all the earth, there is all kinds of incredible intelligence we haven't yet
discovered. I mean, guaranteed, we've already seen in our own bodies, and I don't just mean
that we are host to a bunch of microbiome or any of that. I mean that your cells, and we have
all kinds of work on this, every day they traverse these alien spaces, 20,000 dimensional
spaces and other spaces. They solve problems. I think they suffer when they fail to meet their
goals. They have stress reduction when they meet their goals. These things are inside of us. They are
all around us, I think that we are, we have an incredible degree of mind blindness to all of the
very alien kinds of minds around us. And I think that, you know, looking for aliens off,
off the earth is, is awesome and whatever. But if we can't recognize the ones that are inside
our own bodies, what, what chance do we have to really, you know, to really recognize the
ones that are out there? Do you think that could be a measure like IQ for, uh, for mind,
What would it be not mindedness, but intelligence that's broadly applicable to the unconventional minds, that's generalizable to unconventional minds, where we could even quantify like, holy shit, this discovery is incredible because it has this IQ.
Yeah, yes and no.
The yes part is that what, as we have shown, you can take existing IQ metrics, I mean, literally.
existing kinds of ways
that people used to measure
intelligence of animals and humans or whatever
and you can apply them to very weird things.
If you have the imagination to make the interface,
you can do it and we've done it
and we've shown creative problem solving
and all this kind of stuff.
So yes.
However, we have to be humble about these things
and recognize that all of those IQ metrics
that we've come up with so far
were derived from an end of one example
of the evolutionary lineage here on Earth.
And so we are probably missing
a lot of them. So I would say we have
plenty to start. We have so much
to start with. We could keep, you know, tens of thousands
of people busy just testing things
now, but we have to be aware
that we're probably missing a lot of important
ones. What do you think has more
interesting, intelligent
unconventional minds
inside our body,
the human body,
or like we were talking off Mike,
the Amazon jungle, like
nature, natural systems
outside of
like the sophisticated biological systems
we're aware of.
Yeah.
We don't know because it's really hard
to do experiments on larger systems.
It's a lot easier to go down than it is to go up.
But my suspicion is, you know,
like the Buddhists say,
innumerable sentient beings.
I think by the time you get to that degree of infinity,
it kind of doesn't matter to compare.
I suspect there's just massive numbers of them.
Yeah, I think it really matters
which kind of systems are amenable.
to our current methods of scientific inquiry.
I mean, I spent quite a lot of hours just staring at ants when I was in the
I was on.
And it's such a mysterious, wonderful collective intelligence.
I don't know how amenable it is to research.
I've seen some folks try.
You could simulate you can, but I feel like we're missing a lot.
I'm sure we are.
But one of my favorite things about that kind of work, have you seen that there's at least
three or four papers showing that ant colonies fall for the same?
visual illusions that we fall for?
Not the ants, the colonies.
The colonies.
So if you lay out food in particular patterns,
they'll do things like complete lines that aren't there
and like all the same shit that we fall for.
They fall.
So, you know, I don't think it's hopeless,
but I do think that we need a lot of work to develop tools.
Do you think all the tooling that we develop
and the mapping that we've been discussing
will help us do the setty part,
finding aliens out there?
I think it's essential.
I think it's essential.
We are so parochial in what we expect to find in terms of life that we are going to be just completely missing a lot of stuff.
If we can't even agree on, never mind definitions of life, but, you know, what's actually important, I let a paper recently where I asked, whatever, 65 or so, modern working scientists for a definition of life.
and we had so many different definitions
across so many different dimensions.
We had to use AI to make a morphist space out of it.
And there was zero consensus
about what actually is important, you know?
And if we're not good at recognizing it here,
I just don't see how we're going to be good
at recognizing it somewhere else.
So given how miraculous life is here on Earth,
so it's clear to me that we have so much more work to do.
That said...
Would that be exciting to you if we find life on other planets in the solar system?
Like, what would you do with that information?
Or is that just another life form that we don't understand?
I would be very excited about it because it would give us some more unconventional embodiments to think about, right?
A data point that's pretty far away from our existing data points, at least in this solar system.
So that'd be cool.
I'd be very excited about it.
But I must admit that my level of, my, my set point for surprise has been pushed so high at this point that it would have to, you know, it would have to be something really weird to make me shocked.
I mean, I, the things that we see every day is just, yeah.
I think you've mentioned in a few places that, like, you wrote that the Ingressing Minds paper is not the weirdest thing you plan to write.
Yeah.
How weird are you going to get?
Can you hit, maybe a better question is like,
in which direction of weirdness do you think you will go in your life?
In which direction of the weird Overton window are you going to expand?
Yeah, well, the kind of background to this is simply that
I've had a lot of weird ideas for many, many decades,
And my general policy is not to talk about stuff until it becomes actionable.
And the amazing thing, I mean, I'm really kind of shocked, is that in my lifetime, the empirical work, like, I really didn't think we would get this far.
And the knob, I have this like mental, mental knob of what percentage of the weird things I think do I actually say in public, right?
And every few years, when the empirical work moves forward, I sort of turn that knob a little, right, as we keep going.
So I have no idea if we'll continue to be that fortunate or how long I can keep doing this or however, like, I don't know.
But just to give you a direction for it, it's going to be in the direction of what kinds of things do we need to take seriously as other beings with which to relate to.
So I've already pushed it, you know, so like we knew brainy things and then we said, well, it's not just brains.
And then we said, well, it's not just, so, you know, it's not just in physical space and it's not just biologicals and it's not just complexity.
There's a couple of other steps to take that I'm pretty sure are there, but we're going to have to do the actual work to make it actionable before, you know, before we really talk about it.
So that direction.
I think it's fair to say you're one of the more unconventional humans, scientists out there.
So the interesting question is, what's your process of idea generation?
What's your process of discovery?
You've done a lot of really incredibly interesting, like you said, actionable,
but interesting out there ideas that you've actually engineered with Xenobus.
and entrobots, these kinds of things.
Like, when you go home tonight, go to the lab,
what's the process, empty sheet of paper,
when you're thinking through it?
Well, the mental part is a lot of it,
much like, funny enough, much like making xenobots.
You know, we make xenobots by releasing constraints, right?
We don't do anything to them.
We just release them from the constraints they already have.
And then we say, so a lot of it is,
releasing the constraints that mentally have been placed on us.
And part of it is my education has been a little weird because I was a computer scientist first
and only later biology.
And so by the time I heard all the biology things that we typically just take on board,
I was already a little skeptical and thinking a little differently.
But a lot of it comes from releasing constraints.
And I very specifically think about, okay, this is what we know?
What would things look like if we were wrong?
Or what would it look like if I was wrong?
what are we missing? What is our worldview specifically not able to see, right? Whatever
model I have. Or another way I often think is, uh, I'll take two things that are considered to be
very different things. And I'll say, let's just imagine those as two points on a continuum. What,
what does that look like? What does the middle of that continuum look like? What's the,
what's the, what's the symmetry there? What's the, what's the parameter that I can, you know,
what's the knob I can turn from together from here to there? So those kinds of, I look for
symmetries a lot. I'm like, okay, this thing is like that way in what way? What's the, what's the,
what's the fewest number of things I would have to move to make this map onto that, right?
So, so these, so those are, you know, those are kind of mental, mental tools.
The physical process, um, for me is basically, uh, I mean, obviously I'm, I'm fortunate to have a lot
of discussions with very smart people. And so, so in my, in my group, there's something,
I've hired some amazing people. So we, of course, have a lot of discussions and some stuff comes
out of that. My process is, uh, I do pretty much, pretty much every morning, um, or I, I'm outside for
sunrise and I walk around in nature, this is not really anything, anything better than
as inspiration, right, than nature. I do, I do photography and I find that it's a good
meditative tool because it keeps your hands and brain just busy enough. Like, you don't
have to think too much, but, you know, you're sort of twiddling and looking and doing some
stuff. And it keeps your brain off of the linear, like, logical, like careful train of thought
enough to release it so that you can ideate a little more while, while your hands are busy.
So it's not even the thing you're photographing.
It's the mechanical process of doing the photography.
And mentally, right?
So because I'm not walking around and thinking,
okay, let's see.
So for this experiment, we got to, you know,
I got to get this piece of equipment and this, like,
that goes away.
And it's like, okay, what's the lighting and what am I looking at?
And during that time, when you're not thinking about that other stuff,
then they say, well, yeah, I got to get a notebook.
And I'm like, look, this is what we need to do.
So that, that kind of stuff.
And the actual idea of writing down stuff is,
notebook is a computer.
Are you super organized thinking or is it just like random words here and there with drawings?
And also like what is the space of thoughts you have in your head?
Is this sort of amorphous things that aren't very clear?
Are you visualizing stuff?
Is there something you can articulate there?
I tend to leave myself a lot of voicemails.
Because as I'm walking around, I'm like, oh, man, this idea.
And so I'll just call my office and leave myself a voicemail for later to transcribe.
I don't have a good enough memory to remember any of these things.
And so what I keep is a mind map.
So I have an enormous mind map.
One piece of it hangs in my lab so that people can see like these are the ideas.
This is how they link together.
Here's everybody's project.
I'm working on this.
How the hell does this attach to everybody else so they can track it?
The thing that hangs in the lab is about nine feet wide.
It's a silk sheet.
and I, you know, it's, it's out of date within a couple of weeks of my, of my printing it,
because new stuff keeps moving around.
And then, and then there's more that isn't, you know, isn't for anybody else's view.
But, yeah, I try to be very organized because otherwise, otherwise I forget.
So, so everything is in a mind map.
Things are in manuscripts.
I have something like at the right now, probably 163, 62 open manuscripts that are in
process of being written at various stages.
And when things come up, I stick.
I'm in the right manuscript in the right place so that when I'm finally ready to finalize,
then I'll put words around it, whatever, but there's like outlines of everything.
So I try to be organized because I can't, I don't have to, you know.
So there's a wide front of manuscripts of work that's being done,
and it's continuously like pushing towards completion, be not clear where, what's going to be
finished when and how.
I mean, that's, yes, but that's just the, that's just the theoretical philosophical stuff.
the empirical work that we're doing with in the lab.
I mean, those are, we know exactly, you know.
It's more focused.
There's a specific set of life.
This is, you know, anthropot aging.
This is limb regeneration.
This is the new cancer paper.
This is whatever.
Yeah, those things are very linear.
Where do you think ideas come from when you're taking a walk that eventually materialized
in a voicemail?
Where is that?
What is that from you?
Is that, you know, a lot of really, some of the most interesting people feel like they're
channeling from somewhere else. I mean, I hate to bring up the platonic space again, but,
but, I mean, if you talk to any creative, that's basically what they, what they'll tell
you, right? And, and certainly that's been my experience. So I feel, I feel like it's a,
the way, the way it feels to me is a collaboration. So collaboration is, I, I, I need to
bust my ass and be, be prepped in, in one, A, to, to work hard to be able to recognize the idea
when it comes, and B, to actually have an outlet for it so that when it does come, we have a
lab and we have people who can who can help me do it and then we can actually get it out right so that's
that's my part is you know be up at 4 30 a.m. doing your thing and be ready for it but the other side of
the collaboration is that yeah when you do that like amazing ideas come and you know to say that
it's me i don't think would be would be right uh you know i think it's it's definitely coming from
from other places what advice would you give to scientists pg students grad students young scientists
they're trying to explore the space of ideas,
given the very unconventional,
non-standard, unique set of ideas
you've explored in your life and career.
Let's see.
Well, the first and most important thing I've learned
is not to take too much advice,
and so I don't like to give too much advice,
but I do have one technique that I found very useful.
And this isn't for everybody,
but there's a specific demographic.
because a lot of unconventional people reach out to me
and I try to respond and help them and so on.
This is a technique that I think is useful for some people.
How do I describe it?
You need to, it's the act of bifurcating your mind.
And you need to have two different regions.
One region is the practical region of impact.
In other words, how do I get my idea out into the world
so that other people recognize it.
What should I say?
What are people hearing?
What are they able to hear?
How do I pivoted?
What parts do I not talk about?
Which journal am I going to publish?
Is it time now?
Do I wait two years for this?
Like all the practical stuff
that is all about how it looks from the outside, right?
All the stuff that I can't say this
or I should say this differently
or this is going to freak people out
or this is, you know,
this community wants to hear this
so I can pivot it this way.
Like all that practical stuff.
It's got to be there.
Otherwise, you're not going to be in a position
to follow up
of your ideas. You're not going to have a career. You're not going to have resources to do
anything. But it's very important that that can't be the only thing. You need another part of your
mind that ignores all that shit completely because this other part of your mind has to be pure.
It has to be, I don't care what anybody else thinks about this. I don't care whether this is
publishable, describable. I don't care if anybody gets it. I don't care if anybody thinks it's
stupid. This is what I think and why and give it space to sort of grow, right? And if you try to
mush them, if you try to mush them together, I found that impossible.
because the practical stuff poisons the other stuff.
If you're too much on the creative end,
you can be an amazing thinker,
it just nothing ever materializes.
But if you're very practical,
it tends to poison the other stuff
because the more you think about how to present things
so that other people get it,
it constrains and it bends how you start to think.
And, you know,
what I tell my students and others is
there's two kinds of advice.
there's very practical specific things like somebody says well you forgot this control or this isn't
the right method or you shouldn't be that stuff is gold and you should take that very seriously
and you should use it to improve your craft right and that's like super important but then there's
the meta advice where people like that's not a good way to think about it don't work on this this isn't
that that stuff is is garbage and even very successful people often give very constraining
terrible advice. Like one of my, one of my reviewers in a paper years ago said, I love this Freudian slip.
He said he's going to give me constrictive criticism, right? And that's exactly what he gave
me, was constrictive criticism. I was like, that's awesome. That's a great typo. It was very true.
I mean, that second the bifurcation of the mind is beautifully put. I do think some of the most
interesting people I've met are sometimes, uh, fall short on the, on the normy side, on the practical
how do I, having the emotional intelligence of how do I communicate this with people that
have a very different worldview that are more conservative and more conventional and more
kind of fit into the norm. You have to be able to have the skill to fit in. And then you have to,
again, beautifully put, be able to shut that off when you go on your own and think. And having
two skills is very important. I think a lot of radical thinkers think that they're sacrificing
something by learning the skill of fitting in.
But I think if you want to have impact,
if you want ideas to resonate and actually lead to,
first of all,
be able to build great teams that help bring your ideas to life.
And second of all, for your ideas to have impact
and to scale and to resonate with a large number of people,
you have to have that skill.
And those are very different.
Those are very different.
Let me ask a ridiculous question.
You already spoke about it,
but what to you is one of those beautiful ideas
that you've encountered in your various explorations?
Maybe not just beautiful, but one that makes you happy
to be a scientist, to be able to be curious humans exploring ideas.
I mean, I must say that, you know,
I sometimes think about these ingressions from this space
as a kind of steganography, you know?
So steganography is when you hide data and messages
within the bits of another pattern that don't matter, right?
And the rule of steganography is you can't mess up the main thing,
you know, it's a picture of a cat or whatever.
You've got to keep the cat,
but if there's bits that don't matter,
you can kind of stick stuff.
So I feel like all these ingressions
are a kind of universal steganography,
that there's this like, these patterns seep into everything,
everywhere they can,
and they're kind of shy,
meaning that they're very subtle, not invisible.
If you work hard, you can catch them,
but they're not invisible, but they're hard to see.
And the fact that,
the fact that I think they also affect quote-unquote machines,
as much as they certainly affect living organisms,
I think is incredibly beautiful.
And I personally am happy to be part of that same spectrum
and the fact that that magic is sort of applicable to everything.
a lot of people find that extremely disturbing and that's that's some of the some of the hate mail I get is like yeah we were with you you know on the majesty of life thing until you got to the fact that machines get it too and now now like terrible right here you know kind of devaluing the the majesty of life and I don't know I the idea that we're now catching these patterns and we're able to do meaningful research on the on the interfaces and all that is just to me absolutely beautiful and that it's all one spectrum I think to me is is is
amazing. I'm I'm enriched by it. I agree with you. I think it's incredibly beautiful. I lied. There's
a more ridiculous question. It seems like we are progressing towards possibly creating a super
intelligence system. And AGI and ASI, if I had one, gave it to you, put you in the room,
what would be the first question you ask it? Maybe the first set of questions. Like there's so many
topics that you've worked on and interested in, is there a first question that you really
just, if you can get an answer, solid answer, well, the first thing I would ask is, how much
should I even be talking to? For sure, because it's not clear to me at all that getting somebody
to tell you an answer in the long run is optimal. It's the difference between when you're a kid,
learning math and having an older sibling that'll just tell you the answers, right?
Like sometimes it's just like, come on, just give me the answer.
Let's move on with this, you know, cancer protocol and whatever.
Like, great.
But in the long run, the process of discovering it yourself, how much of that are we willing to
give up?
And by getting a final answer, how much have we missed of stuff we might have found along the way?
Now, I don't know what the thing is, you know, I don't think it's correct to say, don't do that at
all, you know, take, take the time in all the blind alleys and, like, that may not be optimal
either, but we don't know what the optimal is. We don't know how much we should be
stumbling around versus having somebody tell us the answer. That's actually a brilliant question
to ask AGI then. I mean, if it's really, if it's really an AGI. Yeah, if it's really an AGI,
I'm like, tell me what the balance is. Like, how much should I be talking to you versus stumbling
around in the lab and making all my, you know, all my own mistakes? It was at 7030,
you know, 1090, I don't know. So that would be, that would be the first. And then the
AJ, I will say you shouldn't be talking to me.
It may well be.
It may say, what the hell did you make me for in the first place?
You guys are screwed.
Like, that's possible.
Yeah.
You know, the second question I would ask you is, what's the answer I should be?
What's the question I should be asking you that I probably am not smart enough to ask you?
That's the other thing I would say.
This is really complicated.
That's a really, really strong question.
But again, there, the answer might be.
you wouldn't understand the question
it proposes most likely.
So I think for me,
I would probably,
assuming you can get a lot of questions,
I would probably go for questions
where I would understand the answer.
Like it would uncover some small mystery
that I'm super curious about.
Because if you ask big questions,
like you did,
which is really strong questions,
I just feel like I wouldn't understand the answer.
If you ask it,
what question should I be asking you?
It would probably say something like,
you'll say something like
what is the shape of the universe
and you're like why is that important
right you'll be very confused by the question
and proposes yeah
I would probably want to
it would just be nice for me to know
straight up first question
how many living intelligent alien civilizations
are in the observable universe
yeah that would just be nice
yeah to know if is it zero
or is it a lot
I just want to know that
And then, unfortunately, it might answer.
It might be a, give me a Michael Levin answer.
That's what I was about to say, is that my guess is, it's going to be exactly the problem you said, which is going to say, oh, my God, I mean, right in this room, you got, you know, and like, oh, man.
Yeah, yeah, yeah.
Everything you need to know about alien civilizations is right here in this room.
In fact, it's inside your own body.
Thank you, for starters.
AGI.
Thank you.
All right, Michael, one of my favorite scientists, one of my favorite humans.
Thank you for everything you do in this world.
Thank you so much.
Truly, truly fascinating and work.
And keep going for all of us.
Thank you so much.
It's great to see you.
It's always a good discussion.
Yeah, thank you so much.
I appreciate it.
Thank you.
Thanks for listening to this conversation with Michael Levin.
To support this podcast, please check out our sponsors in the description where you can also find links to contact me, ask questions, get feedback, and so on.
And now, let me leave you with some words from Albert Einstein.
The most beautiful thing we can experience is the mysterious.
It is the source of all true art and science.
Thank you for listening.
I hope to see you next time.
Thank you.