Lex Fridman Podcast - #124 – Stephen Wolfram: Fundamental Theory of Physics, Life, and the Universe
Episode Date: September 16, 2020Stephen Wolfram is a computer scientist, mathematician, and theoretical physicist. This is our second conversation on the podcast. Please check out our sponsors to get a discount and to support this ...podcast: - SimpliSafe: https://simplisafe.com/lex - Sun Basket, use code LEX: https://sunbasket.com/lex - MasterClass: https://masterclass.com/lex If you would like to get more information about this podcast go to https://lexfridman.com/podcast or connect with @lexfridman on Twitter, LinkedIn, Facebook, Medium, or YouTube where you can watch the video versions of these conversations. If you enjoy the podcast, please rate it 5 stars on Apple Podcasts, follow on Spotify, or support it on Patreon. Here's the outline of the episode. On some podcast players you should be able to click the timestamp to jump to that time. OUTLINE: 00:00 - Introduction 07:14 - Key moments in history of physics 12:43 - Philosophy of science 14:37 - Science and computational reducibility 22:08 - Predicting the pandemic 38:58 - Sunburn moment with Wolfram Alpha 39:46 - Computational irreducibility 46:45 - Theory of everything 52:41 - General relativity 1:01:16 - Quantum mechanics 1:06:46 - Unifying the laws of physics 1:12:01 - Wolfram Physics Project 1:29:53 - Emergence of time 1:34:11 - Causal invariance 1:53:03 - Deriving physics from simple rules on hypergraphs 2:07:24 - Einstein equations 2:13:04 - Simulating the physics of the universe 2:17:28 - Hardware specs of the simulation 2:24:37 - Quantum mechanics in Wolfram physics model 2:42:46 - Double-slit experiment 2:45:13 - Quantum computers 2:53:21 - Getting started with Wolfram physics project 3:14:46 - The rules that created our universe 3:24:22 - Alien intelligences 3:32:29 - Meta-mathematics 3:37:58 - Why is math hard? 3:52:55 - Sabine Hossenfelder and how beauty leads physics astray 4:01:07 - Eric Weinstein and Geometric Unity 4:06:17 - Travel faster than speed of light 4:16:59 - Why does the universe exist at all
Transcript
Discussion (0)
The following is a conversation with Stephen Wolfram, his second time in the podcast.
He is a computer scientist, mathematician, theoretical physicist, and the founder and CEO of Wolfram Research.
A company behind Mathematica, Wolfram Alpha, Wolfram Language, and the new Wolfram Physics project.
He is the author of several books including a new kind of science, and a new book,
a project to find the fundamental
theory of physics.
The second round of our conversation is primarily focused on this latter endeavor, of searching
for the physics of our universe in simple rules that do their work on hypergraphs, and
eventually generate the infrastructure from which space, time, and all of modern physics
can emerge.
Quick summary of the sponsors.
Simply safe, sunbasket, and masterclass.
Please check out these sponsors in the description to get a discount and to support this podcast.
As a side note, let me say that to me, the idea that seemingly infinite complexity can
arise from very simple rules and initial conditions is one
of the most beautiful and important mathematical and philosophical mysteries in science.
I find that both cellular automata and the hypergraph data structure that Stephen and
team are currently working on to be the kind of simple, clear mathematical playground
within which fundamental ideas about intelligence, consciousness, and the fundamental
laws of physics can be further developed in totally new ways.
In fact, I think I'll try to make a video or two about the most beautiful aspects of these
models in the coming weeks, especially I think trying to describe how fellow curious minds
like myself can jump in and explore them,
either just for fun, or potentially for publication of new innovative research and math,
computer science, and physics. But honestly, I think the emerging complexity in these
hypergraphs can capture the imagination of everyone, even if you're someone who never really connected
with mathematics. That's my hope at least,
to have these conversations that inspire everyone
to look up to the skies and into our own minds
in awe of our amazing universe.
Let me also mention that this is the first time
I ever recorded a podcast outdoors
as a kind of experiment to see if this is an option
in times of COVID.
I'm sorry if the audio is not great.
I did my best and promised to keep improving and learning as always.
If you enjoyed this thing, subscribe on YouTube,
review it with FastThars and Apple Podcasts, follow on Spotify,
support on Patreon, or connect with me on Twitter, Alexa Friedman.
As usual, I'll do a few minutes of ads now
and no ads in the middle.
I tried to make these interesting,
but I do give you time stamps, so you're welcome to skip.
But still, please do check out the sponsors
by clicking the links in the description.
It's the best way to support this podcast.
Also, let me say, even though I'm talking way too much
that I did a survey and it seems like over 90% of people either enjoy these ad reads somehow magically or don't mind
them at least.
That honestly just warms my heart that people are that supportive.
This show is sponsored by SimplySafe, a home security company.
Go to SimplySafe.com to get a free HD camera.
It's simple, no contracts, 15 bucks a month, easy setup, even I figured it out, I have
it set up in my apartment.
Of course I also welcome intruders.
One of my favorite movies is Leon, or the professional, with John Renaud, Gary Oldman,
and the brilliant Young Natalie Portman.
If you haven't seen the movie, he's a hitman with a minimalist life that resembles my own. In fact, when I was younger,
the idea of being a hitman or targeting evil in a skilled way, which is how I
thought about it, really appealed to me, the skill of it, the planning, the craftsmanship.
In another life, perhaps, if I didn't love engineering and science so much, I could see
myself being something like a Navy SEAL.
And in general, I love the idea of serving my country, of serving society, by contributing
my skill in some small way.
Anyway, go to simplysafe.com slash likes to get a free HD camera and to support this podcast.
They're a new sponsor, and this is a trial run.
So you know what to do.
This show is also sponsored by Sun Basket, a meal delivery service.
Visit sunbasket.com slash Lex and use code Lex to get $30 off your order and to support this podcast.
This is the last read of the trial they're doing.
So this is the time to get them if you're considering it.
And if you do, it'll help ensure that they decide to support this spot gas long term.
Their meals are healthy and delicious, a nice break from the minimalist meals of meat and vegetables that I usually eat.
Maybe on a personal note, one of my favorite things to do is watch people cook, especially people who love cooking, and hang out with people over amazing meals. I still
tend to be stricken by diet no matter what, even in fancy restaurants, but it
brings me joy to see friends and family indulge something like a cake that has
way too many calories or ice cream or whatever. My mom, in fact, for much of my
life made this
cake called an amp hill on my birthday that brings me a lot of joy and weight to many
calories. I was thinking of doing a video with my mom as she makes it. I thought it'd
be a fun thing to do together. Anyway, go to somebasket.com slash lux and use code Lex. Do
it now. So they signed a long-term contract with this podcast.
This show is also sponsored by masterclass. Sign up at masterclass.com slash Lex.
180 bucks a year. You get an all-access pass to watch lessons from Chris Hatfield,
Neil de Grass Tyson, Tony Hawk, Hall of Santana, Gareth Esparall, Daniel Nagrano,
Tyson Tony Hawk, Hall of Santana, Gareth Asparall, Daniel Nagrano, and many more brilliant world experts.
Masterclass has been a really special sponsor. They believe in this podcast in a way that gives me strength and motivation to take intellectual risks. I'm thinking of doing a few solo
podcasts episodes on difficult topics, especially in history, like the rise and fall of the Therryk, or Stalin, Putin,
and many other difficult topics that I'm fascinated by.
I have a world view that seeks inspiring positive insights, even and perhaps especially from
periods of tragedy and evil that perhaps some folks may find value in, if I can only
learn to convey the ideas in my mind as clearly as I think them. I
think deeply and rigorously and precisely. But to be honest, I have trouble speaking in
a way that reflects that rigor of thought. So really, it doesn't mean a lot. The love
and support I get as I try to get better at this thing, at this talking thing. Anyway,
go to masterclass.com slash lux to get a discount
and to support this podcast.
And now, finally, here's my conversation with Stephen Wolfram. You said that there are moments in history of physics and maybe mathematical physics
or even mathematics where breakthroughs happen and then a flurry of progress follows.
So if you look back through the history of physics,
what moment stand out to you
as importance is breakthroughs
where a flurry of progress follows?
So the big famous one was 1920s,
the invention of quantum mechanics,
where in about five or 10 years,
lots of stuff got figured out.
That's now quantum mechanics.
Can you mention if people involved?
Yeah, that would be kind of the Shodanja, Heisenberg, Einstein, had been a key figure originally plank,
then Derack was a little bit later. That was something that happened at that time, that sort of
before my time, right? In my time was in the 1970s, there was this sort of realization that quantum field theory was actually going
to be useful in physics and QCD, quantum quantum dynamics theory of quarks and gluons and so
on, was really getting started and there was again sort of big flurry of things happened
then, I happened to be a teenager at that time and happened to be really involved in physics
and so I got to be part of that, which was really cool.
Who were the key figures aside from your young selves
at that time?
You know, who won the Nobel Prize for QCD, okay?
People, David Gross, Frank Wilcheck, you know,
David Pulitzer, the people who are the sort
of the slightly older generation Dick Feynman,
Murray Gellman, people like that,
who Steve Weinberg get out at Hoft, his younger,
he's in the younger group, actually.
But these are all characters who are involved.
I mean, it was, it's funny because those are all people
who are kind of in my time, and I know them,
and they don't seem like sort of historical,
you know, iconic figures. They seem more like everyday characters, so to speak. And so it's always,
you know, when you look at history from long afterwards, it always seems like everything happened
instantly. And that's usually not the case. There was usually a long build up.
But usually there's some methodological thing happens.
And then there's a whole bunch of low-hanging fruit to be picked.
And that usually lasts five or ten years.
We see it today with machine learning and deep learning, neural nets and so on.
Methodological advance, things actually started working in 2011 you know, 2011, 2012, and so on.
And, you know, there's been this sort of rapid picking of low-hanging fruit, which is probably, you know,
some significant fraction of the way, way done, so to speak.
Do you think there's a key moment? Like, if I had to really introspect, like, what was the key moment for the deep learning quote unquote revolution?
I mean it's probably the Alex net business. Alex net with the image net. So is there something like that with physics where so deep learning neural networks have been around for a long time.
There's a bunch of little pieces that came together and then all of a sudden everybody's
eyes lit up like wow there's
something here like even just looking at your own work just you're thinking about the universe that
there's simple rules can create complexity you know at which point was there a thing where your
eyes light up is like wait a minute there's something here. Is it the very first
idea or is it some moment along the line of implementations and experiments and so on?
There's a couple of different stages to this. I mean, one is the think about the world computationally.
Can we use programs instead of equations to make models of the world, that's something that I got interested in in the beginning
of the 1980s.
You know, I did a bunch of computer experiments.
You know, when I first did them, I didn't really,
I could see some significance to them,
but it took me a few years to really say,
wow, there's a big important phenomenon here
that lets sort of complex things arise from very simple programs.
That kind of happened back in 1984 or so.
Then, you know, a bunch of other years go by,
then I start actually doing a lot of much more systematic computer experiments
and things and find out that the, you know, this phenomenon
that I could only have said occurs in one particular case,
is actually something incredibly general,
and then that led me to this thing called Principles Computational Equivalence,
and that was a long story.
And then, as part of that process,
I was like, okay, you can make simple programs,
can make models of complicated things.
What about the whole universe?
That's our sort of ultimate example of a complicated thing.
And so I got to thinking, could we use these ideas
to study fundamental physics?
You know, I happened to know a lot about, you know, traditional fundamental physics.
My, my first, you know, I had a bunch of ideas about how to do this in the early 1990s.
I made a bunch of technical progress.
I figured out a bunch of things I thought were pretty interesting.
You know, I wrote about them back in 2002.
With the new kind of science in the cellular terminal world, and there's echoes in the cellular
terminal world with your new Wolfram physics project world. We'll get to all that, allow me to
sort of romanticize a little more on the philosophy of science. So Thomas Kuhn, philosopher of science, describes that the progress in science is made with these paradigm shifts.
And so to link on the original line of discussion, do you agree with this view that there is revolutions in science that just kind of flip the table?
What happens is it's a different way of thinking about things. It's a different
methodology for studying things and that opens stuff up.
This is this idea of a famous biographer, but I think it's called the innovators, the
biographer of Steve Jobs of Albert Einstein. He also wrote a book, I think it's called
the innovators where he discusses how a lot of
the innovations in the history of computing has been done by groups. There's a complicated
group dynamic going on. But there's also a romanticized notion that the individual is at the core
of the revolution. Where does your sense fall? Is ultimately like one person responsible for these revolutions that they increase the
spark or one or two, whatever, but, or is it just the big mush in mess and chaos of
people interacting, of personalities interacting?
I think it ends up being like many things that is leadership and that ends up being, it's
a lot easier for one person to have a crisp new idea
than it is for a big committee to have a crisp new idea.
And I think, you know, but I think it can happen
that you have a great idea,
but the world isn't ready for it.
And you know, you can, I mean,
this has happened to me plenty, right?
It's, you know, you have an idea,
it's actually a pretty good idea,
but things aren't ready either, either you're not really ready for it, or the ambient world
isn't ready for it, and it's hard to get the thing to get traction.
It's kind of interesting. I mean, when I look at a new kind of science, you're not living
inside the history, so you can't tell the story of these decades, but it seems like the
new kind of science has not had the revolutionary impact, I would think it might.
It feels like at some point, of course it might be, but it feels at some point people will
return to that book and say there was something special here.
This was incredible.
Well, what happened, or do you think that's already happened?
Oh, yeah, it's happened, except that people aren't, you know, the sort of the heroism of it may not be there.
But what's happened is, for 300 years, people basically said, if you want to make a model of things in the world,
mathematical equations of the blessed place to go. people basically said, if you want to make a model of things in the world, mathematical
equations are the best place to go.
Last 15 years, it doesn't happen.
New models that get made of things, most often are made with programs, not with equations.
Now, was that sort of going to happen anyway?
Was that a consequence of my particular work and my particular book, it's hard to know for sure.
I mean, I am always amazed at the amount of feedback
that I get from people where they say,
oh, by the way, I started doing this whole line of research
because I read your book blah, blah, blah, blah, blah.
It's like, well, can you tell that
from the academic literature,
whether it was there a chain of academic references?
Probably not.
One of the interesting side effects of publishing
in the way you did this tone is it serves as an education tool
and an inspiration to hundreds of thousand millions of people.
But because it's not a chain of papers with puffy titles,
it doesn't create a splash of citations.
It's had plenty of citations, but it's, you know, I think that the, it people think of it as
probably more, you know, conceptual inspiration than, uh, then kind of a, you know, this is a line
from here to here to here in our particular field. I think that the, you know, the thing which I am disappointed by and which will eventually happen is this kind of study of the sort
of pure computationalism, this kind of study of the abstract behavior of the computational
universe, that should be a big thing that lots of people do.
You mean in mathematics purely, almost like it's like no mathematics, but it isn't mathematics. But it isn't. It's a new kind of mathematics.
It's a new title of book. Yeah, right. That's why the book is called that. Right. That's
not coincidental. Yeah. It's interesting that I haven't seen really rigorous investigation
by thousands of people of this idea. I mean, you look at your competition around rule 30.
I mean, that's fascinating. If you can say something,
right, is there some aspect of this thing that could be predicted?
That's fundamental question of science.
Well, that has been a question of science. I think that's a, that is a,
some people's view of what science is about. and it's not clear that's the right view. In fact, as we, as we live through this pandemic
full of predictions and so on, it's an interesting moment to be pondering what, what science
is actual role in those kinds of things is.
Are you think it's possible that in science, clean, beautiful, simple prediction may not
even be possible in real systems. That's the open question.
I don't think it's open. I think that question is answered. And the answer is no.
No, no. The answer could be just humans are not smart enough yet.
No, that's the whole point. I mean, that's that's sort of the big discovery of this principle of
computational equivalence of mine. And the, you know, this is something which is kind of a follow-on
to girdle theorem, to Turing's work on the halting problem, all these kinds of things, and this is something which is kind of a follow-on to Gurdles theorem, to Turing's
work on the halting problem, all these kinds of things, that there is this fundamental
limitation built into science, this idea of computational irreducibility, that says that
even though you may know the rules by which something operates, that does not mean that
you can readily sort of be smarter
than it and jump ahead and figure out what it's going to do.
Yes, but do you think there's a hope for pockets of computational reducibility?
Reducibility.
Reducibility.
Yes.
Yes.
And then a set of tools and mathematics that help you discover such pockets.
That's where we live is in the pockets of reducability.
Right. That's why, you know, and this is one of the things that sort of come out of this physics project and actually something that again, I should have realized many years ago, but didn't.
Is, you know, the it could very well be that everything about the world is computationally reducible and completely unpredictable.
But, you know, in our experience of the world, there is atcible and completely unpredictable. But in our experience
of the world, there is at least some amount of prediction we can make. And that's because we have
chosen a slice of, probably talk about this in much more detail, but I mean, we've kind of chosen
a slice of how to think about the universe in which we can kind of sample a certain amount of computational reducibility and that's where we exist.
It may not be the whole story of how the universe is,
but it is the part of the universe that we care about and we operate in.
In science, that's been a very special case of that.
That is science has chosen to talk a lot about places
where there is this computational reducibility
that it confined, the motion of the planets
can be more or less predicted.
The weather is much harder to predict.
Something about other kinds of things,
the much harder to predict.
And these are but science has tended to, you know,
concentrate itself on places where its methods have allowed
successful prediction.
So you think rule 30, if we could linger on it, because it's just
such a beautiful, simple formulation of the essential concept
and the lying, all the things we're talking about.
Do you think there's pockets of reducibility inside rule 30? Yes, that is a question of how big are they, what will they allow you to
say and so on. And that's, and figuring out where those pockets are, I mean, in a sense, that's the,
that's sort of a, you know, that is an essential thing that one would like to do in science.
thing that one would like to do in science. But it's also the important thing to realize
that has not been, you know, is that science,
if you just pick an arbitrary thing,
you say, what's the answer to this question?
That question may not be one that has a computation
or a reducible answer.
That question, if you choose, you know,
if you walk along the series of questions and you've got one
that's reducible and you get to another one sneer by and it's reducible too, if you stick
to that kind of stick to the land, so to speak, then you can go down this chain of sort
of reducible, answerable things.
But if you just say, I'm just pick a question at random, I'm going to have my computer
pick a question at random.
Most likely it's going to be reducible. Most likely it will be irreducible. And what we're throwing
in the world, so to speak, when we engineer things, we tend to engineer things to keep in the zone
of reducibility. When we're throwing things by the natural world, for example, not at all certain
that we will be kept in this kind of zone of reducibility.
Can we talk about this pandemic then?
Sure.
A little bit.
A little bit.
Sure.
So how do we, there's obviously huge amount of economic pain that people are feeling.
There's a huge incentive and medical pain, health, just all psychological.
There's a huge incentive to figure this out, to walk
along the trajectory of reducible, of reducibility. There's a lot of disparate data. People
understand generally how virus is spread, but it's very complicated because there's a lot
of uncertainty. There could be a lot of variability.
So many, obviously, a nearly infinite number of variables
that represent human interaction.
And so you have to figure out, from the perspective of
redisibility, figure out which variables are really important
in this kind of form an epidemiological perspective.
So why aren't we, you kind of said that we're clearly failing.
Well, I think it's a complicated thing.
So I mean, when this pandemic started up,
I happened to be in the middle of being about to release
this whole physics project.
Yes.
But I thought, you know,
The timing is just the cosplay, a little bit bizarre. But, but, you know, but I thought, you know,
I should do the public service thing of, you know, trying to understand what I could about the pandemic.
And, you know, we've been curating data about it and all that kind of thing. But, but, you know,
so I started looking at the data and started looking at modeling and I decided it's just really hard.
You need to know a lot of stuff that we don't know
about human interactions. It's actually clear now that there's a lot of stuff we didn't know about
viruses and about the way immunity works and so on. And it's, you know, I think what will come out
in the end is there's a certain amount of what happens that way you just kind of have to trace each
step and see what happens. There's a certain amount of stuff where there's going to be a big narrative about this happened because of T-cell immunity.
This happened because there's this whole giant field of asymptomatic viral stuff out there.
There will be a narrative, and that narrative, whenever there's a narrative, that's a sign
of reducibility. But when you just say, let's from first principles figure out what's going on, then you can potentially
be stuck in this kind of mess of irreducibility,
where you just have to simulate each step.
And you can't do that unless you know details about human
interaction, networks, and so on and so on and so on.
The thing that has been very sort of frustrating to see
is the mismatch between people's expectations about what
science can deliver and what science can actually deliver so to speak. Because people have this idea
that, you know, it's science, so there must be a definite answer and we must be able to know that
answer. And, you know, this is, it is both, you know, that when you've, after you've played around with sort of little programs in the
computational universe, you don't have that intuition anymore, you know, I'm always fond
of saying, you know, the computational animals are always smarter than you are. That is,
you know, you look at one of these things and it's like, it can't possibly do such and
such a thing, then you run it and it's like, wait a minute, it's doing that thing. How
does that work? Okay, now I can go back and understand it.
But that's the brave thing about science, is that in the chaos of the irreducible universe,
we nevertheless persist to find those pockets.
That's kind of the whole point.
That's like you say that the limits of science, but that, you know, yes, it's highly limited,
but there's a hope there. And like
there's so many questions I want to ask you. So one, you said narrative, which is really
interesting. So obviously from a at every level of society, you look at Twitter, everybody's
constructing narratives about the pandemic, about not just the pandemic, but all the cultural
tension that we're going through. So there's narratives, but they're not necessarily connected to the underlying
reality of these systems.
So our human narratives, I don't even know if they're, I don't like those pockets
of reducibility because we're, it's like, constructing things that are not
actually representative of reality. And thereby not giving us good solutions to how to predict the
system. It gets complicated because people want to say, explain the pandemic to me, explain what's
going to happen in the future. But, but also can you explain it?
Is there a story to tell?
What already happened in the past?
Yeah, what's going to happen?
But I mean, it's similar to sort of explaining things in AI or any computational system.
It's like, explain what happened.
Well, it could just be this happened because of this detail, this detail,
this detail, and a million details.
And there isn't a big story to tell.
There's no kind of big arc of the story that says,
oh, it's because there's a viral field
that has these properties and people start showing symptoms.
When the seasons change, people will show symptoms.
And people don't even understand
seasonal variation of flu, for example.
It's something where there you know, that could
be a big story, or it could be just a zillion little details that mount up. See, but, okay, let's
let's pretend that this pandemic, like the coronavirus, resembles something like the 1D
rule 30 cellular automata, okay? So I mean that's how epidemiologists
model virus spread. Indeed, yes. There's some graphs. You sell your automata, yes.
And okay, so you can say it's simplistic, but okay, let's say it's representative of actually what happens.
You know, the dynamic of
you have a graph,
it's probably closer to the hypergraph.
It did, it's actually, that's another funny thing.
As we were getting ready to release this physics project,
we realized that a bunch of things we'd worked out about,
about fullyations of causal graphs and things
were directly relevant to thinking about contact tracing.
Yeah, and interactions with cell phones and so on,
which is really weird.
But like, it just feels like we should be able to get some beautiful core insight about the
spread of this particular virus on the hypergraph of human civilization.
Right.
I tried.
I didn't manage to figure it out.
But you're one person.
Yeah.
But I mean, I think actually it's a funny thing because it turns out the main model,
the SIO model, I only realized recently
was invented by the grandfather of a good friend of mine
from high school.
So that was just a weird thing.
Right, the question is, okay, so you know,
on this graph of how humans are connected,
you know something about what happens
if this happens and that happens. That graph is made in complicated ways that depends on all graph of how humans are connected, you know something about what happens if this happens and that happens.
That graph is made in complicated ways
that depends on all sorts of issues
that where we don't have the data
about how human society works well enough
to be able to make that graph.
There's actually one of my kids did a study
of sort of what happens on different kinds of graphs
and how robust are the results.
Okay, his basic answer is there are a few general results
that you can get that are quite robust,
like a small number of big gatherings
is worse than a large number of small gatherings.
Okay, that's quite robust.
But when you ask more detailed questions,
it seemed like it just depends.
It depends on details.
In other words, it's kind of telling you,
in that case, the irreducibility matters, so to speak.
It's not there's not going to be this kind of one sort of master theorem that says, and therefore this is how things are going to work.
Yeah, but there's a certain kind of from a graph perspective, the certain kind of dynamic to human interaction.
So like large groups and small groups,
I think it matters who the groups are.
For example, you can imagine large,
depends how you define large,
but you can imagine groups of 30 people,
as long as they are cliques or whatever.
Like as long as the outgoing degree of that graph
is small or something like that, like
you can imagine some beautiful underlying rule of human dynamic interaction where I can
still be happy, where I can have a conversation with you and a bunch of other people that
mean a lot to me in my life and then stay away from the bigger, I don't know, not going
to my desires, concerts or something like that and figuring out mathematically.
Some nice, see this is an interesting thing. So I mean, you know, this is the question of what
you're describing as kind of the problem of many situations where you would like to get away
from computational irreducibility. Classic one in physics is thermodynamics. The, you know,
the second law of thermodynamics, the law that says,
entropy tends to increase things that start orderly tend to get more disordered,
or which is also the thing that says, given that you have a bunch of heat,
it's hard to heat is the microscopic motion of molecules. It's hard to turn that heat
into systematic mechanical work. It's hard to just take something being hot and turn that into,
oh, all the
atoms are going to line up in the bar of metal and the piece of metal is going to shoot in
some direction. That's essentially the same problem as how do you go from this computationally
irreducible mess of things happening and get something you want out of it? It's kind
of mining. You're kind of now, actually, I've understood in recent years that that the story of the dynamics is actually precisely
a story of computational irreducibility, but it is a, it is already an analogy, you know,
you can kind of see that is, can you take the, you know, what you're asking to do there
is you're asking to go from the kind of the mess of all these complicated human
interactions and all this kind of computational processes going on. And you say, I want to achieve
this particular thing out of it. I want to kind of extract from the heat of what's happening.
I want to kind of extract this useful piece of sort of mechanical work that I find helpful.
I mean, do you have a hope for the pandemic?
So we'll talk about physics, but for the pandemic,
can that be extracted?
Do you think what's your intuition?
The good news is the curves, basically,
for reasons we don't understand,
the curves, the clearly measurable mortality clothes
and so on, for the Northern Hemisphere have gone down.
But the bad news is that it could be a lot worse for future viruses and what this pandemic revealed
is where highly unprepared for the discovery of the pockets of reducibility within a pandemic
that's much more dangerous. Well, my guess is the specific risk of viral pandemics,
Well, my guess is the specific risk of viral pandemics, that the pure virology and immunology of the thing, this will cause that to advance to the point where this particular risk is
probably considerably mitigated. But is the structure of modern society robust to all kinds of risks? Well, the answer is clearly no.
And it's surprising to me the extent to which people,
as I say, it's kind of scary actually,
how much people believe in science.
That is people say, oh, because the science
says this, that, and the other, we'll do this,
and this, and this, even though, from a sort of common sense
point of view, it's a little bit crazy.
And people are not prepared and it doesn't really work
in society as it is for people to say,
well, actually, we don't really know how the science works.
People say, well, tell us what to do.
Yeah, because then, yeah, what's the alternative?
For the masses, it's difficult to sit.
It's difficult to meditate on computational or reproducibility. It's difficult to sit. It's difficult to meditate on computational
reproducibility.
It's difficult to sit.
It's difficult to enjoy a good dinner meal while knowing
that you know nothing about the work.
I think this is a place where this is what politicians
and political leaders do for a living,
so to speak, because you've got to make some decision
about what to do.
And it's some.
Tell some narrative that while amidst the mystery and knowing not much about the past or
the future, still telling a narrative that somehow guess people hope that we know what
the heck we're doing.
Yeah.
Get society through the issue. You know, even even though, you know, the idea that we're
just going to, you know, sort to be able to get the definitive answer from
science, and it's going to tell us exactly what to do, unfortunately, it's interesting
because let me point out that if that was possible, if science could always tell us what
to do, then in a sense, that will be a big downer for our lives.
If science could always tell us what the answer is going to be, it's like, well, it's kind of fun to live one's life
and just sort of see what happens.
If one could always just say, let me check my science.
Oh, I know the result of everything is going to be 42.
I don't need to live my life and do what I do.
It's just, we already know the answer.
It's actually good news in a sense
that there is this phenomenon of computational
irreducibility that doesn't allow you to just sort of jump through time and say this is the answer so to speak
And that's so that's a good thing the bad thing is it doesn't allow you to jump through time and know what the answer is
Scary do you think we're gonna be okay as a human civilization? You said we don't know
Absolutely. Yeah, do you think Absolutely. Do you think we'll prosper or destroy ourselves?
In general.
In general.
I'm an optimist.
No, I think that it'll be interesting to see, for example, with this pandemic.
To me, when you look at organizations, for example,
having some kind of perturbation,
some kick to the system,
usually the end result of that is actually quite good.
Unless it kills the system, it's actually quite good,
usually.
And I think in this case, people,
I mean, my impression, it's a little weird for me
because I've been a remote tech CEO for 30 years.
It doesn't, you know, this is bizarrely, you know, and the fact that, you know, like this coming to see you here is, is the, is the first time in six months that I've been like, you know, in a building other than my house.
Okay. So, so, so, you know, it's, I'm, I'm a kind of ridiculous outlier in these kinds of things. But overall, your sense is when you shake up the system
and throw in chaos, you challenge the system,
we humans emerge better.
Seems to be that way.
Who's to know?
But I think that, you know, people, you know,
my sort of vague impression is that people are sort of,
you know, oh, what's actually important, what is worth
caring about and so on.
That seems to be something that perhaps is more emergent in this kind of situation.
So fascinating that on the individual level, we have our own complex cognition.
We have consciousness, we have intelligence, we try to figure out little puzzles.
That somehow creates this graph of collective intelligence, where we have intelligence, we're trying to figure out little puzzles, and then that somehow creates this graph
of collective intelligence,
where we figure out,
and then you throw in these viruses,
of which there's millions different,
you know, this entire taxonomy,
and the viruses are thrown into the system
of collective human intelligence,
and the little humans figure out what to do about it.
We get like, we tweet stuff about
information.
There's doctors, there's conspiracy theorists, and then we play with different information.
I mean, the whole of it is fascinating.
I like you also very optimistic, but there's a feat, just you said, the computation of
reducibility, there's always a fear of the darkness of the uncertainty before us.
It's scary.
I mean, the thing is, if you knew everything, it would be boring.
And it would be, and then, and worse than boring, so to speak, it would reveal the pointlessness, so to speak.
And in a sense, the fact that there is this computational irreducibility, it's like as we live our lives, so to speak,
something is being achieved.
We're computing what our lives, you know,
what happens in our lives.
That's funny.
So the computation-reducibility is kind of like,
it gives the meaning to life.
It is the meaning of life.
Computation-reducibility is the meaning of life.
There you go.
It gives it meaning, yes. I mean, it's what causes it to not be
something where you can just say, you know, you went through all those
steps to live your life, but we already knew what the answer was.
Right. Hold on one second, I'm going to use my handy
off-malfa sunburn computation thing. So long as I can get network here.
There we go. Oh, actually, you know what?
It says sunburn unlikely.
This is a QA moment.
This is a good moment.
Okay, let me just check what it thinks.
Let's see why it thinks that.
It doesn't seem like my intuition.
This is one of these cases where we can...
The question is, do we trust the science?
So do we use common sense?
The UV thing is called the...
Yeah, yeah.
What we'll see, this is a QA moment, as I say.
And so, do we trust the product?
Yes, we trust the product.
So, if I'm desperately sunburned, I will send in an angry feedback. Because we mentioned the concept so much, and a lot of people know it, but can you say
what computation or usability is?
Yeah, right.
The question is, if you think about things that happen as being computations, you think
about the some process in physics, something that you compute in mathematics, whatever else.
It's a computation in the sense it has definite rules. You follow those rules,
you follow them many steps, and you get some result. So then the issue is, if you look at all these
different kinds of computations that can happen, whether they're computations that are happening in
the natural world, whether they're happening in our brains, whether they're happening in our mathematics, whatever else.
The big question is how do these computations compare?
Is are there dumb computations and smart computations?
Or are they somehow all equivalent?
And the thing that I kind of was sort of surprised to realize from a bunch of experiments that
I did in the early 90s and now we have tons more evidence for it, this thing I call the
principle of computational equivalence, which basically says, when one
of these computations, one of these processes that follows rules, doesn't seem like it's
doing something obviously simple, then it has reached the sort of equivalent level of
sophisticated, of computational sophistication of everything. So what does that mean? That
means that, you know, you might say, gosh, I'm studying this
little tiny, you know, tiny program on my computer. I'm studying this little thing in nature,
but I have my brain and my brain is surely much smarter than that thing. I'm going to be able to
systematically outrun the computation that it does because I have a more sophisticated
computation that I can do. But what the principle of computational equivalence says is that doesn't work.
Our brains are doing computations
that are exactly equivalent to the kinds of computations
that are being done in all these other sorts of systems.
And so what consequences does that have?
Well, it means that we can't systematically
outrun these systems.
These systems are computationally irreducible
in the sense that there's no sort of shortcut that
we can make that jumps to the answer.
In a general case.
Right.
Right.
So what has happened, you know, what science has become used to doing is using the little
sort of pockets of computational reducibility, which by the way are an inevitable consequence
of computational irreducibility, that they have to be these pockets scattered around of computational reduced
civility to be able to find those particular cases where you can jump ahead.
I mean one one thing sort of a little bit of a parable type thing that I think
is is fun to tell you know if you look at ancient Babylon they were trying to
predict three kinds of things they tried to predict you know where the
planets would be what the planets would be,
what the weather would be like, and who would win or lose a certain battle.
And they had no idea which of these things would be more predictable than the other.
That's funny.
And it turns out where the planets are is a piece of computational reduced
ability that 300 years ago, so we pretty much cracked.
It's been technically difficult to get all the details right
But it's basically we got that you know who's gonna win or lose the battle?
No, we didn't crack that one that one that one right the game theorists are trying. Yeah, and the weather
I'll be kind of halfway on that way. Yeah, I think we're we're doing okay that one I you know long time climate different story
But the weather you know we're doing okay. That one. So do you think of climate, different story, but the weather, you know, we're much closer
on that.
But do you think eventually we'll figure out the weather?
So do you think eventually most think we'll figure out the local pockets in everything,
essentially, the local pockets of reusability?
No, I think that it's an interesting question, but I think that the, you know, there is an
infinite collection of these local pockets.
We'll never run out of local pockets.
And by the way, those local pockets are where we build engineering, for example.
That's how we, you know, when we, if we want to have a predictable life, so to speak,
then, you know, we have to build in these sort of pockets of reducibility.
Otherwise, you know, if we were, if we were sort of existing in this kind of irreducible world, we'd never be
able to have definite things to know what's going to happen.
I have to say, I think one of the features, when we look at today from the future, so to
speak, I suspect one of the things where people will say, I can't believe they didn't see
that, is stuff to do with the following kind of thing. So if we describe, oh, I don't know,
something like heat, for instance, we say,
oh, the air in here, it's this temperature, this pressure.
That's as much as we can say.
Otherwise, just a bunch of random molecules bouncing around.
People will say, I just can't believe they didn't realize
that there was all this detail and how all these molecules were bouncing around and they could make use
of that. Actually, I realized there's a thing I realized last week, actually, was a thing
that people say, one of the scenarios for the very long term history of our universe is
a so-called heat death of the universe, where basically everything just becomes thermodynamically
boring. Everything's just this big gas and thermo-legalibrium.
People say, that's a really bad outcome.
But actually, it's not a really bad outcome.
It's an outcome where there's all this computation going on,
and all those individual gas molecules are all bouncing around
in very complicated ways, doing this very elaborate computation.
It just happens to be a computation that right now,
we haven't
found ways to understand.
We haven't found ways, our brains haven't an mathematics and our science and so on, haven't
found ways to tell an interesting story about that.
Just look sporing to us.
You're saying there's a hopeful view of the heat death, quote unquote, of the universe,
where there's actual beautiful
complexity going on similar to the kind of complexity we think of that creates rich experience
in human life and life on earth.
Yes.
So those little molecules interacting complex ways that that could be intelligence in that
there could be absolutely.
I mean, this is this is what you learn from this hopeful message. Right. I mean, this is what you learn from this principle for a message.
Right.
I mean, this is what you kind of learn
from this principle of computational equivalence.
You learn, it's both a message of sort of hope
and a message of kind of, you know,
there's not as special as you think you are,
so to speak, I mean, because, you know,
we imagine that with sort of all the things we do
with human intelligence and all that kind of thing and all of the stuff
We've constructed in science. It's like we're very special, but actually it turns out well, no, we're not
We're just doing computations like things in nature do computations like those gas molecules do computations like the weather does computations
The only the only thing about the computations that we do that's really special is that we understand
what they are, so to speak. In other words, we have a, you know, to us, that special because
kind of they're connected to our purposes, our ways of thinking about things and so on.
And that's some, but so that's very human-centric. That's where it just attached to this kind of thing.
So let's talk a little bit of physics.
Maybe let's ask the biggest question, what is a theory of everything in general?
What does that mean?
Yeah, so I mean, the question is,
can we kind of reduce what has been physics
as a something where we have to sort of pick away
and say do we roughly know how the world works? To something where we have to sort of pick away and say, do we roughly know how the world works?
To something where we have a complete formal theory where we say if we were to run this program
For long enough we would reproduce everything
You know down to the fact that we're having this conversation at this moment, etc., etc
Any physical phenomena any phenomena in this world phenomenon in the universe
Any physical phenomena, any phenomena in this world? Any phenomena in the universe.
But because of computational irreducibility,
that's not something where you say,
okay, you've got the fundamental theory of everything,
then tell me whether lions are going to eat tigers or something.
That's a, no, you have to run this thing for
10 to the 500 steps or something
to know something like that. Okay? So at some moment, potentially, you say, this is a rule
and run this rule enough times and you will get the whole universe. Right? That's what it means to kind
of have a fundamental theory of physics as far as I'm concerned is you've got this rule. It's
potentially quite simple.
We don't know for sure it's simple, but we have various reasons to believe it might be
simple.
And then you say, okay, I'm showing you this rule, you just run it only 10 to the 500
times, and you'll get everything.
In other words, you've kind of reduced the problem of physics to a problem of mathematics,
so to speak.
It's like, it's as if, you know,
you'd like to generate the digits of pi. There's a definite procedure, you just generate them,
and it'd be the same thing. If you have a fundamental theory of physics of the kind that
I'm imagining, you, you know, you get a, this rule, and you just run it out, and you get
everything that happens in the universe. So a theory of everything is a mathematical framework within which you can explain everything that happens in a universe.
It's kind of in a unified way.
It's not there's a bunch of disparate modules of.
Does it feel like if you create a rule and we'll talk about the Wolfram Physics model,
which is fascinating, but if you have a simple set of rules with a data structure,
like a hypergraph, does that feel like a satisfying theory of everything, because then you really run up against the
irreducibility, computational irreducibility.
Right, so that's a really interesting question.
So, what I thought was going to happen is, I thought we had a pretty good idea for what
the structure of this theory that's underneath space and time and so on might be like.
And I thought, gosh, in my lifetime, we might be able to figure out what happens in the first 10 to the minus 100 seconds of the universe.
And that would be cool, but it's pretty far away from anything that we can see today, and it will be hard to test whether that's right and so on and so on and so on.
To my huge surprise, although it should have been obvious, and it's embarrassing that it wasn't obvious to me, but to my huge surprise, we managed to get unbelievably much further than that.
And basically, what happened is that it turns out that even though there's this kind of bed of
computational irreducibility that sort of these all these simple rules run
into, there are certain pieces of computational reducibility that quite generically occur
for large classes of these rules. And, and this is the really exciting thing as far as I'm
concerned, the big piece of computational reducibility are basically the pillars of 20th century physics.
That's the amazing thing that general relativity and quantum field theory,
the sort of the pillars of 20th century physics, turn out to be precisely the stuff you can say.
There's a lot you can't say. There's a lot that's kind of at this irreducible level where you kind
of don't know what's going to happen. You have to run it. You know, you can't run it within our universe, et cetera, et cetera, et cetera, et cetera.
But the thing is there are things you can say, and the things you can say turn out to be very beautifully exactly the structure that was found in 20th century physics, namely general relativity and quantum mechanics. And general relativity and quantum mechanics are these pockets of reducibility that we think of as
that 20th century physics is
essentially pockets of reducibility.
And then it is incredibly surprising that any kind of model
that's generative
from simple rules would have
would have such pockets.
Yeah, well, I think what's surprising is,
we didn't know where those things came from.
It's like general relativity,
it's a very nice mathematically elegant theory.
Why is it true?
You know, quantum mechanics, why is it true?
What we realized is that from this,
that they are, these theories are generic to a huge class of systems that
have these particular very unstructured underlying rules. And that's the thing that is sort of remarkable,
and that's the thing to me that's just, it's really beautiful. I mean, it's, and the thing that's
even more beautiful is that it turns out that, you know, people have been struggling for a long time,
you know, how does general relativity, theory of gravity relate to quantum mechanics. They seem
to have all kinds of incompatibilities. It turns out what we realized is at some level they are
the same theory. And that's just it's just great as far as I'm saying. So maybe like taking
a little step back from your perspective, not from the low, not from the beautiful
hypergraph, well from physics model perspective, but from the perspective of 20th century physics,
what is general relativity, what is quantum mechanics, how do you think about these two
theories from the context of the theory of everything? It's just even definitions.
Yeah, yeah, yeah, right. So I mean, you know, a little bit of history of physics, right?
Yeah. So I mean, the, you know, okay, very, very quick history of this, right? So, so I mean,
you know, physics, you know, in ancient Greek times, people basically said, we can just figure
out how the world works. As, you know, we're philosophers, we're going to figure out how the world
works. You know, some philosophers thought there were atoms, some philosophers thought there were continuous flows of things,
people had different ideas about how the world works.
And they tried to just say,
we're going to construct this idea of how the world works.
They don't really have notions of doing experiments
and so on, quite the same way as developed later.
So that was an early tradition for thinking about models
of the world.
Then by the time of 1600s, time of Galileo,
and then Newton, the big idea there
was a title of Newton's book, a princepia mathematical
principles of natural philosophy.
We can use mathematics to understand natural philosophy,
to understand things about the way the world works.
And so that then led to this kind of idea
that we can write down a mathematical equation
and have that represent how the world works.
So Newton's one of his most famous ones
is his universal law of gravity, inverse square law of gravity
that allowed him to compute all sorts of features
of the planets and so on, although some of them he got wrong.
And it took another hundred years for people
to actually be able to do the math to the level
that was needed.
But so that had been the sort of tradition
was we write down these mathematical equations.
We don't really know where these equations come from.
We write them down, then we figure out,
we work out the consequences, and we say,
yes, that agrees with what we actually observe
in astronomy or something like this.
So that tradition continued, and we say yes, that agrees with what we actually observe in astronomy or something like this.
So that tradition continued, and then the first of these two sort of great 20th century innovations
was, well, the history is actually a little bit more complicated, but let's say the,
there were two quantum mechanics and general relativity.
Quantum mechanics, a kind of 1900 was kind of the very early stuff done by Plank that led to the idea of photons, particles of light. But let's take
general relativity first. One feature of the story is that special relativity, thing
Einstein invented in 1905, was something which surprisingly was a kind of logically invented
theory. It was not a theory where,
it was something where, given these ideas that were sort of axiomatically thought to
be true about the world, it followed that such and such a thing would be the case.
And it was a little bit different from the kind of methodological structure of some existing
theories in the more recent times, or it's just been we write down an equation
and we find out that it works.
So what happened there?
So there's some reasoning about the light.
The basic idea was the speed of light
appears to be constant.
Even if you're traveling very fast,
you shine a flashlight.
The light will come out, even if you're going at half the speed
of light, the light doesn't come out of your flashlight at one and a half times the speed of light.
It's still just the speed of light.
And to make that work, you have to change your view of how space and time work to be able
to account for the fact that when you're going faster, it appears that, you know, length
is for shortened and time is dilated and things like this.
That's special activity.
That's special activity. That's special activity.
So then Einstein went on with sort of vaguely similar kinds of thinking in
1915, invented general relativity, which is the theory of gravity.
And the basic point of general relativity is, is, it's a theory that says,
when there is mass in space space is curved. And what does that mean?
You know, usually you think of what's the shortest distance between two points, like, you know,
ordinarily on a plane in space, it's a straight line. You know, photons, light goes in straight lines.
Well, then the question is, is if you have a curved surface,
a straight line is no longer straight. On the surface of the earth, the shortest distance
between two points is a great circle. It's a circle. So Einstein's observation was maybe the
physical structure of space is such that space is curved. So the shortest distance between two points,
the path, the straight line in quotes,
won't be straight anymore.
And in particular, if a photon is traveling near the sun
or something like a particle is going,
something is traveling near the sun,
maybe the shortest path will be one that is something which looks curved to us because
it seems curved to us because space has been deformed by the presence of mass, as I
said, with that massive object.
So the kind of the idea there is, think of the structure of space as being a dynamical
changing kind of thing.
But then what Einstein did was he wrote down these differential equations that basically represented the curvature of space and its response to the presence of
mass and energy. And that ultimately is connected to the force of gravity, which is one of
the forces that seems to base on a strength operate on a different scale than some of
the other forces. So it operates to scale. It's very large.
What happens there is just this curvature of space which causes, you know, the paths of objects to be deflected, that's what gravity does. It causes the paths of objects to be deflected.
And this is an explanation for gravity, so to speak. And the surprises that from 1915 until today,
everything that we've measured about gravity
precisely agrees with general relativity.
And that's some, and that, you know, it wasn't clear black holes were sort of a predict,
well actually the expansion of the universe was an early potential prediction, although Einstein
tried to sort of patch up his equations to make it not cause the universe to expand, because
it was kind of so obvious the universe wasn't expanding.
And it turns out it was expanding
and you should have just trusted the equations.
And that's a lesson for those of us interested
in making fundamental theories of physics
is you should trust your theory and not try and patch it
because of something that you think might be the case
that might turn out not to be the case.
Even if the theory says something crazy is happening.
Yeah, right.
Like the universe is expanding.
Like the universe is expanding, right?
But then it took until the 1940s,
probably even really until the 1960s,
until people understood that black holes
were a consequence of general relativity and so on.
But the big surprise has been that so far,
this theory of gravity has perfectly agreed,
but these collisions of black holes
seen by their gravitational waves, it all just works.
So that's been one pillar of the story of physics.
It's mathematically complicated
to work out the consequences of general relativity,
but it's not, there's no, I mean,
and some things are kind of squiggly and complicated.
Like people believe, you know, energy is conserved.
Okay, well, energy conservation doesn't really work in general activity in the same way as
it ordinarily does.
And it's all a big mathematical story of how you actually nail down something that is
definitive that you can talk about it and not specific to the, you know, reference frames
you're operating in and so on and so on and so on.
But fundamentally, general relativity is a straight shot in the sense that you have this
theory, you work out its consequences.
And that theory is useful in terms of basic science and trying to understand the way black
holes work, the creation of galaxies work, sort of all these kind of cosmological thing,
understanding what happened, like you said, at the Big Bang.
Yeah, like all those kinds of, not at the Big Bang, actually.
Right? But the features of the expansion of the universe,
I mean, there are lots of details where we don't quite know how it's working, you know, is there, you know, where's the dark matter, is that dark energy, you know, et cetera, et cetera, et cetera.
But fundamentally, the testable features of general relativity,
it all works very beautifully.
And it's in a sense, it is mathematically sophisticated,
but it is not conceptually hard to understand in some sense.
OK, so there's general relativity.
And what's its friendly neighbor, like you said,
quantum mechanics.
Quantum mechanics.
Right.
So quantum mechanics, the way that that originated was, one
question was, is the world continuous or is it discrete? You know, in ancient Greek times,
people have been debating this. People debated it throughout history as light,
could made of waves, as it continuous, as it discrete, as it made of particles, corpuscles,
whatever. You know, what had become clear in the 1800s is that atoms that materials are made of discrete atoms.
When you take some water, the water is not a continuous fluid, even though it seems like
a continuous fluid to us at our scale.
But if you say, let's look at it, it's more and more and more and smaller scale.
Eventually you get down to these molecules and then atoms.
It's made of discrete things.
So question is sort of how important is this discreteness? Just what's discrete? What's not
discrete? Is energy discrete? What's discrete? What's not? And so? Does it have mass?
Those kinds of questions? Yeah, yeah, right. Well, there's question, I mean, for example,
is mass discrete as an interesting question, which is now something we can address.
But what happened in the coming up to the 1920s, there was this kind of mathematical theory
developed that could explain certain kinds of discreetness in particularly in features
of atoms and so on.
And what developed was this mathematical theory
that was the theory of quantum mechanics,
theory of wave functions, Schrodinger's equation,
things like this.
That's a mathematical theory that allows you
to calculate lots of features of the microscopic world,
lots of things about how atoms work, et cetera, et cetera.
Now, the calculations all work just great.
The question of what does it really mean is a complicated question.
Now, I mean to just explain a little bit historically,
the early calculations of things like atoms worked great, 1920s, 1930s, and so on.
There was always a problem there were in quantum field theory,
which is a theory of, in quantum mechanics, you're dealing with a certain number of electrons,
and you fix the number of electrons.
You say, I'm dealing with a two-electron thing.
In quantum field theory, you allow for particles being created and destroyed,
so you can emit a photon that didn't exist before,
you can absorb a photon, things like that.
That's a more complicated, mathematically complicated theory,
and it had all kinds of mathematical issues and all kinds of infinities that cropped up. And it was finally figured
out more or less how to get rid of those. But there were only certain ways of doing the
calculations, and those didn't work for atomic nuclei among other things. And that led to
a lot of development up until the 1960s of alternative ideas for how one could understand what was happening
in atomic nuclei, et cetera, et cetera, et cetera, end result.
In the end, the kind of most, quote, obvious mathematical structure of quantum field theory
seems to work, although it's mathematically difficult to deal with.
But you can calculate all kinds of things.
You can calculate to, you know, a dozen decimal places, certain things.
You can measure them. It all works. It's all beautiful. Now you say, the underlying
fabric is the model of that particular theory's fields. Like you keep saying fields.
Those are quantum fields. Those are different from classical fields. A field is something
like you say, there's like you say, the temperature field in this room. It's like there is a value of
temperature at every point around the room. Or you can say the wind field would be the vector
direction of the wind at every point. It's continuous. Yes. And that's a classical field. The
quantum field is a much more mathematically elaborate kind of thing. And I should explain that
one of the pictures of quantum mechanics, it's really important, is, you know, in classical physics, one believes that sort of definite
things happen in the world. You pick up a ball, you throw it, the ball goes in a definite
trajectory that has certain equations of motion, it goes in a parabola, whatever else.
In quantum mechanics, the picture is definite things don't happen. Instead, what happens is this whole structure of all many different paths being followed,
and we can calculate certain aspects of what happens, certain probabilities of different
outcomes and so on.
And you say, well, what really happened?
What's really going on?
What's the underlying story?
How do we turn this mathematical theory
that we can calculate things with into something
that we can really understand and have a narrative about?
And that's been really, really hard for quantum mechanics.
My friend Dick Feynman always used to say,
nobody understands quantum mechanics,
even though he'd made his whole career
out of calculating things about
quantum mechanics.
And so it's a little...
But nevertheless, what the quantum field theory is very accurate at predicting a lot
of the physical phenomena.
So it works.
Yeah.
But there are things about it.
It has certain, when we apply it, the standard model of particle physics, for example, which
we apply to calculate all kinds of things that works really well.
And you say, well, it has certain parameters.
It has a whole bunch of parameters, actually.
You say, why does the muon particle exist?
Why is it 206 times the mass of the electron?
We don't know.
No idea.
But so the standard model physics is one of the models that's very accurate for describing
three of the fundamental forces of physics and it's looking at the world of the very small.
Right.
And then there's back to the neighbor of gravity, of general relativity.
So, and in the context of a theory of everything, what's traditionally
the task of the unification of these theories and why is it hard?
Well, the issue is you try to use the methods of quantum field theory to talk about gravity
and it doesn't work, just like there are photons of light, so there are gravitons which are
sort of the particles of gravity.
And when you try and compute sort of the properties of the particles of gravity, the kind of mathematical
tricks that get used in working things out in quantum field that don't work.
And that's sort of fundamental issue.
And when you think about black holes, which are a place where sort of the structure
of space is, you know, has sort of rapid variation and you get kind of quantum effects mixed
in with effects from general activity, things get very complicated in their apparent paradoxes
and things like that. And people have, you know, there have been a bunch of mathematical
developments in physics over the last, I don't know, 30 years or so, which have kind of picked away at those kinds of issues and got hints
about how things might work. But it hasn't been, you know, the other thing to realize is,
as far as physics is concerned, it's just like his general authority, his quantum field theory,
you know, be happy. Yes, did you think there's a quantization of gravity?
The quantum gravity, what do you think of efforts that people have tried to?
Yeah, what do you think in general of the efforts of the physics community try to unify these laws?
So I think what's, it's interesting.
I mean, I would have said something very different before what's happened with our physics project.
I mean, you know, the remarkable thing is what we've been able to do is to make from this
very simple, structurally simple underlying set of ideas.
We've been able to build this, you know, very elaborate structure that's both very abstract
and very sort of mathematically rich.
And the big surprise, as far as I'm concerned,
is that it touches many of the ideas that people have had.
So in other words, things like string theory and so on,
Twister theory, it's like, we might have thought.
I had thought we're out on a prong.
We're building something that's computational.
It's completely different from what other people have done.
But actually, it seems like what we've done
is to provide essentially the machine code that,
you know, these things are various features of domain-specific languages, so to speak,
that talk about various aspects of this machine code.
And I think this is something that to me is very exciting because it allows one,
both for us to provide sort of a new foundation for what's been thought
about there and for all the work that's been done in those areas to give us more momentum
to be able to figure out what's going on.
Now, people have sort of hoped, oh, we're just going to be able to get string theory to
just answer everything.
That hasn't worked out.
And I think we now kind of can see a little bit about
just sort of how far away certain kinds of things are from being able to explain things.
Some things, one of the big surprises to me actually I literally just got a message about one
aspect of this is the you know it's turning out to be easier. I mean this project has been so much
easier than I could ever imagine it would be. That is, I thought we would be, you know, just about able to understand the first 10th
to the minus 100 seconds of the universe.
And you know, it would be 100 years before we get much further than that.
It's just turned out it actually wasn't that hard.
I mean, we're not finished, but, you know, what-
So you're seeing echoes of all the disparate theories of physics in this framework.
Yes.
It's a very interesting history of science like phenomenon.
The best analogy that I can see is what happened with the early days of computability and computation theory.
Touring machines were invented in 1936.
People understand computation in terms of touring machines, but actually there had been pre-existing theories of computation,
combinators, general cursive functions, lambda calculus, things like this.
But people hadn't, those hadn't been concrete enough that people could really wrap their arms around them and understand what was going on.
And I think what we're going to see in this case is that a bunch of these mathematical theories, including some very, one of the things that's really interesting is one of the most abstract things
that's come out of sort of mathematics, higher category theory, things about infinity
groupboids, things like this, which to me always just seemed like they were floating off into
the stratosphere, ionosphere of mathematics, turn out to be things which our sort of theory
anchors down to something fairly definite and says are super relevant to the way that we can
understand how physics works. Give me a second. By the way, I just threw a head on. You've said that
with this metaphor analogy that the theory of everything
is a big mountain.
And you have a sense that however far we are up the mountain,
that the Wolfram physics model of you, of the universe,
is at least the right mountain.
Will the right mountain?
Yes, without question. So I'm which aspect of it least the right mountain. Will the right mountain? Yes, without question.
So I'm, I'm, I'm which aspect of it is the right mountain.
So for example, I mean, so there's so many aspects to just the way of the
well from physics project, the way it approaches the world that's,
that's clean crisp and unique and powerful.
So, you know, there's a discrete nature to it.
There's a hypergraph.
There's a computational nature.
There's a generative aspect.
You start from nothing, you generate everything.
What do you think the actual model is actually a really good one?
Or do you think this general principle
of simplicity generating complexities is the right?
Like what aspect of the mountain is different?
I think that the kind of the meta idea about using simple
computational systems to do things, that's
the ultimate big paradigm that is super important.
The details of the particular model are very nice and clean
and allow ones to actually understand what's going on.
They are not unique.
And in fact, we know that.
We know that there's a large number of different ways
to describe essentially the same thing.
I mean, I can describe things in terms of hypergraphs.
I can describe them in terms of higher category theory.
I can describe them in a bunch of different ways.
They are in some sense all the same thing, but our sort of story about what's going on
and the kind of cultural mathematical resonances are a bit different.
I think it's perhaps worth sort of saying a little bit about kind of the foundational
ideas of these models and things.
Great.
So, can you maybe, can we like rewind?
We've talked about a little bit,
but can you say like what the central idea is
of the War from Physics project?
Right. So, so the question is,
we're interested in finding a sort of simple computational rule
that describes our whole universe.
It's just, it's just so beautiful.
And that's such a beautiful. That's such a beautiful idea that we can generate our universe from a data structure,
simple structure, simple set of rules, and we can generate our entire universe.
Yes.
That's all inspiring.
Right.
Right.
But so, you know, the question question is how do you actualize that what might this rule be like and so one thing
You quickly realizes if you're gonna pack everything about a universe into this tiny rule
Not much that we are familiar with in our universe will be obvious in that rule
So you don't get to fit all these parameters of the universe,
all these features of, you know, this is how space works, this is our time, etc, etc.
You don't get to fit that all, it all has to be sort of packed in to this thing, something much
smaller, much more basic, much lower level machine code, so to speak than that. And all the stuff
that we're familiar with has to kind of emerge from the operation of the rule in itself,
because of the computational reducibility, it's not going to tell you the story. It's not going to give
you the answer to, it's not going to let you predict what you're going to have for lunch tomorrow.
Right. And it's not going to let you predict basically anything about your life, about the universe.
Right. But and you're not going to be able to see in that rule,
oh, there's the three for the number of dimensions of space and so on.
Right. That's not going to be the space time is not going to be obviously.
Right. So the question is then, what is the universe made of?
That's a basic question.
And we've had some assumptions about what the universe is made of
for the last few thousand years that I think in some cases
just turn out not
to be right. And you know, the most important assumption is that space is a continuous
thing. That is that you can, if you say, let's pick a point in space. We're going to do
geometry. We're going to pick a point. We can pick a point absolutely anywhere in space.
Precise numbers, we can specify of where that point is.
In fact, you know, Euclid, who kind of wrote down
the original kind of axiomitization of geometry
back in 300 BC or so, you know, his very first definition,
he says, a point is that which has no part.
A point is this, you know, this indivisible,
you know, infinitesimal thing.
Okay, so we might have said that about material objects.
We might have said that about water, for example.
We might have said water is a continuous thing
that we can just, you know, pick any point we want
in some water, but actually we know it isn't true.
We know that water is made of molecules that are discrete.
And so the question, one fundamental question
is what is space made of.
And so one of the things that sort of a starting point for what I've done is to think of space as a
discrete thing, to think of there being sort of atoms of space just as there are atoms of material
things, although very different kinds of atoms. And by the way, I mean this idea, you know,
there were ancient Greek philosophers who had this idea.
There were, you know, Einstein actually thought this is probably how things would work out.
I mean, he said, you know, repeatedly, he thought, that's just where it would work out.
We don't have the mathematical tools in our time, which was 1940s, 1990s, and so on, to explore this.
Like the way he thought, you mean that there is something very, very small and discreet that's underlying
space, space. Yes. And that means that, so the mathematical theory, mathematical theories
in physics assume that space can be described just as a continuous thing. You can just pick
coordinates and the coordinates can have any values. And that's how you define space.
Space is this just sort of background,
sort of theater on which the universe operates.
But can we draw a distinction between space as a thing that could be
described by three values, coordinates,
and how you're using the word space more generally when you say,
I'm just talking about space as in what we experience in the universe.
So that you think this 3D aspect of it is fundamental?
No, I don't think of 3D as fundamental at all actually.
I think that the thing that has been assumed is that space is this continuous thing where you can just
describe it by, let's say, three numbers, for instance.
But the most important thing about that is that you can describe it by precise numbers,
because you can pick any point in space, and you can talk about motions, any infinitesimal
motion in space.
And that's what continuous means.
That's what continuous means.
That's what Newton invented calculus to describe these kind of continuous small variations and so on
That was that's kind of a fundamental idea from you clad on that's been a fundamental idea about space and
So right are wrong
It's not right. It's not right. It's it's it's it's it's right at the level of our experience most of the time
It's not right that the level of machine code, so to speak.
And so machine code.
Yeah, of the simulation, that's right.
That's right.
The very lowest level of the fabric of the universe,
at least under the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, the, senses is discrete. Right, so now what does that mean? So it means what what is space then? So in
in models, the basic idea is you say there are these sort of atoms of space, there are these points
that represent, you know, represent places in space, but they're just discrete points. And the only
thing we know about them is how they're connected to each other.
We don't know where they are. They don't have coordinates. We don't get to say,
this is a position such and such. It's just, here's a big bag of points. Like in our universe,
they might be 10 to the 100 of these points. And all we know is this point is connected to this
other point. So it's like, you know, all we have is the friend network, so to speak. We don't,
we don't have, you know, people's, you know, physical addresses, all we have is the friend network, so to speak. We don't have people's physical addresses, all we have is the friend network of these points.
The underlying nature of reality is kind of like a Facebook, but I know that a location
will have the friends.
Yeah, yeah, right.
We know which point is connected to which other points.
And that's all we know.
And so you might say, well, how on earth can you get something which is like our experience
of what seems like continuous space?
Well, the answer is, by the time you have 10 to the 100 of these things, those connections
can work in such a way that on a large scale, it will seem to be like continuous space in,
let's say, three dimensions or some other number of dimensions or 2.6 dimensions or whatever
else.
Because they're much, much, much, much larger.
So like the number of relationships here we're talking about is just a humongous amount.
So the kind of thing you're talking about is very, very, very small relative to our experience of daily life.
Right. So I mean, you know, we don't know exactly the size,
but maybe, maybe,
10 to the minus, maybe around 10 to the minus 100 meters. So, you know, the size of, to give a comparison, you know, size of a proton is 10 to the minus 15 meters. And so this is something
incredibly tiny compared to that. And the idea that from that would emerge the experience of continuous space is mind-blowing.
What's your intuition why that's possible? First of all, we'll get into it, but I don't know if we
will through the medium of conversation, but the construct of hypergraphs is just beautiful.
Tell you're ainoe of beautiful.
We'll talk about it, but okay.
But this thing about, you know,
continuity arising from discrete systems is in today's world
is actually not so surprising.
I mean, you know, your average computer screen, right?
Every computer screen is made of discrete pixels.
Yet we have the, you know,
we have the idea that we're seeing these continuous pictures.
I mean, it's, you know's the fact that on a large scale continuity
can arise from lots of discrete elements.
This is at some level unsurprising now.
Oh, wait, wait, wait.
But the pixels have a very definitive structure
of neighbors on a computer screen.
Right. There's no concept of spatial of space inherent
in the underlying fabric of reality.
Right, right, right.
So the point is, but there are cases where there are.
So for example, let's just imagine
you have a square grid.
And at every point on the grid,
you have one of these atoms of space. And it's connected to
four other four other atoms of space on the, you know, Northeast Southwest corners, right? There,
you have something where if you zoom out from that, it's like a computer screen. Yeah. So the
relationship creates the, the spatial, like the relationship creates a constraint, which then
spatial, like the relationship creates a constraint, which then in an emergent sense creates us, like, yeah, like a, uh, basically a spatial coordinate for that thing.
Yeah, right.
Even though the individual point doesn't have a spatial, even though the individual point
doesn't know anything, it just knows what it's, you know, what it's neighbors are.
They on a large scale, it can be described by saying, oh, it looks like it's's, you know, what it's neighbors are. The on a large scale, it can be described by saying,
oh, it looks like it's a, you know, this grid zoomed out grid.
You can say, well, you can describe these different points
by saying they have certain positions, coordinates, et cetera.
Now, in the, in the sort of real setup, it's more complicated
than that. It isn't just a square grid or something.
It's something much more dynamic and complicated,
which we'll talk about.
But so, you know, the first idea, the first key idea is, you know, what's the universe
made of? It's made of atoms of space, basically, with these connections between them. What
kind of connections do they have? Well, so, the simplest kind of thing you might say is,
we've got something like a graph where every atom of space, where we have these edges
that go between, out of these connections that go between atoms of space. We're not saying
how long these edges are. We're just saying there is a connection from this atom to this
atom. Just a quick pause because there's a lot of
very people that listen to this just to clarify because I did a poll actually what do you think a graph is a long time ago
and it's kind of funny how few people know the term graph
outside of computer science. Let's call it a network. I think that's calling a network is better.
So, but every time I like to work graph though so let's define, let's just say that a graph
will use terms nodes and edges maybe and it's just the nodes represent some abstract entity
and then the edges represent relationships between those entities. Right. Exactly. So that's what
graphs are. So there you go. So that's the basic structure. That is that is the simplest case
with basic structure. Actually, it tends to be better to think about hypergraphs. So a
hypergraph is just, instead of saying there are connections between pairs of
things, we say there are connections between any number of things. So there
might be turnery edges. So instead of just having two points are connected by an
edge, you say three points are all associated with a
hyper edge, are all connected by a hyper edge. That's just at some level, that's
at some level that's a detail. It's a detail that happens to make the for me,
you know, sort of in the history of this project, the realization that you could
do things that way broke out of certain kinds of arbitrariness that I felt
that there was in the model before I had seen how this worked.
I mean, a hypergraph can be mapped to a graph.
It's just a convenient representation,
mathematically speaking.
That's correct.
That's correct.
But so then, so, okay.
So the first question, the first idea of these models of ours
is space is made of these connected sort of atoms of space.
The next idea is space is all there is.
There's nothing except for this space.
So in traditional ideas and physics people have said
there's space, it's kind of a background,
and then there's matter, all these particles, electrons,
all these other things, which exist in space.
But in this model, one of the key ideas is
there's nothing except space.
So in other words, everything that exists in the universe is a feature of this hypergraph.
So how can that possibly be?
Well, the way that works is that there are certain structures in this hypergraph where
you say that little twisty-noted thing, we don't know exactly how this works yet, but we have
sort of idea about how it works mathematically.
This sort of twisted knotted thing, that's the core of an electron.
This thing over there that has this different form, that's something else.
So the different peculiarities of the structure of this graph are the very things that we think
of as the particles inside the space, but in fact it's just
a property of the space.
Mine blowing, first of all, it's mine blowing and we'll probably talk in its simplicity
and beauty.
Yes, I think it's very beautiful.
I think this is, I'm, okay, so that's space.
And then there's another concept we didn't really kind of mention but you think it of computation as a transformation.
Let's talk about time in a second.
Let's just, I mean, on the subject of space, there's this question of what, there's this
idea, there is this hypergraph, it represents space and it represents everything that's
in space.
The features of that hypergraph, you can say certain features in this part, we do know certain features of the hypergraph represent the presence of
energy, for example, or the presence of mass or momentum.
We know what the features of the hypergraph that represent those things are, but it's all
just the same hypergraph.
One thing you might ask is, if you just look at this hypergraph and you say, we're going
to talk about what the hypergraph does, but if you say, how much of what's going on in this hypergraph
is things we know and care about, like particles
and atoms, electrons, and all this kind of thing,
and how much is just the background of space.
So it turns out, so far as in one rough estimate of this,
or everything that we care about in the universe is only
one part in 10 to the 120 of what's actually going on. The vast majority of what's happening
is purely things that maintain the structure of space. In other words, the things that are
the features of space that are the things that we consider notable, like the presence of particles
and so on, that's a tiny little piece of froth on the top of all this activity that mostly is just intended to,
you know, mostly, I can't say intended, there's no intention here,
that just maintains the structure of space.
Let me load that in.
It just makes me feel so good as a human being. Well, to be the froth on the one in a 10 to the 120 or something of well, and also just
humbling how in this mathematical framework, how much work needs to be done on the infrastructure.
Right.
Yes, that's right.
Right.
To maintain the infrastructure value in the universe is a lot of work.
We are merely writing a little tiny things on top of that infrastructure.
But you know, you were just starting to talk a little bit about what, you know, we talked
about, you know, space that represents all the stuff that's in the universe.
The question is, what does that stuff do?
And for that, we have to start talking
about time and what is time and so on. And one of the basic idea of this model is time
is the progression of computation. So in other words, we have a structure of space and there
is a rule that says how that structure of space will change, and it's the application, the repeated application of that rule that defines the progress of time.
What does the rule look like in a space of hyper-gress?
Right, so what the rule says is something like,
if you have a little tiny piece of hyper-graph
that looks like this, then it will be transformed
into a piece of hyper-graph that looks like this.
So that's all it says.
It says you pick up these elements of space
and you can think of these edges,
these hyper edges as being relations
between elements and space.
You might pick up these two relations
between elements and space.
And we're not saying where those elements are
or what they are, but every time there's
a certain arrangement of elements in space, then arrangement in the sense of the way they're connected, then we
transform it into some other arrangement. So there's a little tiny pattern and you transform it
to another little pattern. That's right. And then because of this, I mean, again, it's kind of
similar to cellular atomic and that like, on paper, the rule looks like super simple. It's like,
or a cellular atomic and that like, on paper the rule looks like super simple.
It's like, yeah, okay.
Yeah, right, from this to the universe can be born.
But like, once you start applying it,
beautiful structure starts being,
potentially can be created.
And what you're doing is you're applying that rule
to different parts, like anytime you match it
within the hypergraph.
Exactly.
And then one of the, like, incredibly beautiful
and interesting things to think about
is the order in which you apply that rule.
Yes.
Because that pattern appears all over the place.
Right.
So this is a big complicated thing,
very hard to wrap one's brain around.
Okay.
So you say the rule is is every time you see this little pattern
transformative in this way, but yet, you know, as you look around the space that
represents the universe, there may be zillions of places where that little pattern occurs.
So, so what what it says is just do this apply this rule wherever you feel like.
what it says is just do this, apply this rule wherever you feel like. And what is extremely non-trivial is, well, okay, so this is happening sort of in computer
science terms sort of asynchronously.
You're just doing it wherever you feel like doing it.
And the only constraint is that if you're going to apply the rule somewhere, the things
to which you apply the rule, the little elements to which you apply the rule, the little elements to which
you apply the rule, if they have to be...
Okay, you can think of each application of the rule as being kind of an event that happens
in the universe.
And these, the input to an event has to be ready for the event to occur.
That is, if one event occurred,
if one transformation occurred,
and it produced a particular atom of space,
then that atom of space has to already exist
before another transformation that's going to apply
to that atom of space can occur.
So that's like the prerequisite for the event.
That's right. That's right.
So that defines a kind of this sort of set of causal relationships between events.
It says this event has to happen before this event.
But that is-
But that's not a very limiting constraint.
No, it's not.
And what's it still, you still get the zillion, that's the technical term, options.
That's correct.
But, okay, so this is where things get a little bit more elaborate, but they're mind-blowing.
So, right, but so what happens is, so the first thing you might say is, you know, let's,
well, okay, so this question about the freedom of which event you do when? Well, let me sort of state an answer and then explain it, okay? The validity of special
activity is a consequence of the fact that in some sense it doesn't matter in what order you do
these underlying things, so long as they respect this kind of set of causal relationships.
So that's the part that's in a certain sense
is a really important one, but the fact that it sometimes
doesn't matter.
That's a, I don't know, that's another like beautiful thing.
So there's this idea of what I call causal invariance.
Causal invariance exactly.
So that's a really, really powerful, powerful idea.
It's a powerful idea, which is actually
a risen and different forms many times
in the history of mathematics, mathematical logic,
even computer science, has many different names.
I mean, our particular version of it
is a little bit tighter than other versions,
but it's basically the same idea.
Here's how to think about that idea.
So imagine that, well, let's talk about it
in terms of math for a second.
Let's say you're doing algebra and you're told, you know, multiply out this series of polynomials
that are multiplied together, okay? You say, well, which order should I do that in?
Say, well, do I multiply the third one by the fourth one and then do it by the first one,
or do I do the fifth one by the sixth one and then do that? Well, it turns out it doesn't matter.
You can multiply them out in any order, you'll always get the same answer. That's a property.
If you think about making a network that represents in what order you do things, you'll get different
orders for different ways of multiplying things out, but you'll always get the same answer.
Same thing, if you're sorting, you've got a bunch of A's and B's,
they're in random, some random audio,
BAA, BBBA, whatever.
And you have a little rule that says,
every time you see BAA flip it around to AB, okay?
Eventually you apply that rule enough times,
you'll have sorted the string
so that it's all the A's first and then all the B's.
Again, there are many different orders in which you can do that to many different places where you
can apply that update. In the end, you'll always get the string sorted the same way.
I know with sorting the string, it sounds obvious. That's to me surprising that there is in complicated systems obviously with a string, but in
a hypergraph that the application of a synchronous rule can lead to the same results sometimes.
Yes.
That is not obvious.
And it was something that I sort of discovered that idea for these kinds of systems.
And back in the 1990s, and for various reasons, I was not satisfied
by how fragile finding that particular property was.
Let me just make another point, which is that it turns out that even if the underlying
rule does not have this property of causal invariance, it can turn out that every observation made by observers of the rule
can, they can impose what amounts to causal invariance on the rule. We can explain that.
It's a little bit more complicated. I mean, technically, that has to do with this idea
of completions, which is something that comes up in term rewriting systems, automated
theorem proving systems and so on. But let's ignore that for a second. We can come to
that later.
Is it useful to talk about observation? Not yet. It's so great. So there's some concept of
causal invariance as you apply these rules in an asynchronous way. You can think of those transformations
as events. So there's this hypergraph that represents space and all these events happening in this space and the graph grows in interesting complicated ways.
And eventually the farth arises
to of what we experience as human existence.
So that's some version of the picture,
but let's explain a little bit more.
Yeah, that's exactly what's a little more detail.
Right, so one thing that is sort of surprising
in this theory is one of the sort of achievements
of the 20th century physics was kind of bringing space and time together.
That was, you know, special activity people talk about space time, this sort of unified
thing where space and time kind of are mixed.
And there's a nice mathematical formalism that in which space and time sort of appear as part of the space
time continuum, the space time, you know, four vectors and things like this. You know,
we talk about time as the fourth dimension and all these kinds of things. It's, you know,
and it seems like the theory of relativity sort of says space and time are fundamentally
the same kind of thing. So one of the things that took a while to understand in this approach of mine is that in my kind
of approach space and time are really not fundamentally the same kind of thing.
Space is the extension of this hypergraph.
Time is the kind of progress of this inexorable computation of these rules getting applied
to the hypergraph.
So they seem like very different kinds of things.
And so that at first seems like how can that possibly be right?
How can that possibly be Lorentz invariant?
That's the term for things being following the rules of special activity.
Well, it turns out that when you have causal invariants that, and let's see, it's worth explaining
a little bit how this works.
It's a little bit, a little bit elaborate.
But the basic point is that even though space and time
sort of come from very different places,
it turns out that the rules of sort of space time,
that special relativity talks about about come out of this model
when you're looking at large enough systems. So, so a way to think about this, you know, in terms of
the when you're looking at large enough systems, the part of that story is when you look at some fluid
like water, for example, there are equations that govern the flow of water.
Those equations are things that apply on a large scale.
If you look at the individual molecules,
they don't know anything about those equations.
It's just the sort of the large scale effect
of those molecules turns out to follow those equations.
And it's the same kind of thing happening in our models.
I know this might be a small point, but maybe a very big one.
We've been talking about space and time at the lowest level of the model, which is space,
the hypergraph time is the evolution of this hypergraph.
But there's also space time that we think about in general relativity for your special relativity.
Like, how does, how do you go from the lowest source code of space and times we're talking about to the more traditional terminology of space and time?
Yeah, right. So the key thing is this thing we call the causal graph.
So the causal graph is the graph of causal relationships between events.
So everyone of these little updating events, everyone of these little transformations of the
hypergraph happens somewhere in the hypergraph happens at some stage in the computation.
That's an event.
That event has a causal relationship to other events.
In the sense that if another event needs as its input, the output from the first event, there
will be a causal relationship of the future event will depend on the past event.
So you can say it has a causal connection.
So you can make this graph of causal relationships between events.
That graph of causal relationships, causal invariance implies that that graph is unique,
it doesn't matter, even though you think, oh, I'm, you know, let's say we were sorting
a string, for example, I did that particular transposition of characters at this time,
then I did that one, then I did this one. Turns out, if you look at the network of connections
between those updating events, that network is the same. It's the, if you were to...
I see.
...the structure. So in other words, if you were to draw that, if you were to put that network on a
picture of where you're doing all the updating, the places where you put the nodes of the network
will be different, but the way the nodes are connected will always be the same.
But the cause of graph is a... I don't know, it's kind of an observate.
It's not enforced, it's just emergent from set of events.
It's a feature of, okay, so what it is, the characteristic, I guess, is the way events
happen.
Right.
An event can't happen until its input is ready.
And so that creates this network of causal relationships. And that's the causal graph.
And the thing, the next thing to realize is, OK, when you're
going to observe what happens in the universe,
you have to sort of make sense of this causal graph.
So and you are an observer who yourself
is part of this causal graph.
And so that means, so let me give you
an example of how that works. So so that means, so let me give you an example
of how that works.
So imagine we have a really weird theory of physics
of the world, where it says this updating process,
there's only going to be one updated every moment in time.
And this is going to be like a touring machine.
It has a little head that runs around
and just is always just updating one thing at a time.
So you say, I have a theory of physics,
and the theory of physics says there's just this one little place where things get updated. You
say, that's completely crazy because, you know, it's plainly obvious that things are
being updated sort of, you know, it's interesting. Yeah, right. But, but, but, but the fact is that
the thing is that if I'm, you know, talking to you and you seem to be being updated as
I'm being updated, but, but if there's just this one little head that's running around updating things,
I will not know whether you've been updated or not until I'm updated.
So in other words, draw this causal graph of the causal relationship between the
updating and you and the updating and me, it'll still be the same causal graph,
whether even though the underlying sort of story of what happens is,
oh, there's just this one little thing and it goes on updates in different places in the universe.
So, is that clear or is that a hypothesis?
Is that clear that there's a unique causal graph?
If there's causal invariance, there's a unique causal graph.
So it's okay to think of what we're talking about as a hypergraph and the operations on it as a kind of touring machine with a single head like a single guy running around updating stuff.
Is that safe to intuitively think of it this way?
Let me think about that for a second. Yes, I think so. I think that I think there's nothing. It doesn't matter. I mean, you can say, okay, there is one,
the reason I'm pausing for a second is that,
I'm wondering, well, when you say running around,
depends how far it jumps every time it runs away.
Yeah, that's right.
But I mean, like, one operation.
Yeah, you can't think of it as one operation.
I'm just talking about it right now.
It's easier for the human brain to think of it that way
as opposed to
well maybe it's not okay, but the thing is that's not how we experience the world. What we
experience is we look around everything seems to be happening at successive moments in time
everywhere in space. Yes. That is the and that's partly a feature of our particular construction.
I mean that is the speed of light is really fast compared to, you know, we look around,
you know, I can see maybe a hundred feet away right now.
You know, it's the, my brain does not process very much.
In the time it takes light to co-100 feet.
The brain operates at a scale of hundreds of milliseconds or something like that.
I don't know.
Right.
And the speed of light is much faster.
Right.
You know, light goes in a billionth of a second, light has gone afoot.
So it goes a billion feet every second.
There's certain moments through this conversation where I imagine the absurdity of the fact
that there's two descendants of apes modeled by a hypergraph that are communicating with each
other and experiencing this whole thing as a real time simultaneous update with I'm taking in photons from you
right now, but there is something much, much deeper going on right here.
It does have a parallelizing time.
It's just to remember that.
Right.
No, I mean, you know, but so, you know, I, yes, yes.
As a small little tangent, I just remembered that we're talking about, I mean, this, about
the fabric of reality.
Right.
So we've got this causal graph that represents the sort of causal relationships between
all these events in the universe.
That causal graph kind of is a representation of space time, but our
experience of it requires that we pick reference frames.
This is kind of a key idea Einstein had this idea.
What that means is we have to say what are we going to pick as being the sort of what
we define as simultaneous moments in time.
So for example, we can say,
how do we set our clocks?
If we've got a spacecraft landing on Mars,
do we say that what time is it landing at?
Was it, even though there's a 20 minute speed
of light delay or something,
what time do we say it landed at?
How do we set up sort of time coordinates for the world?
And that turns out to be that's this kind of this
arbitraryness to how we set these reference frames
that defines sort of what counts as simultaneous.
And what is the essence of special relativity
is to think about reference frames going at different speeds
and to think about sort of how they assign
what counts as space, what counts as time and so on.
That's all a bit technical,
but the basic bottom line is that
the this causal invariance property
that means that it's always the same causal graph
independent of how you slice it with these reference frames,
you'll always sort of see the same physical processes go on, and that's basically why special arts have it, it works.
So there's something like special relativity, like everything around space and time that
fits this idea of the causal graph.
Right.
Well, one way to think about it is given that you have a basic structure that just involves updating things in these, you know, connected updates and looking at
the causal relationships from connected updates, that's enough. When you unravel the consequences
of that, that together with the fact that there are lots of these things and that you can
take a continuum limit and so on implies special relativity. And so that it's kind of
a not a big deal because it's kind of a you know, it was completely unobvious. When you
started off with saying we've got this graph, it's being updated in time, et cetera, et cetera,
that just looks like nothing to do with special relativity. And yet you get that. And what,
I mean, then the thing, I mean,
this was stuff that I figured out back in the 1990s,
the next big thing you get is general relativity.
And so, in this hypergraph, the sort of limiting structure,
when you have a very big hypergraph,
you can think of as being just like,
water seems continuous on a large scale.
So this hypergraph seems continuous on a large scale.
One question is, you know, how many dimensions of space does it correspond to?
So one question you can ask is if you just got a bunch of points and they're connected together,
how do you deduce what effective dimension of space that bundle of points corresponds to?
And that's that's pretty easy to explain. So basically,
if you say you've got a point and you look at how many neighbors does that point have, okay,
imagine it's on a square grid, then it'll have four neighbors. Go another level out, how many
neighbors do you get then? What you realize is, as you go more and more levels out, as you go more
and more distance on the graph out, you're capturing something which
is essentially a circle in two dimensions so that, you know, the number of the area of
a circle is pi r squared. So the, it's the number of points that you get to goes up like
the distance you've gone squared. And in general, in D-dimensional space, it's r to the power D. It's the number of points you get to,
if you go r steps on the graph, grows like,
the number of steps you go to,
the power of the dimension.
And that's a way that you can estimate
the effect of dimension of one of these graphs.
So what does that grow to?
So how does the dimension grow?
There's a, I mean, obviously,
the visual aspect of these hypergraphs, they're often visualized
in three dimensions.
And then there's a certain kind of structure.
Like you said, there's a circle, the sphere, there's a planar aspect to it, to this graph,
to where it kind of, it almost starts creating a surface, like a complicated surface, but a surface.
So how does that connect to affected dimension?
Okay, so if you can lay out the graph in such a way
that the points in the graph that,
you know, the points that are neighbors on the graph
are neighbors as you lay them out.
And you can do that in two dimensions,
then it's gonna approximate a two-dimensional thing. If you can't do that in two dimensions, if everything would have to fold over do that in two dimensions, then it's going to approximate a two-dimensional
thing. If you can't do that in two dimensions, if everything would have to fold over a lot
in two dimensions, then it's not approximating a two-dimensional thing. Maybe you can lay it
out in three dimensions. Maybe you have to lay it out in five dimensions to have it be
the case that it sort of smoothly lays out like that.
Well, but okay, so I apologize for the different tangent questions, but you know, there's an infinity number of possible rules.
So we have to look for rules that create the kind of structures that are reminiscent for
that have echoes of the different physics theories in them. So what kind of rules, is there something simple
to be said about the kind of rules
that you have found beautiful, that you have found powerful?
So, I mean, one of the features of computational
and irreducibility is it's very,
you can't say in advance what's going to happen
with any particular, you can't say,
I'm going to pick these rules from this part
of rules space, so to speak, because they're going to be the ones that are going to work.
That's, you can make some statements along those lines, but you can't generally say that.
Now, you know, the state of what we've been able to do is, you know, different properties
of the universe, like dimensionality, you know, integer dimensionality, features of,
of other features of quantum mechanics, things
like that. At this point, what we've got is we've got rules that, that any one of those
features we can get a rule that has that feature. So, yeah, so that they don't have the,
the sort of the final, here's a rule which has all of these features. We do not have that
yet. So, so if I were to try to summarize the Wolfram physics project, which
is something that's been in your brain for a long time, but really has just exploded in
activity only just months ago. So it's an evolving thing, and next week, I'll try to publish
this conversation as quickly as possible, because by the time it's published already, new things will probably have come up.
If I were to summarize it, we've talked about the basics of, there's a hypergraph that
represents space, there is transformations in the hypergraph that represents time, that
progress of time, there's a causal graph, there's a cause of graph, there's a characteristic
of this, and the basic process of science, of science within the Wolfram physics model
is to try different rules and see which properties of physics that we know of known physical
theories are appear within the graphs that emerge from that rule.
That's what I thought it was going to be.
Uh-oh, okay.
So what is it?
So what is it?
It turns out we can do a lot better than that.
It turns out that using kind of mathematical ideas,
we can say, and computational ideas,
we can make general statements, and those general statements
turn out to correspond to things that we know from 20th century physics. In other words,
the idea of you just try a bunch of rules and see what they do, that's what I thought
we were going to have to do. But in fact, we can say given causal invariance and computational
irreducibility, we can derive, and this is where it gets really pretty interesting,
we can derive special relativity, we can derive general relativity,
we can derive quantum mechanics.
And that's where things really start to get exciting,
is, you know, it wasn't at all obvious to me
that even if we were completely correct,
and even if we had, you know, this is the rule,
you know, even if we found the rule,
to be able to say, yes, it corresponds we had, you know, this is the rule, you know, even if we found the rule, to be able to say,
yes, it corresponds to things we already know, I did not expect that to be the case. And so for somebody who is a simple
mind and definitely not a physicist, not even close, what does derivation mean in this case?
Okay. So, so let me, this is an interesting question. Okay, so there's so one one thing in the context of competition
Redisibility. Yeah, yeah, right, right. So what you have to do let me get let me go back to again the mundane example of fluids and water and things like that, right?
So so you have a bunch of molecules bouncing around
You can say
Just as a piece of mathematics, I happen to do this
from Selina or Tomatah back in the mid-1980s, you can say, just as a matter of mathematics,
you can say the continuum limit of these little molecules bouncing around is the Navier-Stokes
equations. It's just a piece of mathematics. It doesn't rely on, you have to make certain assumptions that
you have to say there's enough randomness in the way the molecules bounce around that
certain statistical averages work, etc., etc., etc. Okay. It is a very similar derivation to
derive, for example, the Einstein equations. Okay. So the way that works, roughly, the
Einstein equations are about curvature of space. Coverture of space, I talked about sort of how you can figure out dimension of space.
There's a similar kind of way of figuring out if you're making a larger and larger ball
or larger and larger, if you draw a circle on the surface of the earth, for example,
you might think the area of a circle is pi r squared. But on the surface of the earth, because it's a sphere,
it's not flat, the area of a circle
isn't precisely pi r squared.
As the circle gets bigger, the area is slightly smaller
than you would expect from the formula pi r squared
as a little correction term that depends on the ratio
of the size of the circle to the radius of the earth.
Okay, so it's the same basic thing allows you to measure
from one of these hypergraphs. What is its effective curvature? And now, so the little piece of mathematics
that explains special general relativity is can map nicely to describe fundamental
property of the hypergraphs, the curvature of the hypergras.
So, special relativity is about the relationship of time to space.
General relativity is about curvature,
and this space represented by this hypergroth.
So, what is the curvature of a hypergrath?
Okay, so, first I have to explain,
what is explaining is, first thing you have to have is a notion of dimension.
You don't get to talk about curvature of things. If you say, oh, it's a
curved line, but I don't know what a line is yet. So yeah, what is the dimension of
a hypergraph then? Where from where we've talked about effective dimension, but
right, that's what that's what this is about. That's what this is about is you
have your hypergraph. It's got a trillion nodes in it. What is it roughly like?
Is it roughly like a grid, a two-dimensional grid? Is it roughly like all those nodes arranged online?
What's it roughly like? And there's a pretty simple mathematical way to estimate that by just looking at the
This thing I was describing this sort of the size of a ball that you construct in the hypergraph.
That's a, you just measure that, you can just, you know, compute it on a computer for a given hypergraph,
and you can say, oh, this thing is wiggling around, but it's roughly corresponds to two or something like that,
roughly corresponds to 2.6 or whatever.
So, that's how you, that's how you have a notion of dimension in these hypergraphs.
Curvature is something a little bit beyond that.
If you look at how the size of this ball
increases as you increase its radius,
curvature is a correction to the size increase
associated with dimension.
It's sort of a second order term in the determining size.
Just like the area of a circle is roughly pi r squared.
So it goes up like r squared. The circle is roughly pi r squared, so it goes
up like r squared, the two is because it's in two dimensions, but when that circle is
drawn on a big sphere, the actual formula is pi r squared times one minus r squared over
a squared and some coefficient. So in other words, there's a correction to, and that
correction term, that gives you curvature.
And that correction term is what makes this hypergraph correspond, have the potential to correspond to curved space.
Now, the next question is, is that curvature is the way that curvature works,
the way that Einstein's equations for general relativity, is that the way they say it should work.
And the answer is yes.
And so how does that work?
I mean, the calculation of the curvature of this hypergraph
for some set of rules, no, it doesn't matter what the rules are.
It doesn't so long as they have causal invariants
and computational irreducibility,
and they lead to finite dimensional space,
non-infinite dimensional space, non-infinite dimensional. It can grow infinitely, but it can't
be infinite dimensional. So what does an infinite dimensional hypergraph look like? So that, for
example, so in a tree, you start from one root of the tree, doubles again, doubles again, doubles again, and that means,
if you ask a question, starting from a given point, how many points do you get to? Remember,
in a circle, you get to R squared, the two there, on a tree, you get to, for example, two to the R.
It's exponential dimensional, so to speak, or infinite dimensional.
Do you have a sense of, in the space of all possible rules?
how many lead to
infinitely dimensional hypergrass?
Is that no?
Is that an important thing to know?
Yes, it's an important thing to know. I would love to know the answer to that
and but you know, it gets a little bit more complicated because for example
it's very possible to the case that in our physical universe that the universe started infinite dimensional. And it only, as
it, you know, at the big bang, it was very likely infinite dimensional. And as, as the
universe sort of expanded and cooled, its dimension gradually went down. And so one of the
bizarre possibilities, which actually, their experiments, you can do to try and look at this, the universe can have dimension fluctuations. So in other
words, we think we live in a three-dimensional universe, but actually there may be places
where it's actually 3.01 dimensional, or where it's 2.99 dimensional, and it may be that
in the very early universe, it was actually infinite dimensional, and it's only a late stage
phenomenon that we end up getting three-dimensional space.
If we're in your perspective of the high-programmed, one of the underlying assumptions kind of
implied, but you have a sense, a hope, set of assumptions that the rules that underlie
our universe, or the rule that underlies our universe is static.
Is that one of the assumptions
you're currently operating under?
Yes, but there's a footnote to that
which we should get to because it requires a few more steps.
Well, actually then let's backtrack to the curvature
because we're talking about as long as it's finite dimensional,
finite dimensional computational irreducibility and causal invariance,
then it follows that the large scale structure will follow
Einstein's equations.
And now, let me, again, qualify that a little bit more.
There's a little bit more complexity to it.
The, OK, so Einstein's equations in their simplest form apply to the vacuum,
no matter just the vacuum. And they say in particular what they say is if you have um uh so there's this
term GD-Sick that's a term that means shortest path comes from measuring shortest paths on the earth.
So you look at a bunch of a bundle of GD-6, a bunch of shortest
paths. It's like the paths that photons would take between two points. Then the statement
of Einstein's equations is basically a statement about a certain that as you look at a bundle
of GD-6, the structure of space has to be such that although the cross-sectional area of
this bundle may, although the actual shape of the cross section
may change, the cross sectional area does not.
That's a version that's a, that's the most simple minded
version of army new minus a half r, g mu new equals 0,
which is the more mathematical version of Einstein's equations.
It's a statement, it's a statement of the thing called the
richy tensor is equal to zero.
That's Einstein's equations for the vacuum.
So we get that as a result of this model, but footnote, big footnote,
because all the matter in the universe is the stuff we actually care about.
The vacuum is not stuff we care about.
So the question is how does matter come into this? And for
that, you have to understand what energy is in these models. And one of the things that
we realized last year was that there's a very simple interpretation of energy in these
models. And energy is basically, well, intuitively it's the amount of activity in these hypergraphs
and the way that that remains over time.
So a little bit more formally, you can think about this causal graph as having these
edges that represent causal relationships.
You can think about, oh boy, there's one more concept that we didn't get to. The notion of space-like hyper surfaces. So this is not as scary as it sounds.
It's a common notion in general, so it's a... The notion is you're defining what is a possibly...
meaning what is a possibly, what is, what, where in space time might be a particular moment in time.
So in other words, what is a consistent set of places where you can say, this is happening
now, so to speak.
And you make the series of, of sort of slices through the space time, through this causal graph to represent what we consider
to be successive moments in time. It's somewhat arbitrary because you can deform that if you're
going at a different speed and special activity, you tip those things, if you're, you know, there
are different kinds of deformations, but only certain deformations are allowed by the structure of the causal graph.
Anyway, be as it may.
The basic point is there is a way of figuring out, you know, you say, what is the energy
associated with what's going on in this hypergraph?
And the answer is there is a precise definition of that, and it is the formal way to say it
is it's the flux of causal
edges through space like hyper surfaces. The slightly less formal way to say it's basically
the amount of activity. The, see, the reason it gets tricky is you might say it's the amount
of activity per unit volume in this hypergraph, but you haven't defined what volume is. So
it's a little bit, you have to buy this hyper surface,
give some more formalism to that.
Yeah, yeah, it gives a way to connect that.
But intuitive we should think about as the,
the amount of activity.
Right, so the amount of activity
that kind of remains in one place
in the hypergraph corresponds to energy.
The amount of activity that is kind of where an activity here
affects an activity somewhere else because corresponds to momentum and
and
And so one of the things that's kind of cool is that I'm trying to think about how to say this intuitively the mathematics is easy
But the intuitive version I'm not sure but basically the way that things sort of stay in the same place and have activity
is associated with rest mass and so one of the things that you get to derive is E equals MC squared.
That is a consequence of this interpretation of energy in terms of the way the causal
graph works, which is the whole thing is sort of a consequence of this whole story about
updates and hypergraphs and so on.
So can you linger on that a little bit?
How do we get E equals
umc squared? So where does the mass come from? So, okay, okay, I mean, I, yeah, is there
an intuitive? So, okay, first of all, you're pretty deep in the mathematical explorations
of this thing right now. We're in a very, very, no flux. Currently, so maybe you haven't even had time to think about intuitive explanations.
But this one is, look, roughly what's happening, that derivation is actually rather easy.
And everybody, and I've been saying we should pay more attention to this derivation because
it's such, you know, because people care about this point.
But everybody says, it's just easy.
It's easy. But so there's some concept of energy that can be totally thought of as the activity,
the flux level, the level of changes that occurring based on the transformations within a certain
volume, however the heck do you find the volume? Okay. So, and then mass.
Well, mass is, what? Mass is associated with kind of the energy that does not cause you to, that does
not somehow propagate through time.
Yeah, I mean, one of the things that was not obvious in the usual formulation of special
activity is that space and time are connected in a certain way.
Energy and momentum are also connected in a certain way.
The fact that the connection
of energy to momentum is analogous to the connection to space between space and time is
not self-evident in ordinary relativity. It is a consequence of the way this model works.
It's an intrinsic consequence of the way this model works. And it's all to do with that
with unraveling that connection that ends up giving you this relationship between
energy and, well, energy, momentum, mass, they're all connected.
And so that's, hence the general relativity, you have a sense that it appears to be baked
in to the fundamental properties of the way these hypergraphs are evolved.
Well, I didn't yet get to, so I got as far as special relativity and equals MC squared.
The one last step is in general relativity, the final connection is energy, mass,
cause, curvature in space. And that's something that when you understand this interpretation of
energy and you kind of understand the correspondence to curvature and hypergraphs, then you can finally
sort of the big final answer is you derive the full version of Einstein's equations for space
time and matter. And that's some... So, is, have you, that last piece with curvature, have, is that, have
you arrived there yet?
Oh, yeah, we're with that.
Yes.
And here's the way that we, here's how we're really, really going to know we've arrived.
Okay.
So, you know, we have the mathematical derivation, it's all fine, but, but, you know, mathematical
derivations, okay.
So one thing that sort of a, a, you a, we're taking this limit of what happens when you have to
look at things which are large compared to the size of an elementary length, small compared
to the whole size of the universe, large compared to certain kinds of fluctuations, blah,
blah, blah.
There's a tower of many, many of these mathematical limits that have to be taken.
So if you're a pure mathematician saying, where's the precise proof?
It's like, well, there are all these limits.
We can, you know, we can try each one of them computationally and we can say, yeah, it
really works.
But the formal mathematics is really hard to do.
I mean, for example, in the case of deriving the equations of fluid dynamics from molecular
dynamics, that derivation has never been done.
There is no rigorous version of that derivation.
So, because you can't do the limits.
Yeah, because you can't do the limits.
But so the limits allow you to try to describe something
general about the system in very, very particular kinds of limits
that you need to take with these very...
Right, and the limits will definitely work the way we think they work.
And we can do
all kinds of computer exercises.
It's just the hard derivation.
Yeah, it's just the mathematical structure kind of, you know, ends up running right into
computational irreducibility, and you end up with a bunch of difficulty there.
But here's the way that we're getting really confident that we know completely what we're
talking about, which is, when people study things like black hole mergers using Einstein's equations, what do they actually do? Well, they actually
use mathematical a whole bunch to analyze the equations and so on. But in the end, they
do numerical relativity, which means they take these nice mathematical equations and
they break them down so that they can run them on a computer and they break them down
into something which is actually a discrete approximation to these equations. Then they run them on a computer,
they get results, then you look at the gravitational waves and you see if they match.
Turns out that our model gives you a direct way to do numerical relativity. So in other
words, instead of saying you start from these continuum equations from Einstein, you break
them down into these discrete things, you run them on a computer, you say, we're doing it the other way around. We're starting from these discrete
things that come from our model, and we're just running big versions of it on a computer,
and what we're saying is, and this is how things will work. So, the way I'm calling this
is proof by compilation, so to speak. That is, in other words, you're taking something where, you know, we've got this description
of a black hole system and what we're doing is we're showing that the, you know, what
we get by just running our model agrees with what you would get by doing the computation
from the Einstein equations. As a small tangent or actually a very big tangent but
proof by compilation is a beautiful concept. In a sense, the way of doing physics with this model
is by running it or compiling it. And-
It's unbelievable, yes.
Have you thought about, and these things can be very large,
is there totally new possibilities of computing hardware and computing software,
which allows you to perform this kind of compilation?
Well, algorithms software hardware.
So first comment is, these models seem to give one
a lot of intuition about distributed computing,
a lot of different intuition about how to think about
parallel computation.
And that particularly comes from the quantum mechanics side of things,
which we didn't talk about much yet.
But the question of what, you know, given our current computer hardware, how can we most
efficiently simulate things, that's actually partly a story of the model itself, because
the model itself has deep parallelism in it.
The ways that we are simulating it, we're just starting to be able to use that deep parallelism
to be able to be more efficient in the way that we simulate things.
But in fact, the structure of the model itself allows us
to think about parallel computation in different ways.
And one of my realizations is that, you know,
so it's very hard to get in your brain how you deal
with parallel computation.
And you're always worrying about, you know,
if multiple things can happen at different, on different computers
at different times, oh, what happens if this thing happens
before that thing? And we've really got, you know, we have these race conditions
where something can race to get to the answer
before another thing and you get all tangled up
because you know, which thing is gonna come in first.
And usually when you do parallel computing,
there's a big obsession to lock things down
to the point where you've had locks and mutexes
and God knows what else,
where you've arranged it so that there can only be one sequence of things that can happen.
So you don't have to think about all the different kinds of things that can happen.
Well, in these models, physics is throwing us into forcing us to think about all these possible things that can happen.
But these models, together with what we know from physics, is giving us new ways to think about all possible things happening about all these different things happening in parallel. And so I guess they have built-in
protection for some of the parallelism. Well, causal invariance is the built-in protection.
causal invariance is what means that even though things happen in different orders, it doesn't matter
in the end. As a person who struggled concurrent programming in Java with all the basic concepts
of concurrent programming, that if there could be built up a strong mathematical framework
for causal and variance, that's so liberating. That could be not just liberating, but really
powerful for massively distributed computation.
Absolutely.
No, I mean, you know, what's eventual consistency
and this, and distributed databases
is the center of the causal invariance idea.
Yeah. Okay.
So that's, but have you thought about,
you know, we're like really large simulations?
Yeah.
I mean, I was also thinking about,
look, the fact is, I was printing much of my life as a language designer, right?
So I can't possibly not think about,
you know, what does this mean for designing languages for parallel computation?
In fact, another thing that's one of these,
you know, I'm always embarrassed at how law enforcement has taken me to figure stuff out.
But, you know, back in the 1980s, I worked on trying
to make up languages for parallel computation.
I thought about doing graph-free writing.
I thought about doing these kinds of things,
but I couldn't see how to actually make the connections
to actually do something useful.
I think now physics is kind of showing us
how to make those things useful.
And so my guess is that in time,
we'll be talking about, we do parallel programming, we'll be talking about programming in a certain reference
frame, just as we think about thinking about physics in a certain reference frame. It's a certain
coordinateization of what's going on. We say, we're going to program in this reference frame.
Oh, let's change the reference frame to this reference frame. And then our program will seem
different and we'll have a different way to think about it, but it's still the same program underneath.
So let me ask on this topic because I put out that I'm talking to you. I got way more questions that I can deal with.
But what pops the minds, a question somebody asked on Reddit, I think, is please ask Dr. Wilfrum, what are the specs of the computer running the universe. So, we're talking about specs of hardware and software,
for simulations of a large scale thing,
what about a scale that is comparative to
something that eventually leads to the two of us talking about?
Right, right, right. So actually, I did try to estimate that.
We have to go a couple more stages before we can really get to that answer
because we're talking about this thing.
You know, this is what happens when you build
these abstract systems and you're trying to explain
the universe that quite a number of levels deep, so to speak.
But the...
You mean conception or like literally,
because you're talking about
small objects and there's yeah, it's 20 something. Yeah, right. It's it's it is conceptually
deep. And one of the things that's happening sort of structurally in this project is, you
know, there were ideas, there's another layer of ideas, there's another layer of ideas,
to get to the different things that correspond to physics. They're just different layers of ideas.
And they are, you know, it's actually probably, if anything, getting harder to explain this project,
because I'm realizing that the fraction of the way through that I am so far and explaining
this to you is less than, you know, it might be because we know more now, you know, in every
week basically, we know a little bit more. And like, those are just layers on the initial fundamental structure.
Yes, but the layers, you know, you might be asking me, you know, how do we get, you know,
the difference between fermions and bosons, the difference between particles that can be
all in the same state and particles that exclude each other.
Okay.
Last three days, we've kind of figured that out.
Okay. But, and it's've kind of figured that out. Okay. But
um, and it's very interesting. It's very cool. Um, it's very, uh, and those are some kind
of properties at a certain level layer of abstraction on the graph. Yes. Yes. And there's, and
there's, but the layers of abstraction are kind of their compound stacking up. So it's
difficult, but it, but okay, but the specs nevertheless remain the same.
The specs underneath, so I have an estimate.
So the question is, what are the units?
So we've got these different fundamental constants about the world.
So one of them is a speed of light, which is the, so the thing that's always the same
and all these different ways of thinking about the universe is the notion of time, because
time is computation.
And so there's an elementary time, which is sort of the, the, the amount of time because time is computation. And so there's an elementary time,
which is sort of the amount of time
that we ascribe to elapsing in a single computational step.
So that's the elementary time.
So then there's an elementary or whatever.
That's a constant.
It's whatever we define it to be.
Because I mean, we don't, you know,
we solve relative, it doesn't matter. It doesn't matter what it is
because it could be slow and it's just a number which we use to convert that to second, so to speak,
because we are experiencing things and we say this amount of time has elapsed, so to say.
But we're within this thing, so it doesn't matter. Right. But what does matter is the ratio,
It doesn't matter. Right.
But what does matter is the ratio of the spatial distance and this hypergraph to this moment
of time.
Again, that's an arbitrary thing, but we measure that in meters per second, for example,
and that ratio is the speed of light.
So the ratio of the elementary distance to the elementary time is the speed of light.
Okay.
Perfect. And so there's another, there are two other speed of light. Okay? Perfect.
And so there's another, there are two other levels of this.
Okay?
So there is a thing, which we can talk about,
which is the maximum entanglement speed,
which is a thing that happens at another level in this whole sort of story
of how these things get constructed.
That's a sort of maximum speed in quantum,
in the space of quantum states.
Just as the speed of light is a maximum speed in physical space, this is a maximum speed
in the space of quantum states.
There's another level, which is associated with what we call rural space, which is another
one of these maximum speeds we get to this.
So these are limitations on the system that are able to capture the kind of physical
universe, which would live in the quantum mechanical to. They are inevitable features of having a a rule that has only a finite amount of information
in the rule. So long as you have a rule that only involves a bounded amount, a limited
amount of only involving a limited number of elements, limited number of relations, it
is inevitable that there are these speed constraints. We knew about the one for speed of light, we didn't know about the one for maximum
of entanglement speed, which is actually something that is possibly measurable particularly in
black hole systems and things like this. But anyway, this is a long, long story short, you're asking
what the processing specs of the universe of the sort of computation of the universe.
There's a question of even what are the units
of some of these measurements, okay?
So the units I'm using are Wolfm language instructions
per second, okay?
Because you gotta have some, you know,
what computation that you're doing.
There gotta be some kind of frame of reference, right?
So because it turns out in the end,
there's sort of an arbitraryness
and the language that you use to describe the universe.
So in those terms, I think it's like 10 to the 500 or from language operations per second,
I think, is the, I think it's of that order.
You know, it's a scale of computation.
What about memory, if there's an interesting thing to say about storage and memory?
Well, there's a question of how many sort of atoms of space might there be, you know,
maybe 10 to the 400. We don't know exactly how to estimate these numbers. I mean, this is this is based on some
some I would say somewhat rickety way of estimating things
You know when they're start to be able to be experiments done if we're lucky
there will be experiments that can actually nail down some of these numbers and
Because of computation and reducibility
nailed down some of these numbers. And because of computation and reducibility, there's not much hope for very efficient
compression, like very efficient representation.
Does this question question? I mean, there's probably certain
things, you know, the fact that we can deduce, and a, okay,
the question is, how deep does the reducibility go? Okay, and I
keep on being surprised, it's a lot deeper than I thought.
One of the things is that there's a question of how much of the whole physics do we have to
be able to get in order to explain certain kinds of phenomena? Like, for example,
if we want to study quantum interference, do we have to know what an electron is? Turns out,
I thought we did, turns out we don't. I thought to know what energy is, we would have to know what an electron is? Turns out, I thought we did, turns out we don't.
I thought to know what energy is,
we would have to know what electrons were.
We don't.
So you get a lot of really powerful shortcuts.
Right.
There's a bunch of sort of bulk information about the world.
The thing that I'm excited about last few days, OK,
is the idea of fermions versus bosons, fundamental idea,
that I mean, the reason we have matter
that doesn't just self-destruct
is because of the exclusion principle
that means that two electrons can never be
in the same quantum state.
Is it useful for us to maybe first talk about
how quantum mechanics fits into the world
from physics model?
Yes, let's go there.
So we talked about general relativity.
Now, what have you found for quantum mechanics,
right within and outside of the world from physics?
Right.
So I mean, the key idea of quantum mechanics,
the typical interpretation is classical physics says a definite thing happens.
Quantum physics says there's this whole set of paths
of things that might happen, and we are just
observing some overall probability of how those paths work.
OK, so when you think about our hypergraphs
and all these little updates that are going on,
there's a very remarkable thing to realize, which is, if you say, well, which particular sequence of updates should you do?
Say, well, it's not really defined.
You can do any of a whole collection of possible sequences of updates.
Okay.
That set of possible sequences of updates defines yet another kind of graph that we call
a multi-way graph, and a multi-way graph just is a graph where at every node there is a choice of several
different possible things that could happen. So for example you go this way
go that way those are two different edges in the multi-way graph and you're
building up the set of possibilities. So actually like for example I just made
the one the multi-way graph for TicTac Toe. Okay?
So TicTac Toe is start off with some board that, you know, is everything as blank, and then
somebody can put down an X somewhere, an O somewhere, and then there are different possibilities.
At each stage, there are different possibilities.
And so you build up this multivay graph of all those possibilities.
Now, notice that, even in TicTacaktow, you have the feature that there can be something where you have
Two different things that happen and then those branches merge because you end up with the same shape
But you know the same configuration of the board even though you got there in two different ways
So the thing that sort of an inevitable feature of our models is that just like quantum mechanics suggests
Definite things don't happen.
Instead, you get this whole multi-way graph of all these possibilities.
Okay, so then the question is, so that's sort of a picture of what's going on. Now you say,
okay, well, quantum mechanics has all these features of all this mathematical structure and so on.
How do you get that mathematical structure? Okay, a couple of things to say. So quantum mechanics is actually, in a sense, two different
theories glued together. Quantum mechanics is the theory of how quantum amplitudes work,
that more or less give you the probabilities of things happening, and it's the theory of quantum
measurement, which is the theory of how we actually conclude definite things. Because the mathematics just gives you these quantum amplitudes,
which are more or less probabilities of things happening,
but yet we actually observe definite things in the world.
Quantum measurement has always been a bit mysterious.
It's always been something where people just say,
well, the mathematics says this, but then you do a measurement
and the philosophical arguments about what the measurement is.
But it's not something where there's a theory of the measurement.
Somebody on Reddit also asked, please ask Stephen to tell his story of this double-slide experiment.
Okay. Yeah, I can say that. Does that make sense?
Oh, yeah, it makes sense. Absolutely.
Why is this like a good way to discuss
a little bit? Let me explain a couple of things first. So, so the structure of quantum mechanics is mathematically quite complicated. One of the features, let's see, how to describe this.
Okay, so first point is there's this multi-way graph of all these different paths of things that can happen in the world.
And the important point is that these you can have
branchings and you can have mergings.
Okay, so this property turns out causal invariance
is the statement that the number of mergings
is equal to the number of branchings.
Yeah, so in other words, every time there's a branch,
eventually there will also be a merge.
In other words, every time there were two possibilities
of what might have happened, eventually those will merge.
Beautiful concept, by the way.
So that idea, okay.
So that's one thing,
and that's closely related to the sort of objectivity and quantum mechanics.
The fact that we believe definite things happen, it's because although there are all these different paths,
in some sense, because of course, the invariants, they all imply the same thing.
I'm cheating a little bit and saying that, but that's roughly the essence of what's going on.
Okay, next thing to think about is, you have this multi-way graph. It has all these different possible things that are happening.
Now we ask, this multi-way graph is sort of evolving with time. Over time it's branching, it's merging, it's doing all these things.
Okay?
The question we can ask is, if we slice it at a particular time, what do we see? And that slice represents in a sense something
to do with the state of the universe at a particular time.
So in other words, we've got this multi-way graph
of all these possibilities, and then we're asking,
and, and, okay, we take this slice,
this slice represents, okay,
each of these different paths corresponds
to a different quantum possibility for what's happening.
Right.
When we take the slice, we're saying,
what are the set of quantum possibilities
that existed at a particular time?
And when we say slice, you slice the graph
and then there's a bunch of leaves.
A bunch of leaves and those represent the state of things.
Right, but then, okay, so the important thing
that you are quickly picking up on is
that what matters is kind of how these leaves are related to each other. So a good way to tell
how leaves are related is just to say on the step before, did they have a common ancestor?
So two leaves might be, they might have just branched from one thing, or they might be far away,
you know, way, far apart in this graph, where to get to a common ancestor, maybe you have
to go all the way back to the beginning of the graph, all the way back to the beginning
of the...
There's some kind of measure of distance.
Right.
And that, but what you get is by making the slice, where you call it, branchial space,
the space of branches.
And in this branchial space, you have a graph that
represents the relationships between these quantum states in branch-yield space. And you have
this notion of distance in branch-yield space. Okay, so it's connected to a quantum entanglement.
Yes. Yes. It's basically the distance in branch-yield space is kind of an entanglement distance.
It's basically the distance in bronchial space is kind of an entanglement distance.
So this is a very nice model.
Right, it is very nice.
It's very beautiful.
It's, I mean, it's so clean.
I mean, it's really, you know, it tells one, okay.
So anyway, so then this bronchial space
has this sort of map of the entanglement
between quantum states.
So in physical space, we have, so you can say,
let's say the causal graph, and we can slice that at a particular time,
and then we get this map of how things laid out in physical space.
When we do the same kind of thing, there's a thing called the multi-way causal graph,
which is the analog of a causal graph for for the multiway system. We slice that. We get essentially the relationships between
things, not in physical space, but in the space of quantum states. It's like which quantum
state is similar to which other quantum state? Okay. So now, I think next thing to say
is just to mention how quantum measurement works. So quantum measurement has to do with reference frames
in branch-heal space.
So OK, so measurement in physical space,
it matters whether how we assign spatial position
and how we define coordinates in space and time.
And that's how we make measurements in ordinary space.
So we're making a measurement based on us sitting still here?
Are we traveling at half the speed of light and making measurements that way?
These are different reference frames in which we're making our measurements.
And the relationship between different events and different points in space and time
will be different depending on what reference frame we're in.
Okay. So then we have this idea of quantum observation frames,
which are the analog of reference frames,
but in branch-shell space.
And so what happens is what we realize is that a quantum measurement
is the observer is sort of arbitrarily determining this reference frame.
The observer is saying, I'm going to understand the world
by saying that space and time are
coordinated this way.
I'm going to understand the world by saying that quantum states and time are coordinated
in this way.
And essentially what happens is that, you know, the process of quantum measurement is a
process of deciding how you slice up this multi-way system in these quantum observation frames.
So in a sense, the observer, the way the observer enters
is by their choice of these quantum observation frames.
And what happens is that the observer,
because, okay, this is again,
another stack of other concepts, but anyway,
because the observer is computationally bounded,
there is a limit to the type of quantum observation frames that they can construct.
Interesting.
Okay.
So there's some constraints, some limit on the choice of observation frames.
Right.
And by the way, I just want to mention that there's a, I mean, it's bizarre, but there's
a hierarchy of these things.
So in thermodynamics, the fact that we believe entropy increases,
we believe things get more disordered, there's a consequence of the fact that we can't track
each individual molecule. If we could track every single molecule, we could run every
movie and reverse, so to speak, and we would not see that things are getting more disordered.
But it's because we are computationally bounded, We can only look at these big blobs of what all these molecules collectively do,
that we think that things are, that we describe it
in terms of entropy increasing and so on.
And it's the same phenomenon, basically.
Also, consequence of computational irreducibility
that causes us to basically be forced to conclude
that definite things happen in the world,
even though there's
this quantum, you know, there's set of all these different quantum processes that are going on.
So, I mean, I'm skipping a little bit, but that's a rough picture.
And in the evolution of the World from Physics Project, where do you feel
stand on the some of the puzzles that are along the way? See, you're skipping a long bunch of
stand on some of the puzzles that are along the way. See, you're skipping along a bunch of,
you're skipping a bunch of stuff.
It's amazing how much these things are unraveling.
I mean, you know, these things, look,
it used to be the case that I would agree with Dick Feynman,
nobody understands quantum mechanics, including me.
Okay.
I'm getting to the point where I think I actually
understand quantum mechanics.
My exercise, okay, is can I explain quantum mechanics
for real at the level of kind of middle school type
explanation?
Right.
And I'm getting closer. It's getting there. I'm not quite there. I've tried it a few times.
And I realized that there are things that, where I have to start talking about elaborate
mathematical concepts and so on. But I think, and you've got to realize that it's not self-evident
that we can explain, you can explain at an intuitively graspable
level something which about the way the universe works. The universe wasn't built for our
understanding, so to speak. But I think then, then, okay, so another important idea is
this idea of branchial space, which I mentioned, this sort of space of quantum states.
It is, okay, so I mentioned Einstein's equations describing, you know, the effect of mass
and energy on trajectories of particles, on GD6.
The curvature of physical space is associated with the presence of energy according to Einstein's equations.
So it turns out that rather amazingly,
the same thing is true in branchial space.
So it turns out the presence of energy
or more accurately Lagrangian density,
which is a kind of relativistic invariant version
of energy, the presence of that causes essentially
deflection of GD6 in this branchial space.
So you might say so what?
Well, it turns out that the sort of the best formulation we have of quantum mechanics,
this Feynman path integral, is a thing that describes quantum processes in terms of mathematics that can be interpreted as,
well, in quantum mechanics, the big thing is you get these quantum amplitudes,
which are complex numbers that represent when you combine them together,
represent probabilities of things happening.
And so the big story has been, how do you derive these quantum amplitudes?
And people think these quantum amplitudes,
they have a complex number, has real part and imaginary part.
You can also think of it as a magnitude and a phase.
And people have thought these quantum amplitudes
have magnitude and phase, and you compute those together.
Turns out that the magnitude and the phase
come from completely different places.
The magnitude comes, OK, so how do you compute things in quantum mechanics?
Roughly, I'm telling you, I'm getting there to be able to do this at a middle school level,
but I'm not there yet. The roughly what happens is, you're asking, does this state-in-quantum mechanics
evolve to this other state-in-quantum mechanics? And this other state-in-quantum mechanics.
And you can think about that like a particle traveling, or something traveling through physical space,
but instead it's traveling through branchial space.
And so what's happening is does this quantum state evolve to this other quantum state?
It's like saying does this object move from this place in space to this other place and space. Okay? Now, the way that you,
these quantum amplitudes, characterize kind of, to what extent the thing will successfully
reach some particular point in branchial space, just like in physical space, you could say,
oh, it had a certain velocity and it went in this direction. In branchial space, there's
a similar kind of concept. Is there a nice way to visualize for me now mentally,
branchial space?
It's just you have this hypergraph.
It's sorry, you have this multiway graph.
It's this big branching thing, branching and merging thing,
but I mean, I'm just trying to understand what that looks like.
Is it?
You know, that space is probably exponential
dimensional, which makes it again, another
can of worms in understanding what's going
on that space as in ordinary space, this
hypergraph, the spatial hypergraph limits
to something which is like a manifold, like
a like something like through dimensional
space, almost certainly the multi-way graph
limits to a Hilbert space, which is something that,
I mean, it's just a weirder exponential dimensional space.
And by the way, you can ask,
I mean, there are much weirder things that go on.
For example, one of the things I've been interested in
is the expansion of the universe in branch-ill space.
So we know the universe is expanding in physical space,
but the universe is probably also expanding in branch-ial space. So we know the universe is expanding in physical space, but the universe
is probably also expanding in bronchial space. So that means the number of quantum states of
the universe is increasing with time. The diameter of the thing is growing.
Right, so that means that the, and by the way, this is related to whether quantum computing can have a work. And why?
Okay, so let me explain why.
So let's talk about, okay, so first of all,
just to finish the thought about quantum amplitudes,
the incredibly beautiful thing,
but I'm just very excited about this.
The fine path integral is this formula,
it says that the quantum amplitude is e to the is over h bar, where s that the amplitude, the quantum amplitude, is e to the
ISOH bar, where S is the thing called the action, and it, okay, so that can be thought of
as representing a deflection of the angle of this path in the multiray graph. So it's
a deflection of a GDSick in the multiray path that is caused by this thing called the action,
which is essentially associated with the energy.
And so this is a deflection of a path in branchial space that is described by this path integral
which is the thing that is the mathematical essence of quantum mechanics.
Turns out that deflection is the deflection of GD-SIG in branchial space follows the exact same mathematical setup as the
deflection of GD6 in physical space. Except the deflection of GD6 in physical space is
described with Einstein's equations, the deflection of GD6 in branchial space is defined by the
fine and path integral and they are the same. In other words, they are mathematically the same. So that means that general utility is a story of essentially
motion in physical space.
Quantum mechanics is a story of essentially motion
in bronchial space.
And the underlying equation for those two things,
although it's presented differently because one's interested
in different things in bronchial space and in physical space.
But the underlying equation is the same. So in other words, it's the, it's just,
you know, these two theories, which are the two sort of pillars of
20th century physics, which have seemed to be often
different directions, are actually facets of the exact same
theory. And this, I mean, that's exciting to see, to see where
there evolves, and exciting that that just is there. Right, I mean, that's exciting to see, to see where that evolves and exciting that that just is there.
Right. I mean, to me, you know, look, I, having spent some part of my early life, you know, working in these, in the context of these theories of, you know, 20th century physics, it's, they just, they seem so different.
And the fact that they're really the same is just really amazing.
Actually, I mean, you mentioned double-slut
experiment. Okay, so the double-slut experiment is an interference phenomenon where you say there,
you know, you can have a photon or an electron and you say there are these two slits that could have
gone through either one, but there is this interference pattern where it's, there's destructive interference
where you might have said in classical physics, oh well, if there are two slits, then there's a better chance that it gets through one or the other
of them. But in quantum mechanics, there's this phenomenon of destructive interference. That means
that even though there are two slits, two can lead to nothing, as opposed to two leading to more,
than, for example, one slit. And in what happens in this model,
and we've just been understanding this
in the last few weeks actually,
is that what essentially happens is that
the double slit experiment is a story of the interface
between bronchial space and physical space.
And what's essentially happening is
that the destructive interference is the result of
the two possible
paths associated with photons going through those two slits winding up at opposite ends
of branchial space.
And so that's why there's sort of nothing there when you look at it is because these two
different sort of branches couldn't get merged together to produce something that you
can measure in physical space.
Is there a lot to be understood about barren shell space?
Like is it a lot more than that?
Yes, it's a very beautiful mathematical thing and it's very, I mean, by the way, this
whole theory is just amazingly rich in terms of the mathematics that it says should exist.
Okay, so for example, calculus, you know,
is a story of infinitesimal change in
integer dimensional space, one dimensional,
two dimensional, three dimensional space.
We need a theory of infinitesimal change
in fractional dimensional and dynamic dimensional space.
No such theory exists.
So there's tools of mathematics that are in need of here.
Right, and this is a motivation for that actually.
Right, and it's, you know, there are indications and we can do computer experiments So there's tools of mathematics that are needed to hear. Right. And this is a motivation for that actually. Right.
And it's, you know, there are indications
and we can do computer experiments
and we can see how it's going to come out.
But we need to, you know, the actual mathematics
doesn't exist.
And in branchial space, it's actually even worse.
There's even more sort of layers of mathematics
that are, you know, we can see how it works
roughly by doing computer experiments,
but to really understand it, we need more sort of mathematical sophistication.
But quantum computers.
Okay, so the basic idea of quantum computers, the promise of quantum computers is quantum
mechanics does things in parallel, and so you can sort of intrinsically do computations in
parallel, and somehow that can be much intrinsically do computations in parallel. And somehow that
can be much more efficient than just doing them one after another. And you know, I actually
worked on quantum computing a bit with Dick Feynman back in 1981, 23, that kind of time for
him. And we fast-aying image. You and Feynman were in quantum computers.
Well, we tried to work the big thing we tried to do
was invent a randomness chip that would generate randomness
at a high speed using quantum mechanics.
And the discovery that that wasn't really possible
was part of the story of, we never really
wrote anything about it.
I think maybe he wrote some stuff,
but we didn't write stuff about what we figured out about sort of the fact that it really seemed like the measurement process
and quantum mechanics was a serious damper on what was possible to do in sort of, you
know, the possible advantages of quantum mechanics and for computing. But anyway, so the
sort of the promise of quantum computing is, let's say you're trying to, you know, factor
in integer. Well, you can, instead of, you know, computing is, let's say you're trying to factor an integer.
Well, you can, instead of, you know,
when you factor an integer, you might say,
well, does this factor work?
Does this factor work?
Does this factor work?
In ordinary computing, it seems like we pretty much
just have to try all these different factors,
you know, kind of one after another.
But in quantum mechanics, you might have the idea,
oh, you can just sort of have the physics, try all of them in parallel. Okay? And the, you know, and there's this algorithm,
shores algorithm, which allows you, according to the formalism of quantum mechanics, to do
everything in parallel and to do it much faster than your quantum classical computer.
Okay. The only little footnote is you
have to figure out what the answer is.
You have to measure the result.
So the quantum mechanics internally
has figured out all these different branches,
but then you have to pull all these branches together
to say, and the classical answer is this.
The standard theory of quantum mechanics does not tell you
how to do that.
It tells you how the branching works,
but it doesn't tell you the process of corralling
all these things together.
And that process, which intuitively you can see,
is going to be kind of tricky,
but our model actually does tell you
how that process of pulling things together works.
And the answer seems to be, we're not absolutely sure.
We've only got to two times three so far,
and which is kind of in this factorization
in quantum computers, but what seems to be the case
is that the advantage you get from the parallelization
from quantum mechanics is lost from the amount
that you have to spend pulling together
all those parallel threads to get to a classical answer
at the end. Now, that phenomenon is not unrelated to various
decoherence phenomena that are seen in practical quantum computers and so on.
I mean I should say as a very practical point I mean it's like should people
stop bothering to do quantum computing research? No because what they're really
doing is they're trying to use physics to get to a new level of what's
possible in
computing. And that's a completely valid activity. Whether you can really put, you know, whether
you can say, oh, you can solve an NP-complete problem, you can reduce exponential time
to polynomial time, you know, we're not sure. And I'm suspecting the answer is no, but
that's not relevant to the practical speedups you can get by using different kinds
of technologies, different kinds of physics to do basic computing.
But you're saying, I mean, some of the models you're playing with, the indication is that
to get all the sheep back together, and to corral everything together to get the actual solution
to the algorithm is, you lose all the users, also.
By the way, I mean, so again, this question,
do we actually know what we're talking about
about quantum computing and so on?
So again, we're doing proof-by-compilation.
So we have a quantum computing framework
and multiple language, which is standard quantum, we're getting framework that represents things in terms of the standard,
you know, formalism of quantum mechanics.
And we have a compiler that simply compiles the representation of quantum gates into multi-way systems.
So, and in fact, the message that I got was from somebody who's working on the project who has managed to compile one of the sort of core formalism based on category theory and core quantum
formalism into multi-way systems.
So, these multi-way systems, these multi-way graphs?
Yes.
So, you're a different component.
Yeah, okay, that's awesome.
And then you can do the all kinds of experiments and then multi-way graph.
Right. But the point is that what we're saying is the thing, we've got this representation of,
let's say, Schoer's algorithm in terms of standard quantum gates. And it's just a pure matter of
sort of computation to just say that is equivalent. We will get the same result as running this
multi-way system. Can you do a complex thing in our system on their multi-way system?
Well, that's what we're trying to do. Yes, we're
getting there. We haven't done that yet. I mean, we, we, there's a
pretty good indication of how that's going to work out. And we've
done it, as I say, our computer experiments, we've unimpressively
gotten to about two times three in terms of factorization, which
is kind of about how far people have got with physical
quantum computers as well. But, but that's some, but yes, we will be able to,
we definitely will be able to do complexity analysis and we will be able to know. So the one
remaining hope for quantum computing really, really working at this formal level of quantum
brand, exponential stuff being done in polynomial time and so on. The one hope, which is very bizarre,
is that you can kind of piggyback on the expansion
of branchial space.
So here's how that might work.
So you think energy conservation, standard thing in high school physics, energy is conserved,
right?
But now you imagine, you think about energy in the context of cosmology and the context
of the whole universe.
It's a much more complicated story.
The expansion of the universe kind of violates energy
conservation.
And so for example, if you imagine you've got two galaxies,
they're receding from each other very quickly.
They've got two big central black holes.
You connect a spring between these two central black holes.
Not easy to do in practice, but let's imagine you could do it.
Now, that spring is being pulled apart, it's getting more potential energy in the spring,
as a result of the expansion of the universe.
So, in a sense, you are piggybacking on the expansion that exists in the universe
and the sort of violation of energy conservation that's associated with that
cosmological expansion to essentially get energy,
you're essentially building up a petrol-motion machine by using the expansion of the universe. that's associated with that cosmological expansion to essentially get energy,
you're essentially building up a petrol motion machine
by using the expansion of the universe.
And that is a physical version of that.
It is conceivable that the same thing can be done
in branchial space to essentially mine
the expansion of the universe in branchial space
as a way to get sort of quantum computing for free,
so to speak, just from the expansion of the universe in branchial space. Now, the physical
space version is kind of absurd and involves, you know, springs between black holes and so on.
It's conceivable that the branchial space version is not as absurd and that it's actually
something you can reach with physical things you can build in labs and so on.
We don't know yet.
Okay, so yeah, you were saying the branch of space I'd be expanding and there might be some something that could be exploited.
Right.
In the same kind of way that you can exploit the, you know, that expansion of the universe in principle, in a physical space.
You just have like a glimmer of hope, right?
I think that the, look, I think the real answer
is going to be that for practical purposes,
the official brand that says you can,
you can do exponential things
upon a number of times probably not gonna work.
For people curious to kind of learn more,
so this is more like, this is not middle school,
we're gonna go to elementary school for a second. Maybe me let's go to middle school. So if I were to try to maybe
write a pamphlet of like Wolfram Physics Project for dummies, a K A for me, or maybe make a video on the basics, but not just the basics of the physics project,
but the basics plus the most beautiful central ideas.
How would you go about doing that?
Could you help me out a little bit?
Yeah, yeah, I mean, you know,
a lot of practical matter.
We have this kind of visual summary picture that we made, which I think is a pretty good, you know, when I try
to explain this to people and, you know, it's a pretty good place to start. As you got this
rule, you know, you apply the rule, you're building up this, this big hypergraph, you've
got all these possibilities, you're kind of thinking about that in terms of quantum
mechanics. I mean, that's a,'s a that's a decent place to start
So basically the things we've talked about which is space for representatives a hypergraph
transformation of their space is kind of time. Yes, and then
Stuck of that space and took the curvature of that space as gravity
That's that can be explained
without going anywhere in the quantum mechanics. I would say that's actually easier to explain
than special relativity. Oh, so going into general, so going into curvature. Yeah, I mean,
special relativity, I think is, it's a little bit elaborate to explain. Yeah. And honestly,
you only care about it if you know about special relativity. If you know how special relativity is ordinarily derived and so on.
So I think-
General relativity is easier.
It's easier, yes.
And it's what about quantum?
What's the easiest way to reveal-
I think the basic point is just this fact that there are all these different branches
that there's this kind of map of how the branches work.
And that, I mean, I think actually the recent things
that we have about the double slut experiment are pretty good,
because you can actually see this,
you can see how the double slit phenomenon arises
from just features of these graphs.
Now, having said that, there is a little bit of slight
of hand there, because the true
story of the way that double-slip thing works depends on the co-ordination of branchial
space that, for example, in our internal team, there is still a vigorous battle going
on about how that works.
And what's becoming clear is, I mean, what's becoming clear is that it's mathematically really quite
interesting. I mean, that is that there's a, you know, it involves essentially putting
space-filling curves. You basically have a thing which is naturally too dimensional and
you're sort of mapping it into one dimension with a space-filling curve and it's like,
why is it this space-filling curve and another space-filling curve? And that becomes a story
about reman surfaces and things and it's quite elaborate.
But there's a little bit slight of hand way of doing it where it's surprisingly direct.
So a question that might be difficult to answer, but for several levels of people, could
you give me advice on how we can learn more?
Specifically
There is people that are completely outside and just curious and are captivated by the beauty of hypergraphs actually
So people that just want to explore play around with this a second level is people from
Say people like me,
who somehow got a PhD in computer science, but are not physicists.
And but fundamentally, the work you're doing
is of computational nature.
So it feels very accessible.
Yes.
So what are, what can a person like that do to learn
enough physics or not to be able to one explore
the beauty of it and two, the final level of contribute something of a level of even
publishable, you know, like strong, interesting ideas at all those layers.
Complete beginner, you know, I ICS person and the CS person
that wants to publish.
Right, I mean, I think that, you know,
I've written a bunch of stuff,
doesn't go to Jonathan Gouraud
who's been a key person working on this project,
source for written a bunch of stuff,
and some of the people started writing things too.
And he's a physicist.
Physist.
Well, I would say a mathematical physicist.
A mathematical physicist. He's pretty mathematically sophisticated.
He regularly out-mathematicizes me. Strong mathematical physicist. I looked at some of
the papers. I wrote this kind of original announcement, blogged post about this project, which
people seem to have found. I've been really happy actually that people who, you know, people seem to have grok'd key points from that. Much deeper key points,
people seem to have grok'd than I thought they would grok.
And that's a kind of a long blog post. They explain some of the things we've talked about,
like the hypergraph and the basic rules. Yes. And I don't, does it?
I forget.
It doesn't have any quantum mechanics.
Oh, yeah.
It does.
It does.
But we know a little bit more since that blog post that probably clarifies, but that blog post
does a pretty decent job.
And you know, talking about things like again, something you didn't mention, the fact that
the uncertainty principle is a consequence of curvature and branchial space.
How much physics should a person know to be able to understand the beauty of this framework
and to contribute something novel?
I think that those are different questions.
I think that the why does this work, why does this make any sense?
To really know that, you have to know a fair amount of physics. Okay?
And for example, how about,
when you say why does this work,
you're referring to the connection between this model
and general relativity, for example.
In general relativity.
You have to understand something about general relativity.
There's also a side of this where just
as the pure mathematical framework is fascinating.
Yes, if you throw the physics out.
Right.
Then it's quite accessible to, I mean, I wrote this sort of long technical introduction to the project,
which seems to have been very accessible to people who understand computation and
formal abstract ideas, but are not specialists in physics or other kinds of things. I mean, the thing with the physics part of it is, you know,
it's, there's both a way of thinking and a,
literally a mathematical formalism.
I mean, it's like, you know, to know that we get the Einstein equations,
to know we get the energy momentum tensor,
we kind of have to know what the energy momentum tensor is,
and that's physics.
I mean, that's kind of graduate level physics, basically. And so, so that, you know, making that final connection
is requires some depth of physics knowledge.
I mean, that's the unfortunate thing. The difference between machine learning and physics
in the 21st century. Is it really out of reach of a year or two worth of study?
No, you could get it in a year or two.
But you can't get it in a month.
Right.
I mean, so it doesn't require necessarily like 15 years.
No, it does not.
And in fact, a lot of what has happened with this project
makes a lot of this stuff much more accessible.
There are things where it has been quite difficult to explain
what's going on, and it requires much more
you know having the
Concreteness of being able to do simulations knowing knowing that this thing that you might have thought was just an analogy is really actually what's going on
Makes one feel much more secure about just sort of saying this is how this works
And I think it will be you know the I'm hoping the textbooks of the future,
the physics textbooks of the future, there will be a certain compression. There will be things
that used to be very much more elaborate. Because, for example, even doing continuous mathematics
versus this discrete mathematics, you know, to know how things work and continuous mathematics,
you have to be talking about stuff and waving your hands about things. Whereas, with discrete
the discrete version, it's just like, here is a picture.
This is how it works.
And there's no, oh, did we get the limit right?
Did this thing that is of zero, measure zero object
interact with this thing in the right way?
You don't have to have that whole discussion.
It's just like, here's a picture.
This is what it does.
And then it takes more effort to say, what does it do in the limit when
the picture gets very big? But you can do experiments to build up an intuition actually.
Yes, right. And you can get sort of core intuition for what's going on. Now, in terms of
contributing to this, the, you know, I would say that the study of the computational
universe and how all these programs work in the computational universe, there's just
an unbelievable amount to do there
and it is very close to the surface.
That is, you know, high school kids, you can do experiments,
it's not, you know, and you can discover things.
I mean, you know, we, you can discover stuff about,
I don't know, like this thing about expansion of branchial space,
that's an absolutely accessible thing to look at.
Now, you know, the main issue with doing these things is not there isn't a lot of technical
depth difficulty there.
The actual doing of the experiments, you know, all the code is all on our website to do all
these things.
The real thing is sort of the judgment of what's the right experiment to do, how do you interpret
what you see. That's the part that, you know right experiment to do, how do you interpret what you see?
That's the part that people will do amazing things with, and that's the part. But it isn't like you have to have done ten years of study to get to the point where you can do
the experiments. A cool thing, you can do experiments day one basically. That's the amazing thing about
and you've actually put the tools out there. Yeah, it's as beautiful and some mysterious.
There's still I would say maybe you can correct me.
It feels like there's a huge number of log hanging fruit on the mathematical side at least,
not the physics side perhaps.
No, look, on the, okay, on the physics side, we are, we're definitely in harvesting mode,
of which fruit, the low hanging ones are...
The low hanging ones, yeah.
Right.
I mean, basically here's the thing.
There's a certain list of, you know, here are the effects in quantum mechanics, here are
the effects in general relativity.
It's just like industrial harvesting.
It's like, can we get this one, this one, this one, this one, this one, this one?
And the thing that's really, you know, interesting and satisfying, and it's like, you know,
is one climbing the right mountain, does one have the right model.
The thing that's just amazing is, you know, we keep on like, are we going to get this one?
How hard is this one? It's like, oh, you know, it looks really hard, it looks really hard.
Oh, actually, we can get it. And you're continuously surprised.
I mean, it seems like I've been following your progress.
It's kind of exciting.
All the inharvesting mode, all the things you're picking up a lot.
Right.
No, I mean, it's the thing that is, I keep on thinking it's going to be more difficult
than it is.
Now, that's a, you know, that's a, who knows what, I mean, the one thing.
So the, the, the, the thing that's been a,
was a big thing that I think we're pretty close to,
I mean, I can give you a little bit of the roadmap,
it's sort of interesting to see,
it's like, what are particles?
What are things like electrons?
How do they really work?
Are you close to get, like, what's,
are you close to trying to understand,
like the atom, the electrons, the electrons,
protons, like, the particles?
Okay, so this is the stack. So the first thing we want to understand like the atom, the electrons, the insurance, the portons. Okay, so this is the stack.
So the first thing we want to understand
is the quantization of spin.
So particles, they kind of spin,
they have a certain angular momentum.
That angular momentum, even though the masses of particles
are all over the place,
the electron has a mass of 0.511mmV,
the proton is 938mmV, et cetera, et cetera, et cetera.
They're all kind of random numbers.
The spins of all these particles that are either integers or half integers.
And that's a fact that was discovered in the 1920s, I guess.
I think that we are close to understanding why spin is quantized.
And that's a, and it appears to be a quite elaborate
mathematical story about homotopy groups
in Trista space and all kinds of things.
But bottom line is that seems within reach.
And that's a big deal because that's a very core feature
of understanding how particles work in quantum mechanics.
Another core feature is this difference
between particles that
obey the exclusion principle and sort of stay apart, that leads to the stability of matter
and things like that, and particles that love to get together and be in the same state,
things like photons, that, and that's what leads to phenomena like lasers, where you can
get sort of coherently everything in the same state. That difference is the particles
of interjust spin or bosons like to get together in the same state, the particles of half interjust
spin of fermions like electrons that they tend to stay apart. And so the question is, can we
can we get that in our models? And oh, just the last few days, I think we made, I mean, I think
the story of, I mean, it's
one of these things where we're really close.
It's just connected from the hands of Bosons.
Yeah, yeah, yeah.
So this was what what happens is what seems to happen, okay?
It's, you know, subject to revision, next few days.
But what seems to be the case is that Bosons are associated with essentially merging in multiway graphs and
fermions are associated with branching in multiway graphs.
And that essentially the exclusion principle is the fact that in branchial space things
have a certain extent in branchial space that in which things are being sort of forced
to part in branchial space whereas the case of bosons, they get, they, they come together in bronchial space. And the real question is, can we explain
the relationship between that and these things called spinners, which are the representation
of half-entered-spin particles that have this weird feature that usually when you go around
360-degree rotation, you get back to where you started from. But for a spinner, you don't
get back to where you started from. It takes 720 degrees of rotation to get back to where you started from.
And we are just, it feels like we are, we're just incredibly close to actually having that,
understanding how that works.
And it turns out it looks like my current speculation is that it's as simple as the directed
hypergraphs versus undirected hypergraphs. It's interesting.
The relationship between spinners and vectors.
So it's just interesting.
Yeah, that'd be interesting.
If these are all these kind of nice properties
of this multi-way graphs of branching
and rejoining.
But spinners have been very mysterious.
And if that's what they turn out to be,
there's going to be an easy explanation
that they're not directed or are undirected. It's just, and that's why there's only two different cases.
It's, well, why are spinners important in quantum mechanics?
Can you just give a, yeah, so spinners are important
because they are, they're the representation of electrons,
which have half an inch of spin.
They are the wave functions of electrons are spinners, just like the wave functions of electrons, our spinners. Just like the wave functions
of photons are vectors, the wave functions of electrons are spinners. And they have this
property that when you rotate by 360 degrees, they come back to minus one of themselves and
take 700 or 20 degrees to get back to the original value. And they are a consequence of, we usually think of rotation in space as being, you know,
when you have this notion of rotational invariance and rotational invariance, as we ordinarily
experience it, doesn't have the feature.
You know, if you go 3,300 degrees, you go back to where you started from, but that's not
true for electrons. And so that's why understanding how that works is important.
Yeah, I've been playing with Mobius, uh, Strobe quite a bit lately, just for fun.
Yes, yes. It has some funk, it has the same kind of funky property, right? Exactly. You can have
this the so-called belt trick, which is this way of taking an extended object, and you can see
properties like spinners with that kind of extended object.
That would be very cool if there's somehow connects the directive or a sender active.
I think that's what it's going to be.
It's going to be as simple as that.
But we'll see.
This is the thing that, you know, this is the big sort of bizarre surprise, is that, you
know, because, you know, I learnt physics is probably, let's say, let's say a fifth generation,
in the sense that, you know, if you go back to the 1920s
and so on there,
where the people who were originating quantum mechanics
and so on, maybe it's a little less than that.
Maybe I was like a third generation or something,
I don't know, but, you know, the people from whom I learnt
physics were the people who were, you know,
who had been students of the students
of the people who originated, students of the students of the people who
originated the current understanding of physics. And we're now at probably
the seventh generation of physicists or something from the early days of
20th century physics. And whenever a field gets that many generations deep, it
seems the foundations seem quite inaccessible. And they seem, you know, it seems like you can't possibly understand that.
We've gone through, you know, seven academic generations.
And that's been, you know, that's been this thing that's been difficult to understand
for that long.
It just can't be that simple.
And by, in a sense, maybe that journey takes you to a simple explanation that was there all along.
That's the whole thing. maybe that journey takes you to a simple explanation that was there all along. Right, right. I mean, and the thing for me personally, the thing that's been quite interesting is,
you know, I didn't expect this project to work in this way. And I, you know, but I had this sort of
weird piece of personal history that I used to be a physicist. And I used to do all this stuff,
and I know, you know, the standard canon of physics, I knew it very well. But then I've
been working on this computational paradigm for basically 40 years. And the fact that I'm
now coming back to trying to apply that in physics, it felt like that journey was necessary.
Was this one, did you first try to play with a hypergraph?
So I was happy.
Yeah, so what I had was, OK, so this is again, you know,
when it always feels dumb after the fact,
it's obvious after the fact.
But so back in the early 1990s, I realized
that using graphs as a sort of underlying thing
underneath space and time was going to be a useful thing
to do.
I figured out about multi-way systems.
I figured out the things about general relativity.
I figured out by the end of the 1990s.
But I always felt there was a certain ineligence
because I was using these graphs.
And there were certain constraints on these graphs
that seemed like they were kind of awkward.
It was kind of like,
you couldn't pick any rule, it was like pick any number, but the number has to be prime.
It was kind of like, it was kind of an awkward special constraint. I had these trivalent graphs,
graphs with just three connections from every node. But I discovered a bunch of stuff with that,
but I thought it was kind of an elegant. And the other piece of personal history
is obviously I spent my life as a computational language
designer.
And so the story of computational language design
is a story of how do you take all these random ideas
in the world and kind of grind them down into something
that is computationally as simple as possible.
And so I've been very interested in kind
of simple computational frameworks
for representing things and have, you know,
ridiculous amounts of experience in trying to do that.
Actually, all of those trajectories of your life kind of came together.
So, you make it sound like you could have come up with everything you're working on
now decades ago, but in reality...
Look, two things slowed me down.
I mean, one thing that slowed me down was,
I couldn't figure out how to make a delegate.
And that turns out hypergraphs were the key to that.
And that I figured out about less than two years ago now.
And the other, I mean, I think,
so that was sort of a key thing.
Well, okay, so the real embarrassment of this project, okay?
Is that the final structure that we have that is the foundation for this project,
is basically a kind of an idealized version, a formalized version of the exact same structure
that I've used to build computational languages for more than 40 years.
Yeah.
But it took me, but I didn't realize that.
Yeah.
And, you know, and there yet may be others. So we're focused on physics now, but I mean,
that's what the new kind of science is about, same kind of stuff. And this in terms of mathematically,
well, the beauty of it. So there could be entire other kind of objects.
They're useful for like we're
not talking about, you know, machine learning, for example, maybe there is other variants
of the hypergraph that are very useful for.
Well, we'll see whether the multi-way graph or machine learning system is interesting.
Okay. Let's leave it at that. That's conversation number three.
That's that's that's that's that's that's that's we're not going to go that right now.
conversation. That's that's that's that's that's that's that's we're not going to go that right now. But
one of the things you've mentioned is um the space of all possible rules that we kind of discussed a little bit uh that you know there could be I guess the set of possible rules is infinite.
Right well so here's here's the big set of one of the conundrums that I'm kind of trying to deal with is let's say we think
we found the rule for the universe and we say here it is, you know, write it down, it's
a little tiny thing. And then we say, gosh, that's really weird. Why did we get that one?
Right? And then we're in this whole situation because let's say it's fairly simple. How
did we come up the winners getting one of the simple possible universe rules?
Why didn't we get some incredibly complicated rule?
Why did we get one of the simpler ones?
That's a thing which in the history of science,
the whole story of Copernicus,
and so on, we used to think the Earth was the center of the universe,
but now we find out it's not,
and we're actually just in some random corner of some random galaxy out in this big universe,
there's nothing special about us.
So, if we get, you know, universe number 317 out of all the infinite number of possibilities,
how do we get something that small and simple?
Right, so I was very confused by this, and it's like, what do we gonna say about this?
How are we going to explain this?
And I thought it was might be one of these things where you just, you know, you can get it to the threshold and then you find out it's rule number such and such and you just have no idea why it's like that.
Yeah.
Okay, so then I realized it's actually more bizarre than that.
Okay.
So we talked about multi-way graphs.
We talked about this idea that you take these underlying transformation rules on these hypergraphs
and you apply them wherever the rule can apply you apply it.
And that makes this whole multi-way graph for possibilities.
Okay, so let's go a little bit weirder.
Let's say that at every place, not only do you apply a particular rule,
in all possible ways it can apply,
but you apply all possible rules in all possible ways it can apply, but you apply all possible rules in all possible ways they can apply.
As you say, that's just crazy, that's way too complicated, you're never going to be able to conclude anything.
Okay, however, turns out that there's some kind of invariance.
Yeah, yeah.
So what happens is...
Oh, and that would be amazing.
Right. So this thing that you get, this kind of
Rulial multi-wake off, this multi-wake off that is
a branching of rules as well as a branching of possible
applications of rules, this thing has gaussl invariance.
It's an inevitable feature that it shows gaussl invariance.
And that means that you can take different
reference frames, different ways of slicing this thing and they will all in some sense be equivalent.
If you make the right translation, they will be equivalent. So, okay, so the basic point here is,
is that's true that would be beautiful. It is true and it is beautiful. So you, it's not just an intuition, there is some...
No, no, no, no, there's real mathematics behind this.
And it's, it is, it is...
Okay, so here's, that's what it comes up.
Yeah, that would be amazing.
That's amazing.
Right, so by the way, I mean, the mathematics that's connected to
is the mathematics of higher category theory and group
points and things like this, which I've always been afraid of.
But now I'm finally wrapping my arms around it.
But it's also related to computational complexity theory.
It's also deeply related to the P versus NP problem and other things like this.
Again, it seems completely bizarre that these things are connected,
but here's why it's connected.
This space of all possible, okay, so a
touring machine, very simple model of computation, you just got this tape where
you write down, you know, ones and zeros or something on the tape and you have
this rule that says, you know, you change the number, you move the head of the
on the tape, etc. You have a definite rule for doing that. A
deterministic touring machine just does that
deterministically, given the configuration of the tape,
it will always do the same thing.
A non-deterministic touring machine
can have different choices that it makes at every step.
And so, you know, this stuff, you probably teach this stuff.
So a non-determinist
Turing machine has the set of branching
possibilities, which is in fact one of these
multi-way graphs. And in fact, if you say
imagine the extremely non-determinist
Turing machine, the Turing machine that can
just do that takes any possible rule at
each step. That is this really all
multi-wayake graph.
The set of possible histories
of that extreme non-deterministic term machine
is a Rulio multi-wake graph.
What term are you using?
Rulio?
Rulio.
It's a weird word.
Yeah, it's a weird word.
Rulio multi-wake graph.
Okay, so this, so that.
I'm trying to think of, I'm trying to think of the space of rules.
So these are basic transformations. So in a touring machine, it's like it says move left, move, you
know, if it's a one, if it's a black square under the head, move left and right to green square.
That's a rule. That's a very basic rule, but I'm trying to see
the rules and the hypergraphs,
how rich of the programs can they be?
Or do they all ultimately just map into something simple?
Yeah, they're all, I mean, hypergraphs,
that's another layer of complexity on this whole thing.
You can think about these and transmissions of hypergraphs,
but turn machines are a little bit...
You just think of it too, in machines, okay.
Right, they're a lot simpler.
So if you look at these extreme non-deterministic turn machines are a little bit too much. Right. They're a lot simpler.
So if you look at these extreme non-deterministic turn machines, you're mapping out all the possible
non-deterministic paths that the turn machine can follow.
And if you ask the question, can you reach?
Okay.
So a deterministic turn machine follows a single path.
The non-deterministic turn machine fills out this whole sort of ball of possibilities.
And so then the P versus MP problem ends up being questions about, and we haven't completely
figured out all the details of this, but it's basically has to do with questions about
the growth of that ball relative to what happens with individual paths and so on.
So essentially there's a geometrization of the P versus M P problem that comes out of this.
That's a side show. Okay. The main event here is the statement that you can look at this
multi-way graph where the branches correspond not just to different applications of a single rule,
but to different applications to applications of different rules.
And that then, that when you say,
I'm going to be an observer embedded in that system,
and I'm going to try and make sense
of what's going on in the system.
And to do that, I essentially am picking a reference frame.
And that turns out to be, well, OK,
so the way this comes out essentially is the reference
frame you pick is the rule that you infer is what's going on in the universe.
Even though all possible rules are being run, although all those possible rules are in a
sense giving the same answer because of course, on variance.
But what you see will be see could be completely different.
If you pick different reference frames,
you essentially have a different description language
for describing the universe.
Okay, so what does this really mean in practice?
So imagine there's us.
We think about the universe in terms of space and time,
and we have various kinds of description models and so on.
Now let's imagine the friendly aliens, for example.
How do they describe their universe?
Well, our description of the universe
probably is affected by the fact that we are about the size
we are, a meter-ish tool, so to speak.
We have brain processing speeds of about the speeds we have.
We're not the size of planets, for example,
where the speed of light really would matter., for example, where the speed of light really
would matter.
In our everyday life, the speed of light doesn't really matter.
Everything can be, you know, the fact that speed of light is finite is irrelevant, it could
as well be infinite.
We wouldn't make any difference, you know, it affects the ping times on the internet.
That's about the level of how we notice the speed of light.
In our sort of everyday existence, we not really notice it.
So we have a way of describing the universe that's based on our sensory senses, these days
also on the mathematics we've constructed and so on.
But the realization is that it's not the only way to do it.
There will be completely utterly incoherent descriptions of the universe,
which correspond to different reference frames in this sort of
Rulial space.
In the Rulial space. That's fascinating.
So we have some kind of reference frame in this Rulial space.
Right. And from that, that's why we are attributing this rule to the universe.
So in other words, when we say, why is it this rule and not another,
the answer is just, you know,
shine the light back on us, so to speak.
It's because of the reference frame
that we've picked in our way of understanding
what's happening in this sort of
space of all possible rules and so on.
But also in this space, from this reference frame,
because of the royal, the invariance
that's simple, that the rule on which universe,
with which you can run the universe, might as well be simple.
Yes, yes, but okay, so here's another point.
So this is again, these are a little bit mind twisting
in some ways, but the, another thing that we know from computation is this idea of computation
universality, the fact that given that we have a program that runs on one kind of computer,
we can, as well, we can convert it to run on any other kind of computer.
We can emulate one kind of computer with another.
So that might lead you to say, well, you think you have the rule for the universe,
but you might as well be running it on a touring machine because we know we can emulate any computational rule on any kind of machine.
And that's essentially the same thing that's being said here. That is that what we're doing is we're saying, these different interpretations
of physics correspond to essentially running physics on different underlying, you know,
thinking about the physics as running and different with different underlying rules,
as if different underlying computers were running them. But because of computation,
universality, or more accurately, because of this principle of computational equivalence thing of mine,
there's, there they are, these things are ultimately equivalent.
So the only thing that is the ultimate fact about the universe, the ultimate fact that doesn't depend on any of these, you know,
we don't have to talk about specific rules, et cetera, et cetera, et cetera. The ultimate fact is the universe is computational, and it is the things that happen in the universe are the kinds
of computations that the principle of computational equivalence says should happen. Now, that
might sound like, you're not really saying anything there, but you are, because you could
in principle have a a hyper computer that
things that take an ordinary computer an infinite time to do, the hyper computer can just say, oh, I know the answer. It's this immediately. What this is saying is, the universe is not a hyper
computer. It's not simpler than an ordinary, touring machine type computer. It's exactly
like an ordinary,uring Machine Type Computer.
And so that's the, that's in the end, the sort of net, net conclusion is, that's the thing
that is the sort of the hard, immovable fact about the universe.
That's sort of the fundamental principle of the universe is that it is computational
and not hyper-computational and not sort of infer a computational.
It is this level of infer computational. It is this
level of computational ability and it kind of has that sort of the core fact. But now,
this idea that you can have these different kind of rural reference frames, these different
description languages for the universe, it makes me, you know, I used to think,
okay, you know, imagine the aliens, imagine the extraterrestrial intelligence thing, you
know, at least they experienced the same physics. Right. And now I've realized, it isn't
true. They, they, they, they, they can have a different royal frame. That's, that's
fascinating. They, they can end up with a, a, a, a description of the universe that is
utterly, utterly, and coherent with ours.
And that's also interesting in terms of how we think about
well intelligence, the nature of intelligence,
and so on, I'm fond of the quote,
the weather has a mind of its own,
because these are sort of computationally,
that system is computationally equivalent
to the system that is our brains and so on.
And what's different is we don't have a
way to understand, you know, what the weather is trying to do, so to speak. We have a story about
what's happening in our brains. We don't have a sort of connection to what's happening there.
So we actually, it's funny. Last time we talked maybe eight over a year ago, we talked about how
it was more based on your work with a rival. We talked
about how do we communicate with alien intelligence? Can you maybe comment on how we might, how the
world from physics project changed your view, how we might be able to communicate with
alien intelligence? Like, if they showed up, is it possible that because of our comprehension of
the physics of the world might be completely different? We would just not be able to communicate.
It is the thing. Intelligence is everywhere. The fact this idea that there's this notion of,
oh, there's going to be this amazing extraterrestrial intelligence and it's going to be this unique thing. It's just not true. It's the same thing. I think
people will realize this about the time when people decide that artificial intelligence
is a kind of just natural things that are like human intelligences. They'll realize that
extraterrestrial intelligences or intelligences associated with physical systems and so on.
It's all the same kind of thing.
It's ultimately computation.
It's all the same.
It's all just computation.
And the issue is, can you, are you sort of inside it?
Are you thinking about it?
Do you have sort of a story you're telling yourself about it?
And you know, the weather could have a story.
It's telling itself about what it's doing. We just, it's utterly incoherent with the stories that we tell ourselves based on how our
brains work.
I mean, ultimately, it must be a question whether we can align.
Exactly.
I'll write.
I'll write.
I'll write.
I'll write.
I'll write.
Exactly.
I'll write.
I'll write. Exactly. I'll write. I'll write. Exactly. So that's the question we have doing. Right, so the question is in the space of all possible intelligences. What's the, how do you think about the distance
between description languages for one intelligence
versus another?
And needless to say, I have thought about this.
And I don't have a great answer yet,
but I think that's a thing where there will be things that
can be said.
And there'll be things that way you can start to characterize what is the translation distance
between this version of the universe
or this set of computational rules and this other one.
In fact, this is this idea of algorithmic information theory.
There's this question of what is the,
when you have something,
what is the sort of shortest description you can make of it, where that description could
be saying, run this program to get the thing, right? So I'm pretty sure that there will
be a physicalization of the idea of algorithmic information.
And that, okay, this is again a little bit bizarre, but so I mentioned that there's the
speed of light, maximum speed of information, transmission, and physical space.
There's a maximum speed of information, transmission, and branchial space, which is a maximum
entanglement speed.
There's a maximum speed of information, transmission, and radial space, which has to do with a maximum speed of information transmission in rural space, which has to do with a maximum speed of
translation between different description languages.
Again, I'm not fully wrapped my brain around this one.
Yeah, that one just blows my mind to think about that.
But that starts getting closer to the, yeah,
the... It's kind of a digitalization.
Right, it's also a physicalization of
of algorithmic information and I think there's probably a connection between I mean, there's
probably a connection between the notion of energy and some of these things, which again,
I, I, you know, hadn't seen all this coming. I've always been a little bit resistant to the idea
of connecting physical energy to things in in in computation theory, but I think that's probably
coming. And that's what essentially at the what the physics project is, that you're connecting
information theory with physics.
Yeah, it's computation and computation, yeah, like our physical universe.
Yeah, right. I mean, the fact that our physical universe is, right, that we can think of it as a
computation, and that we can have discussions like,
you know, the theory of the physical universe
is the same kind of a theory as the P versus MP problem
and so on, is really, you know,
I think that's really interesting.
And the fact that's, well, okay,
so this kind of brings me to one more thing
that I have to in terms of this sort of unification
of different ideas,
which is metamathematics. Let's talk about that. You mentioned that earlier. What the heck is
metamathematics? Okay, so here's what, here's okay. So, what is mathematics? Mathematics,
sort of at a lowest level, one thinks of mathematics as you have certain axioms, you say things
like x plus y is the same as y plus x. That's an axiom about addition. And then you say
we've got these axioms. And from these axioms, we derive all these theorems that fill
up the literature of mathematics. The activity of mathematicians is to derive all these
theorems. Actually, the axioms and mathematics are very small.
You can fit, you know, when I did my new kind of science book,
I fit all of the standard axioms and mathematics
on basically a page and a half.
Not much stuff.
It's like a very simple rule from which all of mathematics arises.
The way it works, so it's a little different
from the way things work
in sort of a computation, because in mathematics what you're interested in is a proof, and the
proof says, from here you can use, from this expression for example, you can use these axioms
to get to this other expression, so that proves these two things are equal. Okay, so we can
begin to see how this is going to work. What's going to happen is there are paths in other expression. So that proves these two things are equal. Okay, so we can, we can begin
to see how this has been going to work. What's going to, what happened is there are paths
in metamathematical space. So what happens is each, two different ways to look at it, you
can just look at it as mathematical expressions or you can look at it as mathematical statements,
postulates or something. But either way, you think of these things and they are connected
by these axioms. So in other words, you have some fact, you or you have some expression,
you apply this axiom, you get some other expression. And in general, given some expression,
there may be many possible different expressions you can get. You basically build up a multi-way graph. And a proof is a path through the multi-way graph that goes from one thing to another thing.
The path tells you how did you get from one thing to the other thing.
It's the story of how you got from this to that.
The theorem is the thing at one end is equal to the thing at the other end.
The proof is the path you go down to get from one thing to the other. You mentioned that Gaitles, Inc. is there as
their natural fits naturally there. How hard is it?
So what happens there is that the girdles theorem is basically saying that there are pods
of infinite length. That is, that there's no upper bound. If you know these two things,
you say I'm trying to get from here to here, How long do I have to go? You say, well, I've looked at all the parts of length 10. Somebody
says, that's not good enough. That path might be of length to billion. And there's no
up a bound on how long that path is. And that's what leads to the incompleteness theorem.
So I mean, the thing that is kind of an emerging idea is you can start asking, what's the
analogue of Einstein's equations in metamethematical space? what's the analogue of Einstein's equations
in metamethematical space? What's the analogue of a black hole in metamethematical space?
What's the hope of this all? Yeah, it's fascinating to model all mathematics in this way.
So here's what it is. This is mathematics in bulk. So human mathematicians have made
a few million theorems. They published a few million theorems. But imagine the infinite
future of mathematics
applies something to mathematics that mathematics
likes to apply to other things, take a limit.
What is the limit of the infinite future of mathematics?
What does it look like?
What is the continuum limit of mathematics?
What is the, as you just fill in more and more
more theorems, what does it look like?
What does it do?
How does, what kinds of conclusions can you make? So, for example, one thing I've just been doing is taking Euclid. So Euclid, very impressive.
He had 10 axioms. He derived 465 theorems. Okay? His book, you know, that was, was the sort of defining book of mathematics for 2,000 years.
So you can actually map out. I actually did this 20 years ago, but I've done it
more seriously now. You can map out the theorem dependency of those 465 theorems. So from the
axioms, you grow this graph, it's actually a multi-way graph, of how all these theorems get
proved from other theorems. And so you can ask questions about, you know, what you can ask,
things like, what's the hardest theorem in Euclid? The answer is the hardest theorem is that there are five platonic solids.
That turns out to be the hardest theorem in Euclid. That's actually his, his lost theorem in
all his books. That's the final one. What's the hardness, the distance you have to travel?
Yeah. That's it's 33 steps from the, the longest path in the graph is 33 steps.
So that's the, there, there's a 33 step path you have to follow to go
from the axioms according to Euclid's proofs to the statement there are five platonic
solids. So, it's okay. So then, then, then the question is, in, what does it mean if
you have this map, okay, so in a sense, this metamathematical space is the infrastructural space of all possible theorems
that you could prove in mathematics.
That's the geometry of metamathematics.
There's also the geography of mathematics
that is where did people choose to live in space?
And that's what, for example, exploring
the sort of empirical metamathematics as a duplex.
You could put each individual like human mathematician, you can embed them into that space.
I mean, they represent a path, the little path, things they do, maybe a set of paths.
Right.
So, in a set of axioms that are chosen.
Right.
So, for example, here's an example of a thing that I realized.
So one of the surprising things about, well, the two surprising facts about math, one is
that it's hard, and the other is that it's doable.
Okay?
So, first question is, why is math hard?
You know, you've got these axioms, they're very small.
Why can't you just solve every problem in math easily?
It's just logic.
Right.
Right.
Well, logic happens to be a particular special case that does have certain simplicity
to it.
But general mathematics, even arithmetic, already
doesn't have the simplicity that logic has. So why is it hard? Because of computational
irreducibility. Right. Because what happens is to know what's true, and this is this
whole story about the path you have to follow, and how long is the path, and go to the theorem
as the statement, there could be an inf, that the path is not a bounded length, but the
fact that the path is not always compressible to something tiny is a story of computational
irreducibility. So that's why math is hard. Now the next question is, why is math doable?
Because it might be the case that most things you care about don't have finite length paths.
Most things you care about might be things where you get lost in the
sea of computational irreducibility and worse undecidability. That is just no finite length path
that gets you there. You know, why is mathematics doable? You know, Gurdle proved his
incompleteness theorem in 1931. Most working mathematicians don't really care about it. They just
go ahead and do mathematics. Even though it could be that the questions they're asking are undecidable. It could have
been that Fermat's last theorem is undecidable. It turned out it had a proof, it's a long
complicated proof. The twin prime conjecture might be undecidable. The Riemann hypothesis
might be undecidable. These things might be, the axioms of mathematics might not be
strong enough to reach those statements. It might be the axioms of mathematics might not be strong enough to reach those statements.
It might be the case that depending on what axioms you choose, you can either say that's true or that's not true.
So, and by the way, from our last theorem, it could be a shorter path.
Absolutely.
Yeah, so the notion of GD6 in mathematical space is the notion of shortest proofs in mathematical space.
And that's a human mathematicians do not find shortest paths, nor do automated
theorem-proofers.
But the fact, and by the way, the, I mean, this stuff is so bizarrely connected.
I mean, if you're into automated theorem-proofing, there are the so-called critical pair lemurs
and automated theorem-proofing, those are precisely the branch pairs in
our, um, that in multi-way graphs. Let me just finish on the why mathematics is doable.
Oh, yes, the second part. So, right, which is-
No way it's hard. Why is it doable? Right. Why do we not just get lost and
undecideability all the time? Yeah. Um, so, and here's another fact is in doing computer
experiments and doing experimental mathematics, you do get lost in that way.
When you just say, I'm picking a random integer equation, how do I, does it have a solution or not?
And you just pick it at random without any human sort of path getting there.
Often, it's really, really hard. It's really hard to answer those questions.
When you just pick them up random from the space of possibilities. But what I think is happening is, and that's a case
where you just fell off into this ocean of sort of irreducibility and so on. What's
happening is human mathematics is a story of building a path. You started off, you're
always building out on this path where you are proving things. You've got this proof trajectory, and you're
basically the human mathematics is the sort of the exploration of the world along this
proof trajectory, so to speak. You're not just, you know, parachuting in from, you know,
from anywhere, you're following, you know, Lewis and Clark or whatever, you're actually
going, you're doing the path. And the fact that you are constrained to go along that path is the
reason you don't end up with lot every so often you'll see a little piece of
undersight ability and you'll avoid that that part of the path but that's basically the story of
why human mathematics has seemed to be doable it's a story of exploring these paths that that are
by their nature they have been constructed to be paths that can be followed,
and so you can follow them further.
Now, why is this relevant to anything?
So, okay, so here's my belief.
The fact that human mathematics works that way
is, I think there's some sort of connections between
the way that observers work in physics
and the way that the axiom systems and mathematics
are set up to make mathematics be doable in that kind of way.
And so, in other words, in particular,
I think there is an analog of causal invariance,
which I think is, and this is again,
it's sort of the upper reaches of mathematics
and stuff that, it this is again, it's sort of the upper reaches of mathematics and stuff that
are, it's a thing, there's this thing called homotopy type theory, which is an abstract,
it's came out of category theory, and it's sort of an abstraction of mathematics. Mathematics
itself is an abstraction, but it's an abstraction of the abstraction of mathematics. And there
is the thing called the univalence axiom, which is a sort of a key
axiom in that set of ideas. And I'm pretty sure the Univalence Axiom is equivalent to causal
invariance. What was the term used again? Univalence. Is that something for somebody like me accessible?
Or is this? There's a statement of it that's fairly accessible. I mean, the statement of it is
Or is this there's a statement of it that's fairly accessible. I mean the statement of it is
Basically it says things which are equivalent can be considered to be identical
in which space
Yeah, it's in higher categories
Okay, in category three. Okay, so it's it's a it's a but I mean the thing just to give a sketch of how that works. So category theory is an attempt to idealize, it's an attempt to sort of have a formal
theory of mathematics that is at a sort of higher level than mathematics.
It's where, well, you just think about these mathematical objects and these categories
of objects and these morphisms, these connections between categories.
Okay.
So it turns out the morphisms and categories,
at least weak categories are very much like
the paths in our hypergraphs and things.
And it turns out, again, this is where it all gets crazy.
I mean, it's the fact that these things are connected,
it's just bizarre.
So category theory, our causal graphs
are like second order category theory, our causal graphs are like second order category theory, and it turns out you can take the limit of infinite order category theory.
So just give roughly the idea. This is a roughly explainable idea. So a mathematical proof will be a path that says you can get from this thing to this other thing. And here's the path that you get from this thing to this other thing. But in general, there may be many paths, many proofs that get you,
many different paths that all successfully go from this thing to this other thing. Now you can
define a higher order proof, which is a proof of the equivalence of those proofs. So you're saying
there's a path between those proofs. Essentially, yes you're saying there's a path between those proofs essentially. Yes, a path between the
paths. Yeah. Okay. And so you do that. That's the sort of second order thing. That path between the
paths is essentially related to our causal graphs. They take a limit. Okay. Path between path between
path between path. The infinite limit. That infinite limit turns out to be our Rulio Multisystem.
Yeah, the Rulio Multisystem, that's a fascinating, both in the physics world and as you're saying,
that's that's so okay. Not sure I've loaded it all in completely, but
well I'm not sure I have either and it may be one of these things where where you know in another
another five years or something it's like,ervious, but I didn't see it. Now, the thing which is sort of interesting to me
is that there's sort of an upper reach of mathematics,
of the abstraction of mathematics.
This thing, there's this mathematician
called Growth Indique, who's generally viewed as being
sort of one of the most abstract, sort of creator
of the most abstract mathematics of 1970s-ish time frame.
And one of the things that he constructed with this thing, he called the Infinity
Group Boyd, and he has this sort of hypothesis about the inevitable appearance of geometry
from essentially logic in the structure of this thing.
Well it turns out this William Multiwivirus system is the Infinity Groupoid. So it's this limiting object, and this is an instance
of that limiting object.
So what to me is, I mean, again, I've
been always afraid of this kind of mathematics
because it seemed incomprehensibly abstract to me.
But what I'm sort of excited about with this
is that we've sort of concretified the way
that you can reach this kind of mathematics, which makes it, well, both seem more relevant
and also the fact that I don't yet know exactly what mileage we're going to get from using
the apparatus that's been built in those areas of mathematics to analyze what we're
doing.
But the thing that's... So ways, you know, right,
mathematics and what you're doing and using right,
so you're doing computationally to understand them.
Right. So, for example, the understanding of metamathematical space,
one of the reasons I really want to do that is because I want to understand quantum
mechanics better. And, and that what you see, you know, we live that kind of the multi-way graph of mathematics,
because we actually know this is a theorem we've heard of, this is another one we've heard of.
We can actually say these are actual things in the world that we relate to,
which we can't really do as readily for the physics case.
And so it's kind of a way to help my intuition. It's also, you know, there are bizarre
things like the, what's the analog of Einstein's equations in mathematical space? What's the
analog of a black hole? You know, it turns out it looks like not completely sure yet, but
there's this notion of non-constructive proofs in mathematics. And I think those relate
to, well, actually, they relate to things
and relate it to event horizons.
So the fact that you can take ideas from physics,
like event horizons.
And map them into the same kind of space.
And put them in.
It's really, do you think you might stumble upon
some breakthrough ideas in theorem proving,
like for the other direction.
Yeah, yeah, yeah.
No, I mean, what's really nice is that we are using,
so this absolutely directly maps to theorem proving.
So paths and multi-agraphs,
that's what a theorem prove is trying to do.
But it also means like automated theorem proving.
Yeah, yeah, yeah, that's what, right.
So the finding of paths,
the finding of shortest paths,
or finding of paths at all,
is what automated theorem Proofers do.
And actually, what we've been doing,
so we've actually been using automated theorem proving both
in the physics project to prove things,
and using that as a way to understand multiway graphs.
And because what an automated theorem Proofer is doing
is it's trying to find a path through a multi-way graph.
And its critical pair lemurs are precisely little stubs of branch pairs going off into
branchial space.
And that's, I mean, it's really weird.
You know, we have these visualizations in the language of our proof graphs from our
Automated Therimproving System.
And they look reminiscent of that.
Well, it's just bizarre because we made these up a few years ago, and they have these
little triangle things, and they are.
We didn't quite get it right.
We didn't quite get the analogy perfectly right, but it's very close.
You know, just to say in terms of how these things are connected, so there's another bizarre
connection that I have to mention, because which is, which again, we don't fully know, but it's a connection to something else you might not have thought was in the slightest bit connected, which is distributed blockchain-like things.
Now, you might figure out that that's connected because it's a story of distributed computing.
And the issue, you know, with a blockchain, you're saying there's going to be this one ledger that globally says,
this is what happened in the world.
But that's a bad deal if you've got all these different transactions that are happening.
And, you know, this transaction in country A doesn't have to be reconciled with the transaction in country B, at least not for a while.
And that story is just like what happens when I cause all graphs.
That whole reconciliation thing is just like what happens with light cones and all of
that.
That's where the cause of awareness comes into play.
That's, you know, most of your conversations are about physics, but it's kind of funny
that this probably and possibly might have even bigger impact and revolutionary
ideas and totally other disciplines.
Right.
Yeah.
Right.
So the question is, why is that happening?
Right.
And the reason it's happening, I thought about this whole way is because I like to think
about these meta questions of, you know, what's happening is this model that we have is
an incredibly minimal model.
Yeah.
And once you have an incredibly minimal model, and this happened with cellular automata
as well, cellular automata is an incredibly minimal model.
And so it's inevitable that it gets you, it's sort of an upstream thing that gets used
in lots of different places.
And it's like, you know, the fact that it gets used, you know, cellular automata is sort
of a minimal model of, like, say, road traffic flow or something. And there also a minimal model of something in, you know, the fact that it gets used, you know, cellular automator is sort of a minimal model of, like,
say, road traffic flow or something.
And they're also a minimal model of something in, you know, chemistry.
And they're also a minimal model of something in epidemiology, right?
It's because they're such a simple model that they can,
that they apply to all these different things.
Similarly, this model that we have at the physics project is,
is another, it's a cellular automator,
a minimal model of parallel,
of basically a parallel computation where you've defined space and time.
These models are minimal models where you have not defined space and time.
And they have been very hard to understand in the past.
But the, I think the perhaps the most important breakthrough there is the realization that these are models of physics
and therefore that you can use realization that these are models of physics
and therefore that you can use everything that's been developed in physics to get intuition
about how things like that work.
And that's why you can potentially use ideas from physics to get intuition about how to
do parallel computing and because the underlying model is the same.
But we have all of this achievement in physics.
I mean, you might say, oh,
you've come up with the fundamental theory of physics, that throws out what people
have done in physics before. Well, it doesn't. But also, the real power is to use what's
been done before in physics to apply it in these other places.
Yes.
Absolutely.
This kind of brings up, I know you probably don't particularly love commenting on the work of others, but let
me bring up a couple of personalities just because it's fun and people are curious about
it.
So there's Sabine Hassenfelder, I don't know if you're familiar with her.
She wrote this book, then I need to read it, but I forget what the title is, but it's beauty leads us
to strain physics is a subtitle, something like that, which so much about what we're
talking about now, like this simplification is a to us humans seems to be beautiful. Like
there's a certain intuition with physicists with people that a simple theory like this reduce ability pockets of reduce abilities the ultimate goal and I think
when she tries to argue is
No, we just need to come up with
Theories that are just really good at predicting physical phenomena. It's okay to have a bunch of
disparate theories as opposed to trying to chase this beautiful
Theory of everything is the ultimate beautiful theory a simple one.
You know, so what's your response to that?
Well, so what you're quoting is I don't know the Sabine Hassanfeldh's, you know,
exactly what she said, but I mean, maybe just quoting the exact...
Well, quoting the title of a book.
Okay, let me, let me, let me respond to what you were describing.
Yeah. Mail may not have anything to do with what. Yeah.
You know, what's the bean hustle felt the says? Yeah. Or thanks.
Sorry, Sydney. Right. Sorry for this quoting.
Um, but I mean, the question is, you know, does is beauty a guide to whether something is correct?
Which is kind of also the story of Occam's razor.
If you've got a bunch of different explanations of things,
is the thing that is the simplest explanation
likely to be the correct explanation?
And there are situations where that's true
and there are situations where it isn't true.
Sometimes in human systems, it is true
because people have kind of, you know, in evolutionary systems,
sometimes it's true because it's sort of been kicked
to the point where it's minimized.
But in physics, does Occam's razor work?
Is there a simple quote's beautiful explanation
for things, or is it a big mess?
We don't intrinsically know.
I think that the, I wouldn't, before I worked on the project
in recent times, I would have said,
we do not know how complicated the rule for the universe
will be.
And I would have said, you know, the one thing we know,
which is a fundamental fact about science,
that's the thing that makes science possible,
is that there is order in the universe.
I mean, you know, early theologians would have used that
as an argument for the existence of God,
because it's like, why is that order in the universe? Why doesn't every single particle in the
universe just do its own thing? You know, something must be making that be order in the universe.
We, you know, in the sort of early theology point of view, that's, you know, the role of God is to do
that, so to speak. In our, you know, we might say, it's the role of a formal theory to do that.
And then the question is, but how simple should that theory be?
And should that theory be one that, where I think the point is, if it's simple,
it's almost inevitably somewhat beautiful in the sense that,
because all the stuff that we see has to fit into this little
tiny theory and the way it does that has to be, you know, it depends on your notion of
beauty.
But I mean, and for me, the sort of the surprising connectivity of it is at least in
my aesthetic, that's something that, you know, responds to my aesthetic. But the question is, I mean, you're, you're a fascinating
person in the sense that you're at once talking about
computational, the fundamental computation or
reproducibility of the universe. And, and the other
hand, trying to come up with a theory of everything, which
simply describes the, the, the simple origins of that competition
or reducibility.
I mean, both of those things are kind of,
it's paralyzing to think that we can't make any sense
of the universe in the general case.
But it's hopeful to think like one,
we can think of a rule that generates this whole complexity.
And two, we can find pockets of reducibility that are powerful for everyday life to do different
kinds of predictions.
I suppose to be once to focus on the finding of small pockets of reducibility versus the
theory of everything. You know, it's a funny thing because, because, you know, a bunch of people have started working on this, this, you know, physics project, people who are, you know, physicists, basically.
And it is really a fascinating sociological phenomenon, because what, you know, when I was working on this before in the 1990s, you know, wrote it up, put it,
it's a hundred pages over this,
1200 page book that I wrote,
new kind of science,
it's you know, a hundred pages of that is about physics.
Right, I saw it at that time,
not as a pinnacle achievement,
but rather as a use case, so to speak.
I mean, my main point was this new kind of science,
and it's like, you can apply it to biology,
you can apply it to, you know, other kinds of physics, you can apply it to fundamental physics.
It's just an application, so to speak.
It's not the core thing.
But then one of the things was interesting with that book, was, book comes out, lots of
people think it's pretty interesting, and lots of people start using what it has in different
kinds of fields.
The one field where there was sort of a heavy pitchforking was from my friends, the fundamental physics people.
Yeah. Which was it's like, no, this can't possibly be right. And you know, it's like, you know, if what you're doing is right,
it'll overturn 50 years of what we've been doing. And it's like, no, it won't. It was what I was saying. And it's like, but for a while, when I started,
I was going to go on back in 2002, well, 2004, actually,
I was going to go on working on this project.
And I actually stopped partly because it's like, why am I,
this is like, I've been in business the long time, right?
I'm building a product for a target market that doesn't want the product
And it's like why work. Yeah. Yeah. Yeah. Why the why work against the swim against the current?
Right, but you see what's happened, which is sort of interesting is that so a couple of things happened and it was it was like
You know, it was like I I don't want to do this project because I can do so many other things, which I'm really interested in,
where people say, great, thanks for those tools, thanks for those ideas, etc.
Whereas if you're dealing with a structure where people are saying,
no, no, we don't want this new stuff, we don't need any new stuff.
We're really fine with what we're doing.
Yeah, there's literally millions of people who are thankful for no, no, we don't want this new stuff. We don't need any new stuff. We're really fine with what we're doing. Yeah, there's like literally like, I don't know, millions of people who
are thankful for Wolfram Alpha. A bunch of people wrote to me how thankful they are, they are
different crowd than the theoretical physics community, perhaps. Yeah, well, but you know,
the theoretical physics community pretty much uniformly uses a wolfram language in mathematical,
right? And so it's kind of like like, you know, and that that's but the thing is it is what happens
You know, this is what happens mature fields do not you know, it's like we're doing what we're doing
We have the methods that we have and where we're just fine here now what's happened in the last 18 years or so
I think there's a couple of things have happened. First of all, the hope that
string theory or whatever would deliver the fundamental theory of physics, that hope is
disappeared, that another thing that's happened is the sort of the interest in computation
around physics has been greatly enhanced by the whole quantum information, quantum computing
story. People, the idea there might be something sort of computational related to physics
is somehow growing.
And I think, it's sort of interesting.
I mean, right now, if we say, who else is trying to come up with the fundamental theory of physics?
It's like, they're on professional physicists.
No professional physicists.
No professional physicists.
What are your, I mean, you've talked with him,
but just as a matter of personalities,
because it's a beautiful story.
What are your thoughts about airquise, that has worked?
You know, I think his, I mean,
he did a PhD thesis in mathematical physics at Harvard.
Mathematical physics.
And, you know, it's, it seems like it's like it's kind of, it's in that framework.
And it's kind of like, I not sure how much further it's
got than this PhD thesis, which was 20 years ago or something.
And I think that the, it's a fairly specific piece
of mathematical physics that's quite nice.
And what your jacket you do hope it takes.
I mean, well, I think in this particular case, I mean, from what I understand, which is not
everything at all, but I think I know the rough tradition, at least, that is operating in,
is sort of theory of gauge theories, gauge theories, local gauge invariants and so on.
Okay, we are very close to understanding how local gauge invariance works in our models and it's very beautiful
and it's very um and you know does some of the mathematical structure that he's enthusiastic about
fit quite possibly yes. So there might be a possibility of trying to understand how those things fit
how gauge theory fits. Yeah, right. But the question is you know so there are a couple of things one
might try to get in the world. So for example, it's like, can we get three dimensions of space? We haven't managed to get that yet.
Gage theory, the standard model of particle physics says, but it's SU3 cross SU2 cross
U1.
Those are the designations of these Lee groups.
But anyway, so those are sort of representations of symmetries of the theory. And so, you know, it is conceivable that it is generically true.
Okay, so all those are subgroups of a group called e8,
which is a weird exceptional e-group.
Okay, it is conceivable.
I don't know whether that's the case
that that will be generic in these models,
that it will be generic,
that the gauge invariance
of the model has this property, just as things like general
utility, which corresponds to,
think of general covariance,
which is another gauge-like invariance.
It could conceivably be the case
that the kind of local gauge invariance that we see in particle physics is somehow generic. And that would be
a, you know, the thing that's that's really cool, I think, you know, sociologically,
although this hasn't really hit yet, is that all of these different things, all
these different things people have been working on in these, in some cases, quite
abstruse areas of mathematical physics, and awful lot of them seem to tie into what we're doing.
And you know, it might be that way.
Yeah, absolutely.
That's a beautiful thing in the theory.
I mean, but the reason I,
so the reason I acquires time is important,
is to the point that you mentioned before,
which is, is strange that the theory of everything
is not at the core of the passion, the dream, the focus, the funding
of the physics community. It's too hard. It's too hard and people gave up. I mean, basically what
happened is ancient Greece, people thought we're nearly there. You know, the world has made a
platonic solids. It's, you know, water is a tetrahedron or something. Yes, we're almost there. Okay long period of time where people were like no
We don't know how it works, you know time of Newton
You know, we're almost there everything is gravitation
You know time of Faraday and Maxwell. We're almost there everything is fields everything is the ether
You know then a whole time making big progress though. Everything is fields, everything is the ether. You know, then a whole time we're making big progress though.
Oh yeah, absolutely. But the fundamental theory of physics is almost a footnote.
Because it's like, it's the machine code. It's like we're operating in the high level languages.
Yeah. You know, that's what we really care about. That's what's relevant for our everyday physics.
We talked about different centuries and the 21st century will be everything's computation.
Yes. If that takes us all the way, we don't know,
but it might take us pretty far.
Yes. Right. That's right.
But I think the point is that it's like, you know, if you're doing biology,
you might say, how can you not be really interested in the origin of life
and the definition of life? Well, it's irrelevant.
You know, you're studying the properties of some virus.
It doesn't matter, you know, It doesn't matter where you're operating at some much higher level. And what's happened
with physics is, I was sort of surprised actually, I was sort of mapping out this history
of people's efforts to understand the fundamental theory of physics. And it's remarkable how
little has been done on this question. And it's, you know, because, you know,
there've been times when there's been bursts of enthusiasm.
Oh, we're almost there.
And then it decays.
And people just say, oh, it's too hard,
but it's not relevant anyway.
And I think that the thing that, you know, so,
so the question of, you know, one question is,
why does anybody, why should anybody care?
Right?
Why should anybody care what the fundamental theory of physics is?
I think it's intellectually interesting, but what will be the sort of, what will be
the impact of this?
What, I mean, this is the key question.
What do you think will happen if we figure out the fundamental theory of physics?
Right.
Outside of the intellectual curiosity of us.
This is what it is my best guess. Okay. So if you look at the history of science, I think a very
interesting analogy is Copernicus. Okay. So what did Copernicus do? Bed, bin, this
telemaic system for working out the motion of planets. It did pretty well. It used epicycles,
et cetera, et cetera, et cetera. It had all this computational ways of working out
what planets will be.
When we work out where planets are today,
we're basically using epicycles.
But Copernicus had this different way of formulating things
in which he said, you know,
and the Earth is going around the Sun,
and that had a consequence.
The consequence was, you can use this mathematical theory to
conclude something which is absolutely not what we can tell from common sense.
Right? So it's like, trust the mathematics, trust the science. Okay?
Now fast forward, 400 years, and you know, and now we're in this pandemic, and it's kind
of like, everybody thinks the science will figure out everything.
It's like, from the science, we can just figure out
what to do, we can figure out everything.
That was before Copernicus, nobody would have thought,
if the science says something that doesn't agree
with our everyday experience, where we just have to,
you know, compute the science and then figure out
what to do, people say that's completely crazy.
And so your sense is, once we figure out the framework of computation that can basically
do any understand the fabric or reality, we'll be able to derive totally counterintuitive
things.
No, the point I think is the following. That right now, I talk about computational irreducibility.
People, I was very proud that I managed to get the term computational irreducibility. People, I was very proud that I managed to get
the term computational irreducibility
into the congressional record last year.
That's right, by the way, that's a whole other topic.
We could talk about fascinating.
Different, different, different, different, different topic.
But in any case, but so computational irreducibility
is one of these sort of concepts that I think
is important in understanding lots of things in the world.
But the question is, it's only important if you believe the world is fundamentally computational.
But if you know the fundamental theory of physics and it's fundamentally computational,
then you've rooted the whole thing. That is, you know the world is computational. And while you can
discuss whether it's not the case that people
say, well, you have this whole computational ability to see all these features of computation,
we don't care about those because after all the world isn't computational, you might
say. But if you know, you know, base, base, base thing physics is computational, then
you know that that stuff is, you know, that that's kind of the grounding for that stuff just as in a sense
Copernicus was the grounding for the idea that you could figure out something with math and science
that was not what you would intuitively think from your senses. So now we've got to this point where for example
we say, you know, once we have the idea that computation is the foundational thing that
explains our whole universe, then we have to say, well, what does it mean for other things?
Like, it means there's computational irreducibility, that means science is limited in certain ways,
that means this, that means that.
But the fact that we have that grounding means that, and I think, for example, for Copernicus,
for instance, the implications
of his work on the sort of mathematics of astronomy were cool, but they involved a very small
number of people. The implications of his work for sort of the philosophy of how you think
about things were vast and involved, you know, everybody, more or less.
But do you think so? That's actually the way scientists and people see the world around us?
So it has a huge impact in that sense. Do you think it might have an impact?
more directly to
engineering derivations from physics like propulsion systems, our ability to colonize the world like for example
Okay, this is like sci-fi, but if you if you understand
the computational nature say of Okay, this is like sci-fi, but if you understand
the computational nature of the different forces of physics,
there's a notion of being able to warp gravity, things like this like a warp drive.
Warp drive, yeah.
So would we be able to,
will Elon Musk start paying attention?
Like, it's awfully costly to launch his rockets.
Do you think we'll be able to, yeah, create warp drive?
And, you know, I set myself some homework.
I agreed to give a talk, cut some NASA workshop
in a few weeks about, it's faster than light travel.
So I haven't figured it out yet, but,
but, no, but.
You got two weeks.
Yeah, I'm right.
But do you think that kind of understanding
of fundamental theory of physics can lead to those engineering breakthroughs? Okay, I think it's far away, but I got two weeks. Yeah, right. But do you think that kind of understanding of fundamental theory of physics can lead
to those engineering breakthroughs?
OK, I think it's far away, but I'm not certain.
I mean, you know, this is the thing that I set myself
on exercise when gravitational waves were discovered,
right?
I set myself the exercise of what would black hole technology
look like?
In other words, right now, black holes are far away.
That, you know, how on earth can we do things with them, but just imagine that we could get pet black holes right in our
backyard. What kind of technology could we build with them? I got a certain distance,
not that far, but I think in, so there are ideas. I have this one of the weirder ideas
of things I'm calling space tunnels, which are higher dimensional pieces of space time, where basically
you can, you know, in our three dimensional space, there might be a five dimensional, you
know, a region, which actually will appear as a white hole and a black hole at the other
end, you know, who knows whether they exist.
And then the question's another one, okay, this is another crazy one, is the thing that
I'm calling a vacuum cleaner, okay, this is another crazy one, is the thing that I'm calling a vacuum cleaner. Okay.
So, so I mentioned that, you know, there's all this activity in the universe, which is
maintaining the structure of space.
Yes.
And that leads to a certain energy density effectively in space.
And so the question, in fact, dark energy is a story of essentially negative mass produced by the absence of energy you thought
would be there, so to speak.
And we don't know exactly how it works
in our model or the physical universe,
but this notion of a vacuum cleaner is a thing where,
you have all these things that are maintaining
the structure of space.
But what if you could clean out some of that stuff that's maintaining the structure of space? But what if you could clean out some of that stuff
that's maintaining the structure of space
and make a simpler vacuum somewhere?
Yeah.
You know, what would that do?
I told you a different kind of vacuum.
Right.
That would lead to negative energy density,
which would need to, so gravity is usually a purely
attractive force, but negative mass would lead
to repulsive gravity and lead to all kinds of weird things. Now, can it be done in our
universe? My immediate thought is no, but the fact is that at this level of abstraction can we reach
to the lower levels and mess with it. Once you understand the levels, I think you can start to get.
And I have to say that this reminds me of people telling one
years ago that you'll never transmit data
over a copper wire at more than 1,000 board or something.
And this is, why did that not happen?
Why do we have these much, much faster data transmission?
Because we've understood many more of the details
of what's actually going on.
And it's the same exact story here.
And it's the same, I think that this, as I say,
I think one of the features of one of the things
about our time that will seem incredibly naive in the future
is the belief that things like heat
is just random motion of molecules.
That is just, just throw up your hands, it's just random.
We can't say anything about it. That will seem naive.
Yeah, the heat death of the universe, those particles would be laughing at us humans thinking.
Yes, right. That life is not beautiful.
Life is not beautiful.
Civilization. Humans used to think beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful.
That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is beautiful. That life is beautiful. That life is not beautiful. That life is not beautiful. That life is not beautiful. That life is beautiful. That you know, my immediate thing is, boy, that seems really
hard.
But then, you know, possibly computational irreducibility will bite you, but then there's
always some path of computational irreducibility.
And that path of computational irreducibility is the engineering invention that has to be made.
That was a little pocket.
It can have huge engineering impact.
Right.
And I think that that's right.
And I mean, we make use of so many of those pockets.
And the fact is, you know, this is, yes, it's one of these things where I'm a person who
likes to figure out ideas and so on, and there's sort of tests of my level of imagination,
so to speak.
And so a couple of places where there's
sort of serious humility in terms of my level of imagination.
One is this thing about different reference frames
for understanding the universe, where like,
imagine the physics of the aliens, what will it be like?
And I'm like, that's really hard.
I don't know, you know, and I mean, I
once you have the framework in place, you can at least reason about the things you don't know.
Yes. Maybe can't know or like it's too hard for for you to know. But then the mathematics can
that's the exact it. Allow you to reach beyond where you can reason. Right. So I'm, you know,
I'm trying to not have, you know, if you think back to Alan Turing, for example, and when
he invented Turing machines, and imagining what computers would end up doing, so to speak.
Yeah.
And it's very difficult.
Very difficult, right?
And it's a few reasonable predictions, but most of it he couldn't predict possibly.
By the time by 1950, he was making reasonable predictions about something,
but not that there he's in.
Right. Not not not in the not when he first, you know, conceptualized, you know,
and he conceptualized universal computing for a very specific mathematical reason
that wasn't, um, wasn't his general, but, but yes, it's a, it's a good sort of
exercising humility to realize that, that it's kind of like, it's really hard to figure these things out.
The engineering of the universe, if we know how the universe works,
how can we engineer it?
That's such a beautiful vision.
That's the beautiful vision.
By the way, I have to mention one more thing, which is the ultimate question of,
of from physics is, okay, so we have this abstract model of the universe.
Why does the universe exist at all?
Right?
So, you know, we might say there is a formal model
that if you run this model, you get the universe.
But the model gives you, you know, a model of the universe,
right?
You run this mathematical thing and the mathematics unfolds in the way that corresponds to the universe.
But the question is, why was that actualized?
Why does the actual universe actually exist?
And so this is another one of these humility and is like, can you figure this out?
I have a guess about the answer to that.
And my guess is somewhat unsatisfying,
but my guess is that it's a little bit similar
to girdle second and completeness theorem,
which is the statement that from within
an axiomatic theory like Piano arithmetic,
you cannot from within that theory
prove the consistency of the theory.
So my guess is that for entities within the universe
there is no finite determination that can be made So my guess is that for entities within the universe,
there is no finite determination that can be made of the statement the universe exists
is essentially undecidable to any entity
that is embedded in the universe.
Within that universe, how does that make you feel?
Is that, is that, does that put you at peace
that it's impossible?
Or is it really ultimately frustrating?
Well, I think it just says that it's not a kind of question that, you know, it's, there
are things that it is reasonable.
I mean, there's kinds of, you know, you can talk about hypercomputation as well.
You can say, imagine there was a hypercomputer, here's what it would do.
So great, it would be lovely to have a hypercomputer,
but unfortunately we can't make it in the universe.
Like it would be lovely to answer this,
but unfortunately we can't do it in the universe.
And this is all we have, so to speak.
And I think it's really just a statement.
It's sort of, in the end, it'll be a kind of a logical,
logically inevitable statement, I think.
I think it will be something where it is,
as you understand what it means to have,
what it means to have a sort of predicate of existence
and what it means to have these kinds of things,
it will sort of be inevitable that this has to be the case,
that from within that universe,
you can't establish the reason for its existence,
so to speak, you can't prove that it exists and so on.
And nevertheless, because of computational reusability, the future is ultimately not predictable
full mystery, and that's what makes life worth living. Right. I mean, right. And you know,
it's funny for me, because as a pure sort of human being doing what I do, it's, you know, I'm,
I'm, you know, I like, I'm interested in people. I like sort of,. I like the whole human experience, so to speak. And yet,
it's a little bit weird when I'm thinking, it's all hypergraphs down there. And it's all
just hypergraphs all the way down.
It's like turtles all the way down.
And it's kind of, to me, it is a funny thing because every so often I get this, as I'm thinking about,
I think we've really gotten, we've really figured out kind of the essence of how physics works,
and I'm thinking to myself, here's this physical thing, and I'm like, this feels like a very definite
thing. How can it be the case that this is just some really reference frame of, you know, this infinite creature that is so abstract and so on. And I kind of,
it is a, it's a, it's a funny sort of feeling that, you know, we are, we're sort of, it's
like, it's, in the end, it's just sort of, we're just happy with just humans to think.
And it's kind of like, but we're making, we make things as,
it's not like we're just a tiny speck.
We are in a sense, we are more important
by virtue of the fact that in a sense,
it's not like there is no ultimate,
it's like we're important because,
because we're here, so to speak, and we're not, it's not
like there's a thing where we're saying, we are just but one sort of intelligence out
of all these other intelligences.
And so ultimately, there'll be the super intelligence, which is all of these put together and
it'll be very different from us.
No, it's actually going to be equivalent to us.
And the thing that makes us a sort of special
is just the details of us, so to speak.
It's not something where we can say, oh, there's this other thing.
Just you think humans are cool.
Just wait until you've seen this.
It's going to be much more impressive.
Well, no, it's all going to be kind of computationally equivalent. And the thing that, you know, it's not going to be, oh, this
thing is amazingly much more impressive and amazingly much more meaningful, let's say,
no, we're it. I mean, that's, that's, that's the, and the symbolism of this particular
moment. So this has been one of the, one of the favorite conversations
I've ever had Stephen, it's a huge honor to talk to you to talk about a topic like this
for four plus hours on the fundamental theory of physics. And yet we're just two finite
descendants of apes that have to end this conversation because darkness have come upon us.
Right. And we're going to get bitten by mosquitoes and the symbolism of that.
We're talking about the most basic fabric of reality and having to end
because of the fact that things end. It's tragic and beautiful Stephen. Thank you so
much, Hugh Johnner. I can't wait to see what you do in the next couple of
days and next week, a month. We're all watching with excitement. Thank you so much, huge honor. I can't wait to see what you do in the next couple of days and next week, month, or all watching with excitement. Thank you so much. Thanks.
Thanks for listening to this conversation with Stephen Wilfrum and thank you to our sponsors, simply safe, sunbasket and masterclass.
Please check out our sponsors in the description to get a discount and to support this podcast.
the description to get a discount and to support this podcast. If you enjoyed this thing, subscribe on YouTube, review it with 5 stars and not put podcasts, follow on Spotify, support
on Patreon, or connect with me on Twitter, Alex Friedman. And now, let me leave you with
some words from Richard Feynman. Physics isn't the most important thing. Love is. Thank
you for listening and hope to see you next time.
you