The Rest Is Science - Searching For Meaning In Randomness
Episode Date: January 20, 2026What do we mean when we call an event random? Most people view randomness as a fundamental property of the universe, but is it just a label for our own lack of knowledge? Whether it is a weighted ...coin toss, a scratch card, or the digits of Pi, unpredictability usually emerges from rules and patterns that sit just beyond our perception. Professor Hannah Fry and Michael Stevens dismantle the logic of chance, exploring how chaos is governed by strict mathematical laws and why a coin can be '50 / 50' until the moment you apply the laws of physics to its flight. How does probability measure what we cannot see rather than what will happen. Why do patterns inevitably emerge when we zoom out, how minute uncertainties allowed for the formation of galaxies, and why is the human mind is so determined to find meaning in a world built on statistical mechanics. ------------------- For more information about Cancer Research UK, their research, breakthroughs and how you can support them, visit https://cancerresearchuk.org/restisscience Cancer Research UK is a registered charity in England and Wales (1089464), Scotland (SC041666), the Isle of Man (1103) and Jersey (247). A company limited by guarantee. Registered company in England and Wales (4325234) and the Isle of Man (5713F). Registered address: 2 Redman Place, London, E20 1JQ. ------------------- Find The Rest Is Science all over the internet by clicking here. ------------------- Video Producer: Adam Thornton Video & Social: Bex Tyrrell Assistant Producer: Imee Marriott Producer: Becki Hills Senior Producer: Lauren Armstrong-Carter Head Of Digital: Samuel Oakley Exec Producer: Neil Fearn Learn more about your ad choices. Visit podcastchoices.com/adchoices
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This episode is brought to you by Cancer Research, UK.
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forward slash rest is science. Hello and welcome to The Rest of Science with me, Hannah Fry.
And me, Michael, I've brought a present for you. I see them on the table. The potential to be
be a very good present indeed. I've got some scratch cards. Do you have preference? Oh, there's different
kinds? You didn't just get two of the same? No. So this one is just a straight up top prize of
5,000. Boring. This one, I think, is a more interesting choice. Would you rather have
20,000 pounds a month for five years or 300,000 pounds? I'd rather have the 20,000. I think
it's more likely to win a smaller prize. Oh, okay. So here is one, smaller top price,
$5,000 top prize on this one. Right. So is this the one you won? No, because that one only cost
one pound. So you got to, you got to also spend more, you're more likely to win. So
give me that 20,000 a month for five years.
Because it's five pounds.
I agree this is the best one, by the way.
I agree with the best one.
Can I scratch this now or should we do it later?
Because let's wait, let's wait, right?
Because I want to know what are the chances of both of us.
I've got three games on mine.
Yeah, I don't think it works like that.
All right.
We'll have to find out.
We'll have to find out.
Funny enough, randomness might lead us there.
Look, hey, that's what I call a hook and tease, you know?
Yeah.
If we're talking about randomness, we should probably define it, right?
Yeah.
I'll throw one out there.
I like to just say randomness is a property something has that makes it unpredictable and lacking in identifiable, recognizable, recognizable patterns.
Yeah.
Where you don't know the outcomes in advance.
When you don't know the outcomes in advance, you cannot predict them.
And you can't even find them when you look at past data.
You say, this seems quite random.
Although I also think that to add to that,
I don't think that that means that something being random is necessarily interesting.
I mean, statisticians love the idea of a weighted coin, right?
But like, let's say that somehow I managed to trick this coin so that it landed heads 99% of the time
and then do 100 throws.
The results would technically be random.
Right.
But it would be like, heads, heads, heads, heads, heads, heads, heads, heads, heads, heads, heads,
they'd probably be one, maybe a couple of tails in there somewhere.
Yeah.
But where they appear we wouldn't be able to predict.
Agree.
really great difference to point out that randomness doesn't mean equal probability. Absolutely.
You do have the other end of the spectrum, right? Like if you have a completely fair coin,
then you can't tell where any heads or tails will be. Like it'll be kind of all over the place.
And I think that when people talk about purely random, that's sort of what they mean. But really
they're talking about where every possibility is equally likely to come up. That's right. That's
really what they mean because they will say, oh, well, that doesn't look very random. And it's like,
well, that'll happen sometimes. Yeah.
randomly.
Yeah.
Because a weighted coin that heads 99.9% of the time, it's still random, which one it lands on.
But what do they call it when there's an equal chance of all the options?
Like pi, for example.
So the digits after the decimal place in pi, well, we think that there's an equal chance of every digit to come up.
And if it does, it's called a normal number.
Normal.
Just as likely to get a two as a four, as a, you know, as a six, as an eight, whatever.
And every combination, every two combinations.
So 22 is like is an 83 or whatever.
And as far as we've checked, which, by the way, is very, very, very, very far after the decimal point in pie.
I would say, frankly, too far.
I know people worship pie.
Too far.
We haven't even started.
It's so long.
There will never be far into pie.
No.
But we've checked.
And what have we found?
We've found so far that it looks like it's normal.
It's normal.
I mean, at the moment, we have just.
check so far into pie, but basically, if you wanted to measure the radius of the entire universe,
you could do it to the level of accuracy that was way beyond the width of an atom.
Oh yeah, to measure the universe, you only need pie to like seven digits max.
Hardly any.
You need hardly any.
I think seven might even be too many, but we know it to seven trillion at least.
Yeah.
And still going.
How many digits of pie do you know?
Can we do a competition?
Yes.
We can. I think you'll win.
So do you want to go first?
Go on then. We'll take it in turn, shall we?
Okay. Okay. Okay. I like that. All right.
Three point. One. Four.
One. Five. Nine. Two.
Six. I'm out.
I'm out.
Three point one four, one five, nine two, six five, three, nine seven, nine three.
Once you get to, I think it's like the seven hundred and sixty second digits from there, it goes,
999999.99.99.
How many nines is that?
I think it's six in a row.
Right? Which is like, well, that feels unlike. That feels pretty random.
Oh, oh, this is the Feynman.
This is the Feynman. I've heard about this.
Yeah. Feynman would always say that what he wanted to do was to memorize the digits of pi all the way up to 762.
And then just say, 999, 99, 99. And so on.
And so wasn't he a clever guy?
He was.
Okay, so this is the other end of the spectrum, right?
The digits of pier, the other end of the spectrum in terms of the random sequence.
It's not random.
They're random and potentially normal.
Yes.
Well, okay, we should be careful, though, because they're not actually random because
Pi is a particular number.
That's true.
I can predict what it'll be.
It'll be the ratio between a circumference and a diameter of a circle.
Exactly.
But they have all the characteristics of a random sequence.
So, you know, this infinite sequence in Pi where the digits are distributed uniformly, right?
First of all, I want to throw in another definition of randomness.
That I really like, but then I've got a question about it.
And the definition is that when something is, that when something is, you know,
is random, it takes longer to describe to someone over the phone.
So, like, imagine that I flipped a coin a hundred times and it landed heads every time.
I could quickly tell my friend, dude, I rolled a coin 100 times, I got heads every time.
Bye.
Completely predictable, completely ordered.
Exactly.
The results of those flips were random.
Let's say it was just weird luck.
However, that string of digits is...
Easy to communicate.
Easy to communicate.
So is it still random?
So, okay, there's two slightly different things going on here, right?
Yeah, there are, aren't there?
Yeah, two subtly different things.
So one of them is about whether or not the next thing that's going to happen can be predetermined,
whether it's predictable essentially, right?
Whether this outcome is determined in advance.
That's randomness.
But then there's also the other thing here, which is like the opportunity for surprise, as it were, right?
Because you could have, it's kind of going back to that spectrum.
of like a very ordered sequence, easy to communicate, a very unordered sequence where, you know, like taking a chunk of the digits of pie, is really difficult to communicate.
I mean, that, if you were saying that down the phone, you would have to literally read them out one by one by one.
Yeah, right. If I flipped a coin and I got a more typical distribution, I couldn't just call my friend and say, oh, they were all heads.
I'd have to be like, oh, dude, okay, there were two heads, tails, heads. I'd basically have to just read the whole thing.
and it would take a long time.
That string of digits is more random.
It's less predictable, and there aren't a lot of patterns in it.
Well, I don't know if it's more random, right?
But I think it has, well, it's what the information theory is called more entropy.
It's more chaotic.
Okay, so then there's a difference between being random and being high entropy.
Absolutely.
So being random is about whether or not you can tell the next thing that's going to happen in advance.
And having high entropy is about like the number of opportunities for.
surprise. So like in an alphabet, you know, if I had some scrabble tiles, something that was low
entropy would be A, A, A, A, A, A, A, A, right, perfectly ordered, right? Nothing interesting going on.
Something that was high entropy would be like, you know, T, G, D, P, L, W, like no discernible patterns for you to latch onto.
There's two things that are going on here, right? So one of them is randomness, and that's whether or not
the next thing in the sequence is predictable. And it doesn't matter whether it's very, very likely to be heads.
or equally likely to be heads and tails,
it's still whether you or not,
you can absolutely say for certain what it's going to be in advance.
But then there's this other thing that's going on,
which is that we sort of have a spectrum of chaos here.
So at one end, you've got something that's perfectly ordered,
heads, heads, heads, heads, heads, heads, heads, heads, heads, really boring.
And then at the other end, you've got something that is perfectly messy, right?
There's no structure or pattern that you can latch onto.
And at the one end, you're going to be able to communicate that down the phone
extremely quickly and easily. It's just always. And at the other end, you're going to have to
read out the entire thing. There's no way that you can compress that message. Yeah, that's
a very important distinction to make. The difference between randomness, meaning can't predict it,
and how disordered is the result that we got from a random, unpredictable process. You can
throw scrabble tiles on the ground, and it is possible that they'll land in a way that spells a sentence.
That would be highly ordered.
But if they just looked like a mess, it's very unordered.
And I think it's important to point out, and this will keep us in the topic of randomness,
but it's important to point out that this is starting to feel a little bit subjective.
Yeah.
Because what do you mean it looks messy?
What I mean is there's a lot of ways scrabble tiles thrown on the floor can look messy.
There's a lot of ways.
But there's like only one way they can fall on the ground and spell out how I was born.
Yeah.
All right.
And so the fewer days.
different ways something can be arranged to look the way it does, the higher the entropy.
Yeah, absolutely.
Richard Feynman had a quote that I actually wrote in my notes.
We measure disorder by the number of ways the insides can be arranged so that from the outside
it looks the same.
Oh, that's so good.
Yeah.
He really was smart, wasn't he?
Flip a coin 100 times and get heads the whole time.
There's only one way you could get heads every time.
But how many ways are there to get something that's really?
really hard to communicate on the phone, most of them, a bunch. A lot, a lot, a lot. That has
low entropy. Yeah, I like this idea of the distinction between randomness and disorder, which is what
we're really ultimately talking about here. You know, the other thing about the, um, throwing those
scrabble tiles on the floor and getting a sentence that spells out the way that you were born,
is that that's you imparting meaning onto what is essentially a random sequence. Because if you
carried on going forever. If you chucked, you know, scrabble tiles on the floor over and over and over
and over again, eventually, you would end up with something that told the story of your birth and
your death. Well, right. But like, let's just imagine that the universe is really huge, like, infinite.
And that there are intelligent civilizations that number almost infinite as well. Then the chances
that I could throw scrabble tiles on the ground and some alien somewhere could look at.
look and go, that's how I was born using its language becomes higher and higher.
So whether something is disordered really depends on the context that they're looking from.
Have you read the Library of Babel by Jorge Borges?
Yeah, I have.
Oh my God, I love it so much.
I love it so much.
But he had this, it's a really short story.
It's only like three pages or something.
But he had this idea that there was a fictional library, a kind of infinite library,
where every single possible combination of letters on a page existed within the books within this library.
So that in theory you could go in, I mean spaces are included, right?
You could go in and you could go to some shelf in this library, pull a book off, flick to a page,
and it just say nothing on the page at all apart from your name.
My thought it was right written in the middle.
but there would also be a page somewhere in that library where your name would be written vertically, right?
And another one diagonally.
And another one which was just your name over and over and over again.
Every possible combination of a way to write your name must appear within that library.
But the sort of twist on this story is that even though that might be true,
because as you said, the number of ways to order letters on a page,
the number of ways to order Scrabble tiles is so gigantically massive.
what this means is your experience of going into the library
is that you pull out a book, you open a page, it's junk, another page, it's junk, another page, it's junk.
So he has these librarians wandering around this infinite library, looking for meaning,
and essentially finding nothing for, you know, there's one person who has spent 10 years and found half a sentence, right?
Someone found the word, it's a dog or whatever.
Even that's hard to believe.
Even that's hard to believe.
Even though every single sentence possible is in that.
that library, your likelihood of finding one of them in your lifetime, it's got to be close to
zero. It's not zero. It's not zero. Do you know that someone made this? Someone made a digital
version. Yeah, I talked about it in my video messages for the future. And I got to speak to the guy
who made it. And he told me how he coded the site to work. Because yes, it contains every
combination of letters, including spaces, up to a certain number of characters. He only did
every possible page, right, rather than every possible book.
It's not every possible book.
But it also doesn't exist on a server, like every combination.
Instead, it's coded within numbers.
He did a mathematical trick, basically.
That's right.
You can search, and it will find anything you search in the Library of Babel.
Because we already know they're out there.
In theory, they already exist.
But what he managed to do was to create a way that he can order them and allow you to search them.
Right. So if I looked up your name, I would find it on a certain page in a certain book and a certain volume and a certain wing. But then if anyone else looked up your name, it would be in that same spot. So he's cataloged everything that's ever been said and everything that still hasn't been said. It is a little bit scary.
It's really scary. But I also think that what this demonstrates is just how, like, how difficult we find it to conceive of these worlds, right? Of randomness, of combinations. I think that we are just really, really bad at having intuition for what randomness looks like.
We really are. You said something that I want to get back to, which is that the librarians in the Library of Babel are looking for meaning. What is meaning?
Is it meaning something that we effectively create because the universe doesn't provide it?
Yeah. I might not totally agree with that yet, but I think I will say this, that to me, meaning is what happens when information is discarded, but can be put back in.
Meaning is what happens when information is discarded, but not lost.
Go on.
Okay, so let's just talk about someone's name, right?
Like the name Hannah Frye means something. It means you. It means your life story. It means a lot. It means a lot to different people. Sure. But I don't have to refer to you by describing everything about you and everything that you've done and where you are right now. I can just say your name. If someone goes, oh, who did you see today? I don't have to be like, I saw the woman who was born in this town and did it go on and I can just say Hannah. A lot of information has been discarded.
I'm not mentioning a lot of stuff and yet I am.
It's like, you know what?
It kind of goes back to that idea of like, how quickly can you communicate something around the phone?
I'm compressing everything you represent into a single name.
When we ask what something means, we're asking what information has been discarded.
Right.
Okay, you're asking for the invisible thing that you're no longer directly communicating,
but that is common shared agreement between.
Right.
I heard what you said, but what did you not say?
because that's what you meant.
But then here's, I'm going to go back to what I said before,
that meaning is something that we create, right,
because the universe doesn't provide it.
And I actually, I want to double down on that
because the thing is, the words Hannah Fry,
they might mean something now, right?
They might have a shared meaning between people
who are my family or whatever right now.
But this is something that only has existed
for the briefest flicker of time
and will quite soon cease to exist, right?
Like in a hundred years, maybe less, it will have no longer any meaning whatsoever in the same way as like Ignatius spelling, you know, or whatever.
It doesn't have any meaning to anyone.
That means a lot to me.
That was my father's name.
How dare you?
And so, yeah, I think that actually meaning is something that we are creating, that we are putting on top of the randomness that already exists.
Not only are we creating meaning.
It is what we do.
Yeah.
I think our niche is a species.
is that we create meaning.
We discard information to save time, to solve problems.
It's all what cognition really is.
And I think we make meaning just like bees make honey.
Okay?
We take stuff.
We take information from the universe, just like bees take nectar.
And we go, this could be sweeter.
And we discard a bunch of stuff.
The bees dry out that nectar until they've just got to.
this really, really sweet honey. And we take in all this information and we discard stuff until we've
just got this meaningful thing. I really like that idea. I really like that idea. I think we can go
further with it. So I'm going to pause for a break. And when we come back, we're going to see if there are
other ways to make meaning from randomness and disorder. This episode is brought to you by Cancer Research
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Welcome back. We are talking randomness. We are talking meaning. We're talking disorder.
and chaos, all of the sweet, easy subjects for today.
It's been so random.
I think I was thinking about that during the break.
I went to the bathroom and I was thinking, I was like, yep, I think people use the word
random nowadays in the right way.
They're saying, look, I couldn't have predicted it.
I didn't know that guy would be at the party.
So he was a rando.
Yeah, that one I don't mind is when people say, oh, I just crushed my car.
I'm so random.
That's the one that bothers me.
It's like, no, no, no, no.
You can't retrospectively apply.
A person who talks like that is someone that I would predict would be in a car accident.
It's not random.
That's actually my natural voice.
Oh, so you're just like putting on this.
This one is the fake one.
I'm from Essex, you know?
Come on.
Okay, we agree then that there's a lot of disorder.
There's a lot of uncertainty.
But the thing is, I think science is really, really very good at taking that uncertainty.
and using it for our own advantage.
Give me an example.
All right.
One of my favorite stories is back in like the 1700s,
there was a lot of woo-woo in medicine, right?
Even like official hospitals had a lot of crazy, crazy stuff going on.
What wasn't woo-woo back then?
I mean mathematics, thank you.
There's a lot of good mathematics in the 1700s.
But anyway, one of the most amazing bits of woo-woo was this thing called Perkins Metallic Tractors.
You come across these?
No.
Basically, there were these little rock.
and they had pointy ends.
And what you would do is you would go around to somebody who was like not feeling very well
and you would point the rods over the bit of their body that was hurting.
And then technically, if you stood there for about 20 minutes,
they could draw out the noxious electrical fluids.
I think people were quite into electricity at the time.
And they sold for an absolute fortune.
Old Georgie Washington, he had a set.
Everyone was like fully bought into them.
And then there was this guy called John Hagarth.
And he was like, I think this is not something.
Not right here.
So what he does, he went away and he made some little wooden versions of these tractors.
And he painted them to look like the original.
And then he went into a hospital and he was like, okay, there's lots of people here, right?
If I try this on a number of different people and I won't tell them,
sometimes I'm going to use the real tractors.
Sometimes I'm going to randomly assign the other ones, the wooden ones.
And I'll see who ends up getting better.
And he went around and he collected all the data, wiggling these little sticks in front of people.
and demonstrated that the real ones had made no difference whatsoever,
whether he was wiggling the metal sticks,
the really expensive tractors,
or these little wooden toothpicks that he mocked up at home,
didn't make any difference.
But what he was effectively doing there
was he was using the kind of randomness,
the disorder of the universe to his own advantage
to kind of prove that there was nothing special about these tractors.
That's right.
He found their meaning or lack of,
thereof by randomly applying them.
Was it like double blind?
Did the users not even know whether they had the real things or not?
No, because he was the user.
So no.
So he knew.
He knew.
But it was a bit later on.
I mean, it was like the 1940s when controlled trials, random controlled trials.
So he was like one of the first on record to be doing this kind of a random trial.
Exactly.
To find whether there's meaning or not.
Exactly.
Did he look at the outcomes of people that he didn't do any of the treatments to?
No, this is like early doors, right?
So for that stuff, for it to be properly, the point of which it became the new gold standard,
that was the treatment of TB in the 1940s.
And then there was a particular drug.
It was called streptomycin.
And people weren't sure whether it was actually making a difference or not.
Because, of course, you give a drug to some people with TB and they get better.
You give it to other people with TB and they don't get better.
And it's really difficult to kind of hone in on precisely.
the role of the drug in all of that. So that was when they did it absolutely properly. They
deliberately withheld the drug from a randomly selected group of individuals who had TB in order
to work out whether it was the drug that was making the difference or it was just randomness.
Yeah, right, because there could even be a placebo effect where whether it's real medicine
or not, just the fact that a doctor cares enough to give you attention can affect how your body
heals, how it reacts, what symptoms you have. And it's only by harnessing randomness.
and disorder by doing it on multiple people that you can start to separate out some of
things to separate out the meaning the meaning exactly meaning can even emerge from randomness
it uh i think my favorite example is ziff's law yeah ziff's law is this really bizarre phenomenon
that we've observed in every known language we've observed this in craters on the moon i'll describe
it using language so in in languages there are
are words that are used more than others.
And you can rank how often a word is used.
So in English, it's the word the.
Mm-hmm.
The second most used word, as it turns out,
will be used about half as often as the most used word.
Really?
I'm not done yet.
Okay.
The third most used word will show up in texts a third as often as the number one.
The fourth, a quarter as much.
The fifth, a fifth as much, and so on.
Really?
All the way down.
I did a video about this and I just I said well Vsauce is my YouTube channel.
I'll check the word sauce.
And I don't remember the exact number, but sauce was like the 5,000th most used word in English.
And it showed up one 5,000th as often as the word in the Gutenberg corpus and in Google's corpus.
I was like this is incredible.
And so what's going on, right?
Yeah.
I mean, that sort of feels like it's not random.
That feels like it's like an imparted pattern.
Maybe it's put in there by human minds.
No, because we see this in craters as well.
Crater size and location, it follows Ziff's law.
The most common size shows up a certain amount of time.
The next most common shows up half as often as the most.
And it's incredible.
But then later, it was found that Zipf's law is also obeyed by random typing on a keyboard.
No.
Yep, that just a monkey slap in a keyboard is going to also create a language that follows Zipf's law.
Wait, so hold on, hold on, hold on, though.
What counts as the most common thing there?
Like a combination of letters?
You just treat it like their words and you say, what's the most common word, which means letters that are separated by spaces.
What's the most common word that the monkey's typing?
And then you look and they're going to follow the same pattern.
And that is because the space bar is what defines a word ending and beginning.
The space bar is one of the keys.
So imagine a keyboard that just had letters and a space bar.
It's got 27 buttons.
Eventually, you're going to hit the space bar.
And that makes shorter words more likely than longer ones.
A longer word means that you've gone a long time without hitting the space bar.
It's much less likely.
And how much less likely?
You can look at the math behind it and it just forms that exact same shape.
Wow.
So actually, what Zip's Law is doing there is that it's like this inherent pattern.
that appears when things are generated effectively at random.
And when you stand far enough away,
which brings us back to that subjective quality of randomness.
Like if you zoom out, you see a different view.
Yeah, if I look at a bottle of gas really close up,
those molecules are going everywhere.
They're bouncing off of each other.
It's incredibly chaotic.
Maximum disorder.
But I go far enough back and I go, oh, it's cooling down.
Or, oh, the hot air at the ground floor is rising.
It becomes incredibly predictable the further away I look, even though at the microscopic level, its nature is randomness.
And that's it, right? That idea of like sliding along from order to chaos, from like clean everything being the same to messy disorder.
Actually, that's a function of scale as well, like you zoom in, zoom out.
You know, you see this in patterns of human behavior as well.
One of my favorite examples of this is burglaries.
So your chance of being burgled is actually at its highest when you've just been burgled, right?
So in a lot of ways, burglaries follow a similar pattern to earthquakes, right?
The very first shock is very difficult to predict.
But once something has happened, then the aftershocks in inverted commas have this kind of very clear pattern.
They get smaller and smaller and smaller as you go further away from the epicenter and they also decay away in time.
A few people notice this with burglaries, right?
that it's like if you look across a city,
it's really hard to say,
here's where a burglary is going to be for the first one.
But once a group starts targeting a particular area,
particularly in cities where houses are structured in the same way
all the way across the street,
you know,
people get to know their layout of the house,
they get to know where you keep your valuables.
Also people replace their valuables.
I mean, that's another thing, right?
Or it might be that they had been and spotted something
and wanted to come back for it
because they couldn't get it the first time.
So a little while ago,
this is maybe about 10 years ago or so,
A group of mathematicians and criminologists, they noticed that there were these patterns that actually, even though they were random, and when you were at the scale of the individual, when it's your house being burgled, right?
It feels like there is no order anywhere here.
But when you zoom out to the scale of the city, actually there's a pattern that appears in the randomness.
So what they did is they created these tools that could be used by police so that if a set of burglary started, these tools could say, okay, this is where we predict their likelihood.
to happen next.
And Kent Police in particular, they were one of the earlier doctors of this.
And in the first few weeks, I mean, they had this amazing drop in the number of crimes,
like eight and a half percent drop, right?
Really kind of demonstrated this proof of concept that there is some predictability.
There are any patterns you can latch onto.
There was one story in particular of where this model that had been created told Kent Police,
you need to go to this particular square on the map.
This is where crimes are likely to have.
happened tonight. The police officer turned up, pulled up in a car, and as they arrived in the street,
they saw someone climbing through a window, burglling house. Right. Now, okay, that story sounds really
positive, right? And everyone got very excited about this at the time. The problem is, if I tell you,
here's where there's likely to be events happening tonight. Here's where Berger is likely to happen.
And you're the police, right? Your options are quite limited because what you can't do is suddenly
change all of your officers to like flood that area because then what you're doing is you're
disproportionately policing particular neighborhoods over others and then of course you're going
to capture more crimes which then just makes the model think that area is a worse area and so and
you get to the point where you're actually using statistics to kind of harass particular
neighborhoods right which is very bad so what they do now is that when there has been a burglary
they still have the models running saying this is where they're likely to be they'll post a leaflet
through your door and they'll say your chances of being burgled have increased.
Make sure that you lock your windows. Make sure that you lock your doors. That does have
a genuine quantifiable decrease in the probability of burglary across an entire city.
Wow. It's a very chaotic system, isn't it? That you've got the behavior of the burglars,
but then also the behavior of the police. And so if they're catching more criminals,
because that's where they all are, then that feeds back into the system. And it's a double
pendulum of crime. It just gets very messy very quickly. I mean, I would sort of say that a double
pendulum in the original sense is a bit of a crime to watch it. But let me tell you this, triple
pendulum. Oh, God. Just imagine. No, I can't. It's too, too chaotic. Now, when scientists need
random numbers, where do they get them? Because as we've been dancing around, like, the more
knowledge you have, the less random something becomes.
And so we have to look at probably the most confusing things.
Lava lamps.
Their behavior is very chaotic.
And you can train a camera at a lava lamp and just ask,
is a blob going to cover this pixel or not?
And that can generate the numbers that you need,
have like no patterns, completely unpredictable,
just like the lava lamp.
Random.org uses static electricity in the atmosphere
to generate random numbers.
You can go there right now and tell me, give me a bunch of random numbers between one and 100.
And it does a pretty good job.
I mean, good in the sense that no one's going to be able to predict what it produces.
However, to a certain extent, it should be predictable.
If you knew a lot about the atmosphere right now, you would have a better chance of predicting what numbers it's going to produce.
But since most of us don't, it's random.
In order to find meaning, we have to, and we're advantaged by using randomness, random trials, right?
Which means that to find meaning, we need those things that have none.
Mm-hmm.
What a wonderful yen and yang.
Wait, let me just sit with it for a second.
So in order to find meaning from things that look random,
we need to use things that have no meaning at all.
Yeah.
To be able to separate out the two.
Yeah.
That's nice, isn't it?
You need both bright and burning.
Yeah.
I like that a lot.
You know the Enigma machine during World War II?
Basically, it's like a typewriter.
where you type in your message and it has a series of cogs and dials that changes,
if you hit like the letter G, for instance, it will, behind the scenes, this mechanical thing
will change it into, I don't know, a letter R, for instance.
And then when you hit G again, those wheels will have turned around and it will generate a different letter,
T for instance, okay.
So the idea from the Germans' perspective was what they wanted was it to just look like
a random jumble of letters.
But what the British realized, even though when you were,
originally look at these encoded messages, it's really hard to grab onto anything.
What the British realized was that there was little bits of meaning in there that they could
latch onto.
And one of them in particular was that messages that were sent would often end with the message
Heil Hitler.
So they knew that the last few letters of any communication were likely to have been that.
And so they managed to like grab onto.
that little bit of meaning hidden within the randomness in order to decode the entire thing.
Wow.
But then there's also another level of meaning here because what you would do is you would set the dials in a particular way.
You would have like a particular code of two letters or three letters that would allow you to set the dials in a particular way for that day.
And they worked out that what the Germans were doing is they were choosing the letters of their girlfriends.
Oh my gosh.
initials, right, or their wives. So they had this little book, which was just all of the German
military personnel that they were targeting that they knew were sending these messages, and all
of their lovers and mistresses and girlfriends. And now you've got a really short list of initial
settings to decode. To try, to kind of, to like shortcut you. So just by learning who the Germans
were dating, the randomness became a lot less random. Because we can't help it, right? Humans can't help,
but in part meaning.
We put this meaning in and then it all unravels.
So is this related to the question of,
I'm going to flip this coin, I'm going to catch it.
Yeah.
And I'm going to put it down on the table.
Yeah.
What's the probability that it's heads or tails?
50-50.
50-50.
Okay.
You just looked at it.
And now what's the probability?
For you or me?
For me, it's 100% tails.
Because I saw it.
it. Or you're lying. But for you
it's still 50-50. Right. Probability
is a measure of our ignorance. It's not a measure of something that's objectively
out there in the universe that God would know. No.
No, I totally agree. A supremely omniscient creature would have to go
the probability, hmm, for who? How much do they not know?
As the police learn more or as the love lives of the
Germans become more known, meaning emerges. Meaning emerges.
You know how you were talking earlier
about how humans are these basically
meaning machines, right?
They're like, we live in that space
between perfect order and perfect chaos
and that is where you can find meaning.
I think that's true beyond just like human experience.
I think that's also true for like the whole reason
we are here in the first place.
So in the 1960s there were these two astronomers
who were putting telescopes in the sky
like recording loads of information
and there was basically this this constant
hiss in their antenna, right?
They just couldn't get rid of it.
Now, I haven't checked the news for decades, but it was just birds, right?
That was, I think, one of the original hypotheses, but then they tried it to non-bird places.
Oh, so they fixed that?
And so the noise went away?
No, the noise did not go away.
Literally, wherever they went, they tried it a day, they tried it at night.
They cleaned out pigeon droppings from the inside.
They felt that might be the cause.
Nothing would get rid of this hiss.
It felt like it was very random, right?
It's like static on your TV.
It's kind of no discernible source.
this just like total cosmic mystery.
And what people eventually worked out
that actually this random noise,
it wasn't an error,
it was what's become known as the cosmic microwave background.
Essentially they're like the oldest light in the universe, right?
The residual heat from the Big Bang,
this like afterglow that has been traveling through space for billions of years
that now appears on Earth as this electromagnetic bit of radiation,
a kind of crackle on your TV sets.
if you were born pre-1995.
But anyway, since then, what people have done
is they have used satellites to like map out this noise
in verticomers in like this exquisite detail.
And what you see is that at the moment of the Big Bang,
we were so, so, so, so close to having AAAAAAA, A, A, A, A, A, A, A, A, right?
Or heads, heads, heads, heads, heads, heads.
It was unbelievably close to being completely ordered.
The entire universe had almost no,
fluctuations in it whatsoever. So the estimates are there it was variations of less than one part in
100,000 in terms of temperature, right? It was almost completely blanket uniform, but it wasn't
totally uniform. It was somewhere on that spectrum between perfect order and perfect
airs, just nudged ever so slightly to the right of perfect order. There were these little quantum jitters,
right, these like tiny little variations in temperature. And what that meant was that over time,
Gravity started to form around those really tiny variations.
And that then became the seeds of every planet, of every galaxy, of every solar system that we have,
every star that we have across the entire universe is because of those tiny little moments of non-order in an otherwise order state.
So if this early universe, which is that's what the cosmic microwave background radiation is,
it's like the furthest away light.
It is us literally looking at what the universe looked like when it was 300,000 years old or something.
At the moment it became transparent.
Yeah, absolutely.
Okay, a long time ago.
Yeah.
If that had been more disordered, what would the universe look like today?
Yeah.
If it had been a complete mess, it would have been black holes everywhere.
Okay, and what if it had been super ordered?
If it had been perfectly ordered, death.
Nothing would have, nothing would have formed.
But because of these imperfections, gravity is eventually able to make,
Not black holes, but galaxies, planets, koalas.
Exactly.
Exactly.
On the hierarchy of things that we care about, yes.
And that's it, right?
This is this sweet spot in between.
It's where there is the potential to surprise,
but the potential to create meaning,
by which in this case I literally mean planets,
you know, the physical matter on which life can form.
The only reason why exist is because,
there was randomness. So mountains and scratch cards and gingivitis only exist because of
randomness. Only exist because we live in the sweet spot between order and chaos. The sweet spot,
just random enough to be interesting. Yeah. I'm going to go one further and say it's not just
the physical matter. It's not just living organisms. But I'm working on a theory that consciousness
itself comes about because the universe has no meaning.
Go on.
So that's the short version.
The elevator pitch is that you exist because life has no meaning and you are alone,
which sounds sad.
But like if our universe was completely uniform, discarding information didn't matter because
there was just one thing.
Then there would be no reason for a creature to evolve that incited and excited information,
that created meaning.
Because there would only be one meaning.
But we don't live in a universe with meaning.
We live in one that is filled with lots of different meanings.
I can make anything mean anything.
So we'll do an episode on consciousness later, but I think that we need to have a certain amount of complexity,
which is the name for this region in between chaos and order.
We need a bit of complexity for a creature like ourselves to exist and a creature who needs to figure things out in its own head,
pack up meaning and unpack the meaning.
that all happens up here.
And I think long story short, we wind up kind of living in here a little bit.
And that's where the concept of a self emerges.
That I am a conscious being who lives in my interior.
All of this only happens because the universe has no single meaning.
It's got a lot that we get to make.
Hey, look, I think that there's no more positive way to end an episode than to say life exists because the universe has no meaning.
That's the, you know, perfect possible wrap-up.
Apart from actually these scratch cards, which we still haven't done.
Oh, my gosh.
Let's do it. Let's do it.
All right.
All right, guys.
This is it.
So the symbols that we want to match are either a plant, a window, a house, a chest, or a bulb.
Mm-hmm.
The winning image is a stack of coins.
So basically none of us want anything.
The delicious taste of defeat.
Next time.
time. Well, that is a wrap on this episode, but there is a lot more where that came from.
So please do make sure that you are following The Rest is Science on YouTube or wherever you get your podcasts.
Make sure that you like and subscribe. Okay. That's my message to you.
Do it. And you can always reach out to us at the rest is science at gollhanger.com.
See you next time.