i like you very much !

You know what's really cool? The second chromosome in our body has been genetically spiced which cannot happen naturally so it is fair to draw the conclusion that either we have lost technology that allowed genetic manipulation or we have been made by some other form of life AKA aliens... one of these is the truth and it is a logical 50/50 split with 100% chance one of these is the truth...

How is everything not equally complex? Everything in existence came from the Big Bang which is a singularity state. Anything that exists is equally complex as anything else... all existence is God here this is a god eat God world... face the facts...

What people fail to realize is that everything came from The Big Bang singularity... if anything exists anywhere in this universe it exists everywhere for everything is from the singularity.

I address everything from the root therefore I am never wrong... anyone doing anything different is going to fail in comparison to me...

Agreed! Moreover, the 'basic' description may well not be the _shortest_: if you consider a system consisting of an iron sphere floating through an infinite vacuum, then we can model all state variables using a much simpler model (treating the sphere as a point object with some fixed velocity) than the fundamental physics of all constituent particles -- moreover that complexity would be more or less constant across a large range of sizes of the rock, at least until internal repulsive forces begin to fail, even though the base system would get more and more difficult to compute using the naive method described in the video. Both of those facts (there existing a simpler model than raw particle physics, and that that model is to an extent size-invariant) are also true of a clock, but the simplest model for such would still have to be more complex than the simplest model for an iron sphere.

If we accept Kolmogorov complexity, we will need to take seriously Dembski’s schema regarding Complex Specified Information, and the “conservation of information”. Also, Stephen Wolfram’s “A New Kind of Science” is relevant.

But isnt Kolmogorov's complexity really a measure of "disorder" instead of complexity? A "completely random" sequence (generated by white noise) of elements would take a longer program to recreate, if compared with a "complex" sequence (that necessarily would have some kind of correlations that allow us to compress the sequence).

@@adolfobahamondealvarez5739 It certainly is a measure of disorder. A uniform sequence of a repeating constant value would have the lowest kolmogorov complexity and and a totaly random sequence would have the "highest", with Sheakspeare somewhere in between. You're totally right in that merely higher kolmogorov complexity does not mean higher actual complexity. However, it is still, in my opinion, extremely useful because it mathematically bounds actual complexity. We still don't know what it is but we can be sure it must be more than x and less than y. Putting bounds is useful.

@@yakovdan Quite possibly I don't properly understand Kolmogorov complexity but producing random noise with an algorithm doesn't seems long or hard if you are satisfied with a pseudo random solution and seems impossible if you want a true random one, thus I am not convinced that it isn't really a good measure of complexity in most practical cases.

"A New Kind of Science" by Stephen Wolfram. A great nerdy read.

Yeah, looks like Ms Hossenfelder isn't aware of Wolfram's NKS otherwise she would have mentioned it even if she didn't like it.

@@NewsBytesOnKZbin It's not yet scientific. It doesn't make any testable predictions, nor has he worked out how it explains the existing measurements. It's a very long rant about complexity that's unassociated with physics, and his physics thing is (so far) unassociated with science, until he manages to work it out far enough to make predictions.

​@@darrennew8211 The "science of complexity" has the same implied "structure" as the "science of Evolution" has. By definition the "science of evolution" does not make predictions, because it implies prior knowledge of changes in the environment in which the Evolution/Complexity emerges. The "science of Evolution" has mostly explanatory properties rather than predictive properties. The same should be true for any " science of Complexity".

@@reasonerenlightened2456 Evolution certainly makes predictions. For example, if you count the number of chromosomes in an ape vs a human, humans have one less. The science of evolution predicts that you find telomeres in the middle of one chromosome, which you do. Evolution predicts that sea creatures that swim quickly will tend to all be streamlined. Evolution predicts there are *not* giant jumps in the fossil record, that we don't find rabbit bones in the bellies of dinosaur fossils, etc. Hell, evolution predicted the existence of DNA well before DNA was discovered. Darwin figured evolution wouldn't work if traits could be diluted, so inheritance had to be some sort of digital/discrete mechanism, which Mendel later showed was the case. That said, yes, evolution isn't going to predict the way in which creatures evolve in the future, because that is too complex, as you say. It's definitely less predictive than fundamental physics stuff, for sure. I'm not sure what Wolfram's "science of complexity" was trying to predict. I read the thing, but I don't remember it making too many predictions about the structure of measurements.

Indeed, for the purposes of control and prediction it is more important how much interconnected (interdependent) the individual components of a system are than the number of components. As far as the role of software engineer is concerned, it is long overdue for a code to be written which treats the human as a consultant to the code that writes code instead of the the human being the code writer. Even better, the human must become like a customer to the code that writes the code the human needs, you just tell it what you need as you would do to another human, and the code gives you the code solution that will work for you. Do not confuse what I am saying with the stupidity of the chatGPT technology that currently became popular. The chatGPT technology and the likes (for images, video, sound, code, control, etc.) just have the veneer of intelligence.

read NASA guidelines

As a product designer who designs systems to control mass production lines, I like the c4 model of software architecture. I like to use it to map and understand the user requirements and flows.

​@@reasonerenlightened2456well, it's still garbage in, garbage out. You want a human to tell the code what it wants and the code will take that as an input and convert that into code that does what the human wants. However, any kind of function suggests both implicit and explicit properties/aspects. It's only when beginning to use and test the first code iterations that it becomes clear what was implicit that needs to be made explicit. We call those implicit things that haven't yet been handled 'bugs', because they create the possibility for an unwanted output without the means for handling a correct output having been made explicit.

@@512Squared Machine learning still does not understand "iterations".

Interesting .

a very mentally ill man with severe schizophrenia

This has been pointed out by Auguste Comte two centuries ago. The modern scientists think they have invented everything.

Pirsig is a wonder. He's probably the guy that came the closest to realising enlightenment, the closest to walking through the door, without actually walking through it. Even though logically he saw that Quality was the Tao, the source of all individual things, he still could not 'feel' it, feel himself as just a manifestation of Quality. So instead of feeling so happy and free, realising there was no individual named Robert Pirsig, nothing for him to do, nowhere he was supposed to go, no burden of the future or even the present moment on his shoulders, and went about his day like many mystics do, he instead only realised that logically, and reasoned there was no reason to get up so urinated on the floor, no reason to stop the cigarettes from burning his fingers, no reason to do anything. The logical part of his brain realised the truth, but could not let go and let the emotional part of his brain feel it in the experiential dimension. This 'letting go' is crucial for the process. Without knowing, without understanding, you let go and trust the Tao, the universe, whatever you want to call it, to do you, rather than you doing it. Pirsig seems to have never done this. Chris' death made it worse. "Where, after all, did he go?", he asked over and over. Lila is an agonising attempt to answer these questions and analyse Quality without ever having actually felt himself to be a manifestation of it, without ever having felt the 💙love💙 that is another name some people give to Quality. He never let go and Lila is strained at best, torturous at worst.

@@philharmer198 I expanded your answer. :-)

Don't forget to collect your Nobel prize when you figure it out.

Overall function vs size? I don't like recursive code, even if it makes a very small program. Can be a right pain to debug.

@@threeMetreJim to be honest, I haven't really looked really deep into it. But it looks like there are some methods already. Since there's no perfect way to measure complexity in physics, there's no perfect way to measure complexity of software. Because everything emerges from physics.

Software engineers being software engineers, there have been software tools written to measure software complexity. Like Testwell.

How about something along the lines of product-sum ratio of the number of functions defined and the number of calls to those functions multiplied by the number of variables parameterized by those functions, though I suspect that the ratio between number of value and reference parameters will need to be considered as well. User-code only, as I would assume you don't care how complex the generated machine code is, just the user-code-base you need to maintain. First bit is an attempt to measure the size of the code-base against how much it interacts with itself, second bit is an attempt to measure how much data is being moved around. More considerations might be needed to compare dissimilar code bases, perhaps incorporating the average number of lines of code per function in attempt to get a ball-park measure of the code's relationship to spaghetti... /two cents Edit: If this ends up helping, I'd be happy with 10% of the prize money and an acknowledgement in your Nobel prize winning paper. XD

Agreed.

And one of her best!

Can you point to resources for understanding how information content and complexity might be different?

@@pbajnow wikipedia -))))?

@@dancroitoru364 I get that. But order, information content, entropy, and complexity all seem related but maybe different in common usage.

Yes, a true gem lol

Plus the length of the program, a point Sabine seemed not to grasp: as if she confused the programming language with the program itself.

Still her point is coherent in this context. Anything with the same number of particles has the same number of quantum states, and that also implies that it has the same order of magnitude of entropy insofar as an algorithm is concerned. A baby is just atoms, exactly the same as a rock. Simulating a same-weight rock and a same-weight baby is exactly as computationally complex, yet this doesn't fit our idea of complexity, so it can't be an accurate measure of complexity from our perspective.

@@Zeuskabob1 I completely disagree. It ignores the effects of the processes going on inside the brain as well as all those going on inside the body. Her statement that "If you went by Kolmogorov complexity everything would be equally complex" is just completely wrong. She just said in effect that all programs are the same length. I cannot imagine how Sabine made such a huge error. That's just factually wrong: very much a rarity in her videos, but this was one. (She did immediately follow by saying that "That makes no sense.", but then why did she choose to make the statement?)

Ya it didn't really make sense to me either because Kolomogorov complexity requires a turing machine or something like it. Which means you would somehow have to reduce the dynamics of the baby, rock, etc. to some type of turing machine and prove lower bounds on program size. Yes the dynamics are all describable by in QFT but the dynamics would be (and should be) extremely different even in the QFT formalism

Even your own brain?

Really, you figured out how the most complex things in the universe work? How much did it cost? Tell me how to build a gene drive. I'm passively putting together the math model. Tell me what you know. Bruh.

@@ADUAquascaping That becomes a culinary question.

Do you use NetLogo to model your systems biology? You should. It is easy, You define your environment, you define your agents, you define how the agents interact with each other, and the environment,...and how those interactions change the agents and the environment. Then you sit back and observe emerging behaviours. The only limit are the accuracy of the assumptions your model makes.

Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

Thank you from the entire team!

What

hmm? 🤔

There is no free will but don't worry 😊

Construction is dual to destruction, creation is dual to annihilation. Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

A relevant question is whether the property (conductivity) of the collection of atoms could in principle be predicted given complete knowledge of the physics of a single atom.

The answer is an emphatic no.@@brothermine2292

​@@brothermine2292You can't, because arrangement matters. Graphite and diamond have different conductivities despite being made from the same atoms. Defects matter as well. And temperature. Not to mention impurities. While you can in principle calculate for a given arrangement and conditions, this becomes impractical quickly as you scale up. Exploiting symmetry helps, but defects break symmetry.

@@michaelinners5421 : Yes, arrangement matters. But why couldn't one in principle predict the emergent property (conductivity) for any given assumption about the arrangement (positions, momenta, etc) of the atoms?

@@brothermine2292 You will be able to predict IF you have a theory and understanding of the electronic structure of multiple atoms. This means valence bond theory or molecular orbital theory. So, just the "complete knowledge of the physics of a single atom" will not be enough. You need to understand the physics of what states the collection of atoms can have. Does this make sense?

It all depends on how simplicity and complexity are defined in any given system, and the more configurations that a system has the more ways there are to describe it.

You neglect that since entropy grows, complexity will eventually become impossible.

@@bodeeangus9957 *"It all depends on how simplicity and complexity are defined in any given system, and the more configurations that a system has the more ways there are to describe it."* ... The number of particles that make up the living, breathing, self-aware lifeform called "you" can be counted. Another structure can have the exact same number of particles, but be completely void of life and self-awareness. *Conclusion:* An equal mathematical assessment of two distinct objects does not dictate that they are equal in complexity. Mathematics, material substrates, and particle configurations are not the arbitrators of "complexity."

@@brothermine2292 *"You neglect that since entropy grows, complexity will eventually become impossible."* ... 13.8 billion years ago there was nothing but a totally benign point of singularity. That is as _least-complex_ as one can get! Today we have eight billion living, breathing, self-aware lifeforms running around exchanging information in a KZbin comment thread. If you charted the evolution of complexity like we do with the stock market from its beginning to now, the "complexity line" would be consistently moving upward. ... That is the way "reality" is presented to us.

@@0-by-1_Publishing_LLC Then what exactly is the parameter that we can use to measure complexity? Atoms make up everything, but some things that are made of atoms can move and others cannot, but that still doesn't answer the question of how complexity is defined. The question of what complexity actually means is likely to be sensitive to the context of whatever system is being studied, because while we can call a life form complex, we can say the same thing about a star for instance. Is the sun more complex than a human? How do you quantify something like that?

This was a great talk about a very interesting topic which is far above my pay grade....I have a small library of books from 10yrs ago when this was a hot topic.....your comments hint at how the concepts have grown......my favorite issue is "self organization of complex/chaotic systems" which seems to me to be the edge of answering the question of how RNA/DNA got started......but now I must "just shut up"

@@docjohnson2874 Don't give up, Doc! 🙂

You should look at Kolmogorov's complexity en.wikipedia.org/wiki/Kolmogorov_complexity

Yeah, this is a mistake in how Kolmogorov complexity is explained in this video. You cannot seperate out some input (i.e. arrangement of particles) from of the program. A program cannot take input when you want to describe its Kolmogorov complexity, thus the input needs to be included/encoded in the program itself, thus affecting the program size and the Kolmogorov complexity.

There is also no distinction made whether "complexity of a stone" means: - The complexity of one specific stone that you take as an example, or - The complexity of the characteristics that an object needs to have so that it falls under the category "stone" In the latter case, the Kolmogorov complexity would depend on how broadly you define the type of object you want. In the former case, it would be about the same for any real object, maybe depend on its size or number of particles. The algorithmic complexity in the video seems to refer to how complex it is to simulate the physical evolution of the object, but not how the object is made up in the first place.

@@tmlen845 I think that a major issue in the notion of complexity @Sabine is speaking about is that it is unclear that one needs to distinguish the complexity of a system (that is any mathematical or physical object) from the complexity of its properties. One such properties being its predictability. And I think that we can roughly agree that a system is "predictable" if you can "infer" its future states faster than the speed of time. (That is, you want to know what happens tomorrow today) The thing is that the complexity of a a dynamic system is not really related to the complexity of any static state of this system. Take the Syracuse sequence "u(n+1) = if 'n is odd' then u(n)/2 else 3 u(n)+1" quite a simple system yet it's dynamic is quite complex. Another example is the "full network" disagreement, there is actually no disagreement, I think everyone can agree that this network is "simple" in the sense that it is easy to describe. The fact that it is more "complex" than the empty network is not a matter of complexity of the network (seen as a graph) but rather a matter of complexity of the underlying system or worse of complexity of the dynamic of the underlying. system.

Yet I also agree that we do not have an airtight definition of complexity, good thing for me considering I'm finishing my PhD on a closely related topic :-)

RM3, non-binary logic, categorical logic --- validity is better than truth? Because mere truth is binary and not a real thing in the real world, there is always a third possibility that is Valid

I’m not on the same boat, but I’m looking across and trying to distinguish the possibility of methodology and intriguing concepts that invariably make us ask more questions 😊

The truth is out there. We need to go into space. That must be the biggest goal of humanity. As in the era of the sailing ships exploring the world, we need to embark on the same journey in the ocean of space. We have hit a theoretical limit, we must now push the pragmatic possibilities. It's cyclical and we need to embrace the half of the cycle we are in now.

IN THE INTEREST OF FINDING THE THEORY OF EVERYTHING: SOME THINGS MODERN SCIENCE DOES NOT APPARENTLY KNOW: Consider the following: a. Numbers: Modern science does not even know how numbers and certain mathematical constants exist for math to do what math does. (And nobody as of yet has been able to show me how numbers and certain mathematical constants can come from the Standard Model Of Particle Physics). b. Space: Modern science does not even know what 'space' actually is nor how it could actually warp and expand. c. Time: Modern science does not even know what 'time' actually is nor how it could actually warp and vary. d. Gravity: Modern science does not even know what 'gravity' actually is nor how gravity actually does what it appears to do. And for those who claim that 'gravity' is matter warping the fabric of spacetime, see 'b' and 'c' above. e. Speed of Light: 'Speed', distance divided by time, distance being two points in space with space between those two points. But yet, here again, modern science does not even know what space and time actually are that makes up 'speed' and they also claim that space can warp and expand and time can warp and vary, so how could they truly know even what the speed of light actually is that they utilize in many of the formulas? Speed of light should also warp, expand and vary depending upon what space and time it was in. And if the speed of light can warp, expand and vary in space and time, how then do far away astronomical observations actually work that are based upon light and the speed of light that could warp, expand and vary in actual reality? f. Photons: A photon swirls with the 'e' and 'm' energy fields 90 degrees to each other. A photon is also considered massless. What keeps the 'e' and 'm' energy fields together across the vast universe? And why doesn't the momentum of the 'e' and 'm' energy fields as they swirl about not fling them away from the central area of the photon? And electricity is electricity and magnetism is magnetism varying possibly only in energy modality, energy density and energy frequency. Why doesn't the 'e' and 'm' of other photons and of matter basically tear apart a photon going across the vast universe? Also, 'if' a photon actually red shifts, where does the red shifted energy go and why does the photon red shift? And for those who claim space expanding causes a photon to red shift, see 'b' above. Why does radio 'em' (large 'em' waves) have low energy and gamma 'em' (small 'em' waves) have high energy? And for those who say E = hf; see also 'b' and 'c' above. (f = frequency, cycles per second. But modern science claims space can warp and expand and time can warp and vary. If 'space' warps and expands and/or 'time' warps and varies, what does that do to 'E'? And why doesn't 'E' keep space from expanding and time from varying?). g. Energy: Modern science claims that energy cannot be created nor destroyed, it's one of the foundations of physics. Hence, energy is either truly a finite amount and eternally existent, or modern science is wrong. First Law Of Thermodynamics: "Energy can neither be created nor destroyed." How exactly is 'energy' eternally existent? h. Existence and Non-Existence side by side throughout all of eternity. How?

​@joeboxter3635 'you are the field, and the knower of the field' - old Eastern proverb. Thing is, we already know, intuitively, however, our unique perspectives from our individual observer positions causes the 'truth'to slightly fluctuate between actors.

Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

I'm confused. In what terms were you thinking before?

Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

The mere existence of connections adds a certain complexity, but the dots remain identical, which reduces complexity from the state where only some dots are connected only to some other dots. Maximum complexity lies somewhere between the unconnected and fully-connected states, as in neural networks (and our brains.)

@@jpdemer5 I think of aligned complexity as what you described as the in-between the unconnected and fully connected states. which I think describes intelligence, looking at it this way you can consider systems where the path of least resistance is chosen as intelligent(like light, movement of charged particles, water flow, etc. but in general they are complex systems all connected and offering other paths that are not taken. I think of them as functions that can be called if a certain if-else statement is fulfilled.

Wdym by aligned complexity

@@l1mbo69 Having a way of finding the solution to a problem faster than brute force.

if we are only talking about the complexity of description, then no connections vs full graph is exactly the same: for any two functions they are either always connected or always disconnected. You know this bit of information ans you can reconstruct the graph just knowing its size. Now if you want to consider complexity of operation, a dynamic one, you are actually talking about possible traces, paths in this graph, which are a different thing altogether

And one week later the gravity video, can't decide which one is the best. She's a extraordinary teacher and human.

Exactly. First useful commentary on that matter/video!

The way forward, then, is to realize that we don't need to agree on what is being measured! What we need is multiple measurements of utmost precision and accuracy. Then we can produce theories of thermodynamic complexity, chemical complexity, biological complexity, social complexity, computational complexity, theoretical complexity, and any kind of complexity produced by a system of well defined measurements and/or theories.

@@ywtcc yeah we don’t need to but when we don’t share or share too much, people get confused and turn to magic and religion. It’s present in the patterns of connections. Like how matter is fueled by energy and that energy allows a flux or change and now all the big can change to small and small to big and we exist between. Multiple variables come together of different shapes and sizes such as quantum particles and macro like planets or giant bodies of water or something in space waiting to be connected to more so that the differences of 6 plus 7 can blow up and create everything in between and then when the combos in between start gaining layers and more variables then they can see what is not. Look at how we see chemicals and those variables and how the structures and bonds share energy through those connections. Plants, cells, chemicals, made into all this. The Big Bang set in motion the very variables and now we reflect and connect. Our brain grows different cells in different patterns and edits them through the senses and diet and such so that we can survive and grow. We take in patterns connected to a whole and we don’t see everything. That’s apartment when dealing with radiation and X-rays and stuff. We lack the biological tools to sense them but we created them and connected the inputs to a different form called language and understood them through the details of connections and recognizing the reflections. Sounds like magic but it’s like connect the dots on steroids.

@@ywtcc i mean think about it, we became complex over time, what is time but a measurement of change in relation. The sun and earth and moon are just the same as the people and the cycles we shift through. We are the same. As above so below. It’s more than one saying because it’s everywhere. A paradox is like both sides of the same coin so which makes the other but it’s a connected and intertwined connection where they make each other sharing the energy. We try to leave something behind that can contain the complexity of the pattern so that we can persist and grow, we draw and do art because it is another pattern we reflect because we noticed a deeper complexity just a little to the side of others. Conscious growth and connection and thought is what came forth but think about this, how many people are conscious when they just live their lives? They bounce around the environment because they live in it and get changed by it but how many stop and think of a different pattern from somewhere else that makes them see different? How many preform an action that isn’t what the environment grew into them? Do people ever sit back and wonder why they see through their eyes? I think we do but we don’t use our conscious will to do what we want and instead we’ve been trained by the media and such to only believe this and don’t trust each other. I mean our society hates each other somehow when we should be listening and trying to think of things other than what reality grew into us. Be conscious of thought and grow a new thought beyond what you currently are. Idk how else to put it. We give up our why because we don’t see it but our why is everywhere and we just haven’t learned enough to see it. There is no why, there is only so live.

This boils down to the first term psychology question about what intelligence is. The correct answer is: It's the thing you measure with an intelligence test. That's why definitions are so hard when you enter the terrain of complexity: Complexity is too much for our understanding, so we have to break it down into models (thus reducing complexity) to have a grasp on it. And this very step is where different people (and scientific disciplines) extract different metrics/variables to suit their needs of the model being able to make predictions. So maybe we need different approaches to measure complexity depending on which property of complexity in a given system we are interested in.

Exactly my though. For me the complexity of a system depends on the number of significant interactions (at that emergence level) you need to account for in order to predict the exact outcome.

so how does your framing differentiate between two colliding galaxies and two people talking with each other, for example? And how is a "significant interaction" defined ? Seems to me like it's just pushing the definition of "complex" to be based on the vague term "significant"...

I agree, but I think there's a psychological component. How your brain categorizes thing contributes to whether or not you will view things as different systems. You can view many body systems as the same system, and it's largely arbitrary that we separate them. How do you have an immune system without a digestive system, without a skeletal system, without a cardiovascular system, etc etc etc.

​@@JundArbiterImagination can definitely be emergent even when bound by karma/conditioning... is there emergence via an omniscient consciousness, or is the universe a block theory coupled with determinism and randomness. We know there is supposedly no free will, so consciousness is just an emergent property derived from determinism and randomness? This is what the mathematics shows, but no one really knows where the energy/information is coming from. Observation is a physical act and can alter non-local reality, yet has no unit of measurement within the quantum wave function. So it's a simulation created by something, but not GOD? GOD doesn't have to be a humanoid, but when people talk about simulation theory and an architect while refuting God, it really doesn't make sense. Whatever the architect is or happens to be can be defined as God even if it's something we can't fully comprehend. God= the architect of our simulation that we don't fully understand. That's pretty much the same definition from thousands of years ago. If we aren't in a simulation, then where is the energy/information coming from? It just existed forever... how can we ever fully define consciousness if we don't know its source?

​@@JundArbiterThat can be applied to the totality of the universe. It's all one thing. There is no separation and time is just an illusion. Measurement from A to B.

Perhaps what we think of as "irregular" is an illusion, in that we use it in order to describe something that does not have any patterns that are recognizable to us currently. It could just be that we don't yet understand the patterns, and that even highly chaotic systems are ordered in strange ways.

@@bodeeangus9957 That is certainly a possibility, though in principle we could find a dataset that cannot be produced by any program of length

you're right, it's not just the algorithm but the inputs, which in turn may be expressed more compactly, compression is a good intuitoin for this but the video seems to assume that these programs can have free variables / inputs, but they shouldn't

​@@bodeeangus9957 Kolmogorov complexity goes even deeper than that, look into Chaitin's constant for example, although it can be compared in some sense for actual programs, you can objectively say which is shorter, if i'm not mistaken you can even do that without loss of generality in assuming a particular language, but you can't do it in general and you can't coompute the Kolmogorov complexity of a given string because concrete examples exist in cryptography, for example a pseudorandom generator is an object which without knowledge of the seed appears to have unbounded complexity, but in a very tangible sense only has a constant amount of it

❤ I like your background in social silence 😂. It made me think. People in general make too much noise. We all should listen more to each other, especially listen to Sabine 🧐

Hard to predict for who though? The same problem can be solved in a different amount of steps by different function. If you have the perfect model, maybe predicting different things is equally difficult.

Unless we assume complexity is equal to the probability of outcome after some amount of time, for which we maybe need to quantize time to get finite number of steps. If you can predict a state of system in 100 steps with 100% certainty, you get a complexity factor of 1? Sounds arbitrary but hey

A frozen baby could become not very complex though as system gets predictable, by that definition :p

The only algorithm you need to make a baby are the laws of nature. There is no cut off point. The baby is a result of the same laws as the rock. Also check out Steven Wolfram's work on how equally simple algorithms may give rise to vastly different outcomes, some outcomes are periodical, some are chaotic.

Accept, it does fall short in some cases. The whole concept of complexity is higher-dimensional, it's likely that in a system with infinite configurations there can also be an infinite number of ways to describe them.

Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

Complexity is dual to simplicity. Randomness (entropy) is dual to order (syntropy). Points are dual to lines -- the principle of duality in geometry. Points (nodes, vertices) are dual to lines (links, edges) -- graphs and networks are dual. Convergence (syntropy) is dual to divergence (entropy). Syntropy (prediction) is dual to increasing entropy -- the 4th law of thermodynamics! Syntax is dual to semantics -- languages. If mathematics is a language then mathematics is dual. Real is dual to imaginary -- complex numbers are dual (photons. light or pure energy). The integers are self dual as they are their own conjugates. Subgroups are dual to subfields -- the Galois correspondence. Sine is dual to cosine or dual sine -- the word co means mutual and implies duality. "Always two there are" -- Yoda.

The older ones are worth to watch. Sabine is a great communicater and a deep thinker.

So you wait till the end of a year to do a little thinking. Then only to listen to someone else do the thinking for you.

@@PlanetEarth3141Hi, are you here to communicate? That´s what makes thinking easier indeed sometimes.

Computability is a challenge to tackling Complexity for sure or as Sabine said we would just use the fundamental equations in Physics and be done with it, (*sigh*) but for combinatorial explosion eh? Where we have success in high complexity domains like Biology is where we have good heuristics that sufficiently model the fundamental behaviors we are interested in predicting. The number of NP problems nature tackles every day is quite impressive until you recognize that it's using all of the atoms in the entire universe to do so... an option that is mostly closed to us unless we redefine predict to mean observe. To me one of the essential features of a theory of Complexity needs to account for is the dynamics of a system. If you take a human body and freeze it in time it's not really a complex system anymore, it's just a particle arrangement. A rock that is moving through time has dynamics but they are relatively static (non-complex) on a human time scale. Geology has complexity but only on geologic time scales so clearly the complexity of a system somehow includes a scale factor based on the dynamics of the system and so comparing system complexity must include that variable. I mean on a geological time scale the inanimate and decidedly non-complex inorganic chemistry of the earth somehow evolved into organic chemistry and then life which makes the complexity of rocks pretty interesting. Linguistic challenges are clearly at play here as we continue to overload mathematical concepts with human linguistic baggage.

@John-zz6fz Yeah, it's a huge task and the number of variables is just unreal... Unless we really are in a simulation and can, some how, access the source code. 😬

​​​@@John-zz6fzHow would functions(where certain subsystems emerge which serve a superior "super-system" - known as functional differenciation, as seen like in the brain or society) and evolution(a REAL evolution - like biological life, society, the cosmos as a whole) add to the complexity of a system? Compared to just complex chaotic phenomena like the weather.

@bjornrie The increasing complexity would be to emergent phenomena. In this case the term complexity has dual use. In the computer science frame we mean computational complexity and if the system is calculable in a Turing sense then no new complexity emerges. From the information science frame complexity isn't the same as computational complexity. It's not totally clear what the term actually means in information science and that point is made by Sabine as she's saying we need to make progress on a formal mathematical definition of complexity in the frame of complexity theory.

Nope.

I kind of agree - the only issue is quantifying "amounts" of description. I can describe a pencil with the word "pencil" and a human with "human", so using "number of words" isn't quite enough. Possibly "number of variables" is more in the right direction.

It would appear in terms of complexity that the early universe is in essence the same as the universe today., there must be at least equal unseen complexity in the early universe, since it describes and preforms the future it will become. Unlike DNA, which iterates within an outside medium which provides external elements to make a baby, the early universe is self contained and must have the same complexity at all points in time. The early universe must have unseen internal complexity to produce a baby in 13 billion years , as well as civilization.

the important thing is realizing that this inherent complexity can also be a characteristic of a system through time. We need to consider time and space as equivalent even though we are stuck in one and free in the other ;) something that starts extremely simple can become complex and in a sense then it "already is complex".@@myroomtv2014

Bad humor below: A rock is harder than a baby.

Usually.

@@myroomtv2014 I don't agree that the initial conditions of a system are necessarily complex for the result of the evolution of that system to be complex. The rules themselves breed complexity by their very nature. It seems enough to provide a very low entropy seed and let the rules create the complexity.

Actually life drives entropy at a much faster rate. Simply because of your extreme locality might seem to exhibit lower entropy is a far cry from the wider environment. Look at climate change as a simple example.

@@SebWilkes How is change in climate an example of entropy? Life takes the energy that would otherwise be entropically wasted and concentrates some of it and builds greater complexity and organization. It is the only thing we know of that goes against the prevailing entropy gradient.

@@obsidianjane4413 CO2 in the atmosphere is a higher entropic state than oxidisable carbon in the ground. The amount of additional entropy you generate in creating a building, say, greatly outsizes the entropy you reduce by having a few crushed rocks suspended above you.

@@SebWilkes That isn't "life" that is just humans mucking about. Very tiny percentage compared to the total on that particular thing.

@@obsidianjane4413 I don't think it is limited to just humans, but without a better argument I'll concede on that. Nonethless, it is worth pointing out that since life, or at the very least intelligent life, is so good at increasing entropy it has been argued by proponents of biological determinism as a reason to believe that a system that seeks to maximise entropy (and its rate thereof) would be likely to bring about life.

We will let our robot overlords shoulder that burden.

Every Physicist ever: dy/dx = x" + x' + y + H.O.T., but we can ignore the Higher Order Terms

QM implies its all random anyway, theres also the point that most of the high entropy situations are near indistinguishable from each other and can usefully be approximated to random for that reason

Adjectives, including "high," are ambiguous shorthands that actually refer to a relative comparison to an unstated alternative: "X is high" actually means X is higher than some unstated Y. There are typically many possible alternatives for comparison, which is why failure to explicitly state the unstated alternative creates ambiguity and is often misleading. What your comment is doing is proposing a definition... a particular threshold that distinguishes "high entropy" from "non-high entropy." That's fine, but different thresholds could be proposed. For example: Entropy is "high" when entropy has grown to the point when a complex system can never afterward exist. I think this definition of high entropy would be more consistent with Sabine's point that complex systems are neither low entropy nor high entropy.

@@festusmaximus4111 Isn't QM all about finding patterns in all this "randomness", that could also be close to the highest possible complexity when you assume particles interact with every other particle in the universe?