Steve mould, i think I found your long lost twin sibling!! His name is "david castello-lopes", and he is a french journalist/comedian/youtuber. The resemblance is very much striking

for a clear resin 3d print, like optically clear, you can polish it to 800 grit, then use a clear glossy spray paint. It'll make it optically clear. i've made lenses out of SLA 3d prints

8:54 this surface isn't polished, it's ground very smooth.

@@adri1572 Steve is cuter.

Please make and sell the small 3D Gilbert curve resign cube!!

"and you can quote me on that." - Steve mould

glad this was appreciated

Never went to a nightclub in small town then.

@@gorgenfol You should take this down. It was "you can quote me on that", not "you can quote me on this". But then I'm making the same faux pas.

its nubbles lol

These are used on boats if anyone is curious on specific use cases

cool

This proves that maths is applied philosophy

@@mamoopy Wow, I never knew they used sacrificial mathematicians on boats. This explains what happens to most graduates, thank you

Turns out "Matt" was short for "Magnesium galvanic anode" all along 😌

If you haven't already seen it, 3Blue1Brown has an excellent explainer on the topic (though it is far longer than a minute).

Dimension is essentially a scaling factor, with higher dimensional things scaling more from the same change in length as lower things (like how doubling the radius of a ball will have more of an impact on its weight than its surface area). Things with fractional dimension are just things that scale at a rate between the rate of the integer dimensions. For example, the area of a Sierpinski triangle scaled up by two does something in between doubling (like it would if it was a line segment) and quadrupling (like it would if it were a full triangle). That's how it made sense to me when I was explained it, so in case it makes sense to you, here you go. It also I think prepares you very well to see the math behind it, where a formula for scaling in terms of dimension is then solved for dimension and used as a definition extension.

This was a good video but he didn't actually explain fractal dimension, he just gave a couple examples

damn, were you actively researching it for five years or something? lmao

@@ludvig3242 no. I heard about fractal dimensions for the first time 5 years ago, didn't understand it. For the longest time, when I watched science videos and the topic came up I didn't understand it. Only finally got it when I saw Steve Mould explain it 6 months ago in this video, right before I made that comment.

Seeing the “water runs”… plus the marble run earlier… makes me think of a crossover that I didn’t know I wanted… who’s the guy that does the marble races? Jelly’s or something? It’s been a minute…

Just looked it up. Jelle’s! I was close-ish. :)

@@DavidLindes Wintergaten makes those crazy marble machine musical instruments.

asmr community gonna have a new toy to play with

​@@DavidLindes🎉🎉🎉🎉🎉🎉🎉🎉

Do I detect a nerd sniping? Can't wait for the video!

You could use braces, there are enough parallel parts that can be linked to spo them from wobbling away. It takes a bit away from the concept bit not too much.

Count me in.

@@standupmaths ba dum tss...

would use a very thin exit nozzle, to make sure the water is well pressured, and fills everything as it goes through. 🤔

Thank you, I was actually here to make the same point. The issue is that people's intuitive idea of a fractal (self-similarity) and the definition in terms of the Hausdorff dimension (which in the case of space filling curves should agree with Minkowski dimension) aren't the same.

the issue is that there is no sequence of finer and finer labyrinths that have a limit. the path the next iteration takes is wildly different, in the hilbert curve, the 20th iteration is very similar to the 19th, in that the point that is, say, 1/pi along the curve barely moved (and same for all other numbers 0 to 1)

"definitionally fractal because it's Minkowski dimension exceeds its topological dimension" - what is this supposed to mean to us ordinary plebs who don't talk math?

​@@terdragontra8900 Is the limit of the space filling curve {lim n->∞ (x_n(t), y_n(t))} the set of limits of points on the curve, which is literally the whole area? Or is it {(x,y)|∃N∀n>N, (x,y) ∈ {x_n(t), y_n(t)}} (so just the 1/2^n points)? Or is it the closure of the second thing, which would also be the whole area?

@@ArawnOfAnnwn Minkowski dimension is fairly straightforward in idea: en.wikipedia.org/wiki/Minkowski%E2%80%93Bouligand_dimension The other is isn't so straightforward but in the case of curves like these think, if you zoomed in close enough what dimension would it look like. This is not what it is, it's about refinements of covering sets or some nonsense like that. But the shapes in the video are well behaved so you can think of it like that Here's the idea: en.wikipedia.org/wiki/Lebesgue_covering_dimension

I think this is also similar to the way pythons and boas rest.

Same here! 😊

Yes! Please! I got to know!

Green coolant and orange coolant in your radiator.

The business man

should use oil and water so they don't mix.

You could probably print them without inlets and outlets, and then drill as necessary to glue together bigger cubes. Might get time consuming (64 cubies to do it twice, 512 for 3, etc.), and it would possibly stop working after a while.

Potentially... Unlike the sides of a Koch Snowflake, where each iteration is made out of exact copies of the previous generation, the Hilbert curve (and the generalized 3D versions) are copies of the original *plus* extra lines to connect those copies. Those connectors don't always connect at the same angle (sometimes at a right angle on both sides, sometimes only on one), so you'd have to include paths for all possible connectors and then somehow plug the ones you aren't using

It seems like by definition that should work

@@zlacthe problem with drilling and glueing is that you create branches and shortcuts

Oh nice idea!

Aint no way Brah!!!

Interestingly, there are continuous functions from the curve to [0,1], although mutliple values on the curve will get mapped to the same point on [0,1]. Since it isn't injective, it is jective!

Are we going to simply ignore the fact that Steve already said what the word "fractal" means, and it is not what you are saying? If you think your words are more correct, you're going to need a reference.

@@u1zha😂 he’s exactly correct and it would take you a few seconds to learn for yourself.

@@u1zhathe fact that you need someone to reference a fact that disagrees with something you learned from KZbin is hilarious.

@@u1zhastart with a guy named Mandelbrot and go from there.

@@u1zha The Onion Curve is a good example of a non-fractal space-filling curve. See "Onion Curve: A Space Filling Curve with Near-Optimal Clustering" (2018) by Xu, Nguyen, and Tirthapura.

Very interesting, this is shown in the multiple videos, there is a gradual decrease in pressure from start to finish. If it was infinitely long, there has to be infinite pressure at the start too. So your ending statement of "no matter how much pressure you can exert" is just plainly wrong. the pressure can be represented as a integral of length of the line.

@@acters124 The problem is that no amount of force can accelerate the water beyond the speed of light. The water would have to travel along the path which is infinitely long, so it could never reach the end (or anywhere else in the cube for that matter) in a finite amount of time.

To have an infinite line you would need a tube with no width unfortunately all liquide I know ha e a minimum width for exemple I doubt water could get thinner than an h2o molecule. Therefor none 0 with tube means finite tube means finite time to fill

@@glorrin You are correct that this scenario could not happen in the real world, but original post was about the limit case, a true space filling curve with no thickness. It doesn't really make physical sense, but it's interesting to think about.

Water wouldnt fit on the cavities

you missed what Matt Parker was saying. While it is true that the approach used to demonstrate fractals as space filling will not work on the Celtic labrynth, there is no way of knowing at this time if it is space filling or if it is not. This is because the absence of a method of proof does not itself constitute a valid disproof.

​@@Thesupremeone34you misunderstood the comment. It's not that the curve is not a fractal, which we already knew about, and that's what Matt Parker said, it is in fact that the limit of the curves doesn't exist, so you cannot even ask the question in the first place, there's no infinite labyrinth to check if it fills space in any known or unknown way because the infinite labyrinth is not well defined

@@Thesupremeone34no. what matt said was wrong. the labyrinth curve is an infinite family of curves with increasingly more parallel lines, which does not converge to a well defined curve. every space filling curve needs to be a fractal

Can you prove that the Celtic labyrinth doesn't converge? In my mind I can see it converging so I don't agree with your whole premise.

@@toniokettner4821 what Matt said wasn't strictly wrong, he just didn't stop enough to notice the answer was a definite no because of convergence reasons, so he just erred in the side of caution and said "you cannot prove it with known methods", which is technically true, the best kind of true

Very astute observation

@@AndieZ4U2 Thanks

Essentially the same technique is sometimes used in distributed particle simulations to map nearby particles to the same compute node. So many applications!

I work with epoxies. Just spray it with clear lacquer of pretty much any type.

Karnough maps as well. Traversing a truth table with only a single bit or state changing each turn.

Until, IPV6...

Fancy seeing you on here as I'm catching up on some YT I've missed due to life! :D

Your comment caused me to review a few papers. Looks like it's useful for very memory bound GPU tasks (without accounting for encoding time). Row major is still fastest on problems below cache size and on the CPU. Hilbert curves were consistently slower than Morton curves, *the effects were quite dependant on the architecture*. The advantage goes away when interdependence is added, then it spends too much time computing Morton indices instead of crunching the numbers.

But non-fractal space filling curves don't exist though, in fact the inclusiveness goes the other way around. Fractal dimensions can go non-integer and cover go from 1D to 1.5D to 2D and even 3D and everything inbetween, actually most fractals aren't space-filling. But being a fractal is a requirement to be space-filling, no smooth curves can fill up the space, and the Celtic labyrinth doesn't count as it doesn't have a limit that respects the definition of a limit. I recommend you 3Blue1Brown's video about fractal dimensions and self-similar fractals on the matter, it does explain exactly how fractal maths generalise to non fractal shapes and how it affects their dimensions. And also his video about the Hilbert curve that is linked in this video's description as it explains why the Hilbert curve does respect the definition of a limit.

​@@jAujAl1 I partially disagree. A logarithmic fractal is a pseudo-fractal, because it's fractal at the central point but not at any other point. when Parker said "your problem is that the 'Mould curve' is not defined by a recursive substitution approach" he's actually mostly right but partially wrong. In actuality, the Mould curve is defined by a recursive substitution approach around the origin, and a simple algorithm everywhere else. It's fundamentally halvable just like a Hilbert Curve is, at the origin, but the results of halving are less than the results of the Hilbert Curve because it's only halving at one point rather than every relevant point. meaning that it has a definable fractal dimension at the origin, and a relative fractal dimension everywhere else. This means that it sits between a pure fractal and a non-fractal. So I would instead say that a pseudo-fractal can be pseud-space-filling. It's not that it can't fill a space, but instead that it doesn't inherently fill a space. It only fills the space it's defined to fill, and it would require extra effort to make it fill a space it's not defined to fill. A true space-filling fractal can fill any space, but I realized from this video that a pseudo-space-filling fractal can only fill the space it's defined as filling. And unfortunately, fractal shapes generalizing to non-fractal shapes doesn't solve my problem. I need true in-betweens. Things that are neither fractal nor non-fractal. Logarithmic spirals and the Mould Curve are appropriate examples. Still, I'll look into that 3Blue1Brown video. I've watched most of his, and I might have missed that one. Thanks for the recommendation.

@@jAujAl1 If you're talking about kzbin.info/www/bejne/nXOcn2Wdfdh7hJY, it doesn't describe a generalization of a fractal to a no-fractal at all. It only describes fractal dimension as a secondary characteristic. It describes a good generalization of fractal dimension. But in only in the same way that a number line describes a good generalization of integers and non-integers. In other words, it's completely useless for what I need. I don't need a simple number line, I need a definitional difference between integers, irrational numbers, and transcendental numbers as it relates to the definition of a fractal. Fundamentally, an Archimedes spiral is space-filling for a circle, but not any other shape. The impossible problem I'm trying to solve is inventing a math that includes Hilbert curves, Archimedes spirals, and squares, as computable shapes. in the same way a number line includes transcendental numbers, irrational numbers, and integers.

@@epigeios Yeah, that's the one I was talking about. Fat chance, it sounded awfully close to my understanding of your problem, and my bad, I remembered it as generalizing the definition for non-fractal, sorry for the mixup. I would argue the "Mould curve" has a pretty imprecise definition of how it is defined at the center, but if you interpret it as an infinitely nested U shape with a sharp turn, it could indeed count as a single-point fractal and be space-filling at the top half of the center point (or around the full center point if you mirror it). I don't think it would count as a non-fractal though, so I think making those properties generalize to actual non-fractals would still be an impossible endeavour, but I hope that won't be a limiting factor for your computational model.

@@jAujAl1 You're right about that, it's not really non-fractal in that way. And the "Mould Curve" isn't exactly what I'm looking for. It's just a step in the right direction. It's in the direction of mixing and matching fractal parts with non-fractal parts to create something different.

And if the load takes longer. The loading screen just zooms in the fractal because its infinite

How so?

@@JebFromWarmDays Inverse the morton transform from 2D/3D to 1D so spatially close values also tend to be closer in linear address space.

you could likely do it if you had two fluids of different densities, say oil and colored water. then have it drain into a bucket, and alternate between pumping from the top and bottom of the bucket.

The water would carry them to the exit tho.

The back rooms: Hilbert edition.

As mazes go, it's a real easy one! 😎 Assuming you are able bodied enough to climb up/down ladders just move forward there are no branches.

Branching structures such as tree roots and lungs, both optimized for surface area exchange, also nehprites in the kidneys

Space-filling curves aren't actually very good for a heat exchanger. It's true that they offer enormous surface area, but they also make it very difficult to push the fluids through, and there will always be spots where different-temperature parts meet (because a space-filling curve can't be injective). Tree structures don't have this problem, but they're not optimal either because you waste half the space in the branches before you actually get to where the heat exchanging happens. The best design for a heat exchanger is a _gyroid_ instead.

skill issue😊

Only reason I'm here. Need resolution

Interesting! Thank you. Why doesn't the limit exist for the back and forth? I'm guessing it's because of some subtlety about limits that I don't know about.

​@@SteveMould It's related to the locality property you mentioned. In order for the limit to be a curve, it needs to be a well defined function from a line segment to the plane, so the mapping of each individual point needs to be well defined, and the function needs to be continuous. You can show that where the points are mapped to jiggles around without ever settling down.

You have to think of it as a parametrised curve - I.e. as if it is filling up with water. For t between 0 and 1, there is a point on each approximating curve for the position at time t. For the Hilbert and Gosper curves, these become better and better approximations to the point on the ‘real’ fractal curve, and that means you define the fractal by saying at time t, the point is the limit of the points on the approximating curves. A pointwise limit of a function, technically. For the non-fractal construction, the points at time t do not converge, so it is not possible to define the limit, so there is no limiting curve to speak of. So the trouble is that for some t, the points at time t don’t settle down as you go through the sequence of curves. They jump around too much.

​@@SteveMould I think it's kind of important to also emphasize that this situation is in no way at the edge of what mathematicians can handle it's a very standard type of example for learning about limits of functions

​​@@SteveMouldmagine you're snaking from curve top to bottom, increasing the number of folds each iteration; the X coordinate of a point at an irrational distance along the line (say 1/π) will constantly be changing as you keep iterating and never settle down and approach a fixed point. It's analogous to an infinite series that oscillates instead of converges. Rational distances will also oscillate and not converhe but will do so in a repeating way, like the point halfway along the line will oscillate between x coordinate of 0->1/2->1-1/2->0->...