"Gabriel must have an incredibly small mouth if he's blowing in the small end". End?

Yo, making an approximation of this horn and filling it up then measuring the volume would be a great new addition to Matt's weird ways of calculating π

“It’s always nice when π appears out of nowhere” Starts pushing squares against each other on a frictionless surface.

It’s amazing how intuitive his explanation of the volume of a solid of revolution is.

I think the real key to the paradox is that these are different units. Any finite amount of volume can theoretically spread into an infinite area if you can spread it infinitely thin, so you CAN paint the horn (e.g. the inside, by filling it) with a finite amount of paint.

:: Slaps horn :: "This baby can hold π paint"

The animations on this channel just keep getting better.

Thank you for bringing our attention to this bug. Our team is working on it and we hope to have it patched in the next update.

"It's always nice when π appears out of nowhere" *sad revolution noises*

That man has the disheveled nature and wild look in his eyes of someone who has looked into infinite and saw it staring back.

Interestingly, the word “frustum” is taken directly from the Latin which means “crumb, or morsel” so comparing it to a pizza crust was more accurate than he ever imagined!

These were extraordinarily intelligent questions asked. "If you fill the horn with paint, haven't you painted it too?" Excellent point.

"Welcome to Sherwin-Williams. How much paint do you want?" "Pi."

"You can't argue with the maths." Well. I CAN argue with the maths. I'll lose. They kicked me out of the math club a long time ago and told me never to return.

"Conical Frustum" sounds like an uncomfortable urological condition.

Absolutely loved it where you skipped the pain and substituted for “bigger than 1” just to get to the proof. Something I didn’t really encounter in maths at school. Mind blown in lots of ways on this video

I am a Mechanical Engineering drop-out of 17 years, and I literally followed every single step of this. Thank you, Mr. Walton, Mr. Roy and whoever my calculus professor was in college.

7:12 "Can't fit any more. Can't fit any less" ...you definitely could fit less though!

"Gabriel's horn has a finite volume" Never have I so violently disagreed with such a logically sound and well explained argument/claim.

I think you could paint the outside by placing the horn into a horn made by revikving 2/x and filling the larger horn which itself has finite volume

Anyone else wondering why he didn't just use cylinders again for the surface area?

Mathematician: Rotate. Pi: It's Free Real Estate.

A nice way to think about this (and resolve the paradox), is that we are basically thinking about 2 different types of paint as if they are the same. When you fill the horn you are thinking of 3-dimensional paint particles, but when you are painting the horn's surface you are only thinking of 2-dimensional paint plates. If we would try to fill the horn with 2D paint, we would never finish. In fact, we wouldn't even be able to fill a tiny bit of it, because our 2D paint plates have height zero. This matches our intuition that something that fills out a volume must be more than something that only covers the surface. Contrary, if we would try to paint the surface of the horn (let's say the outside) with the 3D paint, we are making it unintentionally thicker everywhere as well (presumably by a constant epsilon > 0). If a covered surface is epsilon > 0 thicker than before, then the thickness of the horn doesn't converge to zero like explained at the beginning of the video, but converges to a constant > 0. Now, of course the paint we would need to cover the surface is still infinite, but the paint we would need to fill the entirety of the horn including the epsilon-thick surface is also infinite.

as a chemist i was assuming the volume would be dependent on the size of a molecule of paint haha. great video i love your channel

how 2 paint the horn: fill the inside with paint dump the paint out, this will result in a coating of paint inside the horn. turn the horn inside out refill the horn with paint and dump it out again

"If you are bigger than infinity, you are infinity." -Dr. Tom Crawford

I love Tom's enthusiasm and he's great at explaining things. Very nice!

for those who can not wrap their head around this - imagine a pancake. The thinner you make it the bigger pane you need. As the thickness will approach 0, the area covered by the pancake will approach infinity. However, the volume is still the same.

I feel like part of the reason that this is confusing is that it implies that it is reasonable to compare sizes of different dimensions. In some sense, any 3-dimensional size larger than zero is larger than any 2-dimensional size, even infinite. A single drop of paint that has no limit to how thinly it can be spread can cover an entire plain.

I've used this a few times as an Oxford Maths admissions interview question, but I guess I can't anymore now you all know the answer... :p

“The surface area of a conical frustum is just AB” No talk to me I angy

I like how the paradox is making people assume you cannot paint an infinite surface. Yes, you can, just have to make the pain infinitely thin

I’m learning from Numberphile! I was like “one series will converge, but the other will diverge”. All thanks to Numberphile and other similarly awesome channels.

"... we will need to do an integral." Ok. That's my stop. Have a nice weekend!

I adore how excited he is about this problem. Absolutely captivating!

It occurred to me that painting - in mathematical terms - involves a layer of paint that is infinitely thin. This would cancel out the infinitely large surface area if we were using even a very small amount of volume of paint. In other words, even the tiniest volume of paint can paint even the largest area - if the thickness of the paint is zero.

so this is the 3D version of the “mathematicians walk into a bar” joke, where the bartender just serves them 2 pints

I was thinking about Brady’s question about being able to fill up the volume with a finite amount of paint but needing an infinite number of paint for the surface. I think the idea is this: in ANY finite amount of VOLUME of paint, we can cover an infinite surface area. If you put your finite volume of paint in a can, there are an infinite number of cross sections we can take of the can of paint, so we can cover an infinite surface area.

So, someone like Matt Parker could, for instance, construct a long enough Gabriels horn, in order to fill it all the way up such that he gets an approximation for Pi? 🤔

I think you could actually paint the horn. The paradox comes from assuming that a finite volume of paint can't cover an infinite area but the horn proves that you can't assume that. Simply fill the horn with paint, freeze it, and take it back out of the horn. The paint is now a solid copy of the horn and thus has finite volume but infinite surface area, therefor a finite volume of paint can have and cover an infinite area.

But.. By filling the horn, the paint literally touches the horn.. aAaAA infinity melts my brain every time

I think I can resolve the paradox. When we normally talk about "painting" a surface, we choose a thickness of paint, say 1 millionth of a meter. Then the amount of painted needed to paint the surface would be the surface area times the thickness. If the surface area is infinite, that's an infinite amount of paint, no matter how thin the layer of paint is. Does that mean you can't paint the surface? No, not really. You can instead use a variable thickness of paint. Suppose you paint the region from x=1 to x=2 to a thickness of 1 micrometer. Then the region from x=2 to x=3 to a thickness of 0.5 micrometers, and the region from x=3 to x=4 to a thickness of 0.25 micrometers, etc. The region from x=n to x=n+1 is given a thickness of 1/n micrometers. Then this only requires a finite amount of paint. That's what's happening when you fill Gabriel's horn with paint. You're painting the inside of the horn, but the thickness of paint gets less and less as you go.

Really appreciated the walkthrough of the calculus, I always enjoy explanations of calculus that really focus on logical thought and physical characteristics and don't just go "this is the answer"

A non-paradoxical paradox: the reason there seems to be a paradox here is because of an unstated (and absurd) assumption, that the thickness of the paint is uniform throughout the length of the trumpet! If the paint thickness tapers off as 1/x, adding another 1/x term to the integral, the volume of surface paint will be finite. This is exactly why the interior surface is coated with a finite volume of paint: that paint must taper off at least as fast as 1/x to fit inside the trumpet.. I didn’t read all 3,904 comments to see if anyone else mentioned this and apologize if they did. And I find it disappointing that the author of the post didn’t realize this. It is not at all unique to have a finite volume(surface) enclosed with an infinite surface(boundary), e.g., the Mandelbrot set is a finite surface area but its boundary is (hideously) infinitely long.

We gotta give props to Brady for asking such a wonderful question, 16:04.

I'm guessing he doesn't have a tattoo of Gabriel's Horn because it'd take infinite ink?

It's a trick. The thickness of the coating of paint we're applying is zero, which is why it doesn't "use up" any volume of paint at all!

I remember learning of this in calc 2, and I was fascinated. This recaptured that exact feeling for me

This is exactly what we want. *The real maths*

Finite volume, but infinite horniness 😳😩

CORRECTION: At 8:55, Area of "Net of Conical Frustum" = A*B, but "A"arc should be taken at mid section of Frustum and not at the uppermost portion as shown in the video.

Regardless of how many angels can dance on the head of the pin, the music they're dancing to is definitely played by an angel blowing on the infinitesimally small end of an infinitely long trumpet

Loving the vibe of this guy. Pokemon tats, bright eyed when talking math, and lip piercing is rarely seen in the same person.

Why cannot the area of a slice be 2*pi*(1/x)*dx ?

One really cool detail about this: Early on, the voice behind the camera points out that the volume of the horn appears infinite because you can always keep adding a little bit more at the end, infinitely, which is technically true. So the fact that the answer resolves to Pi, a number that famously has an infinite number of digits, really fits this perfectly. You can always keep adding smaller and smaller amounts at the end, and yet it is a finite constant. The volume is finite, but indefinite.

It's a bit like the infinite number of mathematicians walks into a bar joke. The bartender would need an infinite number of glasses but just two pints of beer to serve all of them.

This is an awesome production - very clean and extremely well explained by Mr. Crawford. The derivation of dS I would never come up with on my own. It's elegant to see the various tools of mathematics applied to a problem like this. The animations on this channel are strictly top drawer.

Next video: Gabriel's wedding cake, the discrete version of Gabriel's horn

The Gabriel's horn in the ear was a classy touch, well played

Assuming the horn is of negligible thickness, this claim asserts that the finite volume of paint that fills the horn will not coat the horn. However, if the horn is of infinitesimal thickness, the surface area of the inside and the outside are the same. Since the inside is holding the finite volume of paint, that volume of paint is touching the entire surface area. CLEARLY that volume of paint can also completely cover the surface of the horn.

I guess this is similar to cutting a square in half infinitely, with the formula 1/(2^n). The total area is 1, but you can always add total perimeter length when you cut the next square in half.

Explanation of the paradox for anyone who is curious: The paradox is the result of using two seperate models for how it is treating the paint in the two different scenarios. In the "Fill" scenario we treat the paint as a pure mathematical volume; which can be compressed and shrunken infinitely. This is not how paint actually exists in the real world. Which is to say, in the real world paint is made up of a finite number of paint particles with their own, immutable volume. However, in the "Paint the surface" scenario he switces from treating the paint as the mathematical idea of volume to treating it like actual paint, which can only be spread over a finite area because it is made up of a finite number of paint particles, and once they run out, you are out of paint. So now we can choose between two different paint models: If we treat paint as it actually is (as a finite collection of particles with finite, immutable volume) then you can neither paint the surface area nor can you completely fill the horn. You cannot paint the surface because you will eventually run out of particles, and you cannot fill the horn completely because eventually the horn will be too thin for the paint particles to fit. However, if we stick to the "Fill" example's model and treat paint like a pure mathematical volume. Then you can easily both fill the inside and also paint the surface area. In fact, when treating paint like this, *Any* amount of "paint" would be sufficient to paint the surface, both inside and out trivially. This is because you can (as demonstrated in his explanation) morph the "paint" into a shape wherein it maintains it's volume, but has infinite surface area and is wrapped around the horn. Interestingly enough, while treating paint consistently in this manner, you could not both fill the horn completely And paint the outside if you only had π units of paint. However if you had any amount of paint more, say π+0.0000000000000001 units of paint, you could both fill the horn completely and paint the outside completely as well.

Instead of getting stick bugged in math the equivalent is getting Pi'd where Pi just pops out of nowhere lol

I feel like this, much like the perimeter of a fractal, can be painted. You would need to cover an infinite surface area in this case, but that's entirely possible. You would have to dump the entire horn in paint and the outside would be painted. If you made another infinite horn say, twice as large at every point so your horn fits inside it, you could fill it with paint while your horn is there (wouldn't take much paint) and your horn would be painted. This reminded me of like an infinitely long, higher dimensional fractal. You can easily have a fractal with an infinite perimeter and very finite area, and you could easily surround the whole thing with paint to paint the edges.

the inside and outside surface areas are the same so just fill it and then invert it to fully paint the outside.

"Technically this is a derivative, I kinda treated them as fractions, it's fine for now" Is this physics or what?

Learning Calc 3 right now. Crazy that I know what he is talking about. A year ago I would have had no idea.

The solution of the paradox is simply that there are pi volumetric units, but infinite surface units. However, since there are infinite surfaces in a volume, you can "paint" infinite surfaces with any finite volume of paint.

For anybody bothered by the lack of intuition in the result, maybe this will help. What we have here is a finite volume contained within an infinite surface area. Consider the fractal coastline problem, wherein the coast length of a piece of land increases towards infinity as you account for smaller and smaller bumps, but the area of the land contained within the coastline stays approximately the same. This is an analogous situation where we have a finite area contained within a boarder of infinite length. Just increase everything by one dimension to get back to Gabriel's horn. If you were comfortable with the fractal coastline problem, now maybe you're comfortable with Gabriel's horn. If you aren't comfortable with the fractal coastline, then I've just doubled your anxieties; you're welcome.

"Some other big horns" in the middle of this mathy explanation nearly slayed me

Surface area and volume is two different units, it's like comparing apples to oranges. To know if we have enough paint to cover the area we need to state the amount of paint as an area. Thus if the area of the horn is infinite m2 then we need to get the, for arguments sake, pi m3 volume to a surface area. How do we do this? Let's spread the paint out onto a surface, to get the volume to become a surface we need to devide by the thickness of the paint on the surface that we are covering. Since this is a purely mathematical construct and we are not dealing with phisics we can say that the thickness will tend towards 0. Thus lim x->0 (pi/x) and since the thickness will always be positive we can say that the area that the paint can cover tends towards infinity.

I initially learned about Gabriel's horn from a book I'm reading called "The Math Book" and came to this video to learn more about it. I watched this video twice now and just noticed the book I'm reading is on the top shelf in the video! Great explanation by the way!

Dude liked Gabriel's Horn so much he got earings like em

Holy cow. Good job on the animations!

It's always nice when pie appears out of nowhere, except when it's being thrown at your face.

I'm a student of topography, I'm gonna be very simple, you are basically just stretching a solid with finite volume infinitely, so no matter how long it becomes it's always gonna have that finite volume, and for Gabriel's horn that's why it's width becomes infinitesimally small in order to compensate for that finite volume the shape got. Same goes for 2d shapes.

This guy teaches surface area and volume of revolution in 20 minutes better than my professor does in 2 weeks.

12:20 The cold rage of a thousand hells is entering my heart

I think it makes sense somehow. In fact, with real world paint, made out of atoms of finite size, it would not be possible to fill the horn either. At some point, as x gets bigger and the diameter shrinks, it would get stuck (and probably before that because of surface tension anyway). That's the same reason why it would be impossible to paint the outside area: a finite volume of paint cannot be infinitely spread as particles cannot be spread. However, if one considers a mathematically ideal paint, made out of infinitely small particles, then the horn could be both filled and painted with it !

I’ve thought of a second paradox that arises when you try to fill the horn with paint. Assume we are in a frictionless, surface tension-less, atmosphere-less etc., etc. world but gravity is the same as earth’s. You start pouring the paint and the first bit is continually accelerating down the horn. However, because the horn is infinitely long, it will never reach the bottom in a finite amount of time. That will mean there is always space to be filled further down the horn, so you actually cannot empty your pi units of paint from its can. But, since the first paint poured will always be accelerating, it can’t “get in the way” of the paint you continue to pour. So you should be able to empty the can. But, of course that would mean there is still unfilled space inside the horn. Which would mean, actually you can’t empty the can and so on.

If Gabriel's horn is infinitely long, it can't be played, because there would be no end for the mouthpiece to be at.

*"The human brain is the most complex structure in the whole entire universe"* _-Human Brain._

"Horn is completely full of paint. We need more paint."

The trouble comes when thinking of the paint as a surface. It isn't, but it's tempting to think of it that way as if it's equivalent to the surface area. But the paint has some volume, even if we make it infinitely thin, otherwise we couldn't fill the horn. Think of the paint being between your original horn and a slightly larger horn, and the paint is filling the gap between the two horns. We know the paint can't have infinite volume, or it wouldn't fit in the horn. Note that making the outer horn a little bigger does not make its volume infinite. We can make the outer horn as big or as small as we want as long as it's less than infinity, so the paint can be as thick or thin as we want it. But as long as the paint is between the gap between the two horns, it must be a finite amount, since it takes up finite volume. If we took off the horn when the paint is dry, it would be clear we still don't have an infinite amount of paint. And yes, the paint would still have infinite surface area, but still finite volume, just like the horn.

Original fact: "crust," as in pizza, actually comes from *C* [onical f] *RUST* [um].

This is not a paradox; any finite amount of volume of paint can be painted on an infinite surface, as long the thickness of the paint is infinitely thin....

Me, a human that lives in the physical world: Well, yeah, surface tension would eventually prevent you from adding any more paint...

The longer the horn gets, the higher its volume is, and the higher its surface area is. The paradox only arises if you conceive of a limit as being the actual measure of something. If you state it as "as the horn gets longer, the relative increase in its surface area diminishes at a slower rate than the relative increase in its volume, because surface area increases with r and volume increases with r squared," then it doesn't seem paradoxical at all.

"1 over infinity, that's 0" Now wait just a darn minute.

The area for the side of the conical frustum is incorrect!! The "A" should be the length of the arc measured in the middle of the frustum, kind of like its midriff.

Mentions of events from 2010 are now classified as 'Old-school references' :*(

I’ve been geeking out over Gabriel’s Horn for almost twenty years. This video made me very happy

Quite clearly, you just reduce the thickness of the coat as you go towards the end of the trumpet.

I remember once feeling like it made sense that you could fill it but couldn’t paint the outside, but now I can’t see how I felt that. It really is a paradox.

The cross section of your surface is everywhere a circle. "It's always nice when pi appears out of nowhere"

Never seen a mathematician with such cool hairstyle please don't get me wrong

As an engineer, I thought treating the infinitesimals as fractions WAS rigourous math 😔

I like the paradox, thank you. Also, your enthusiasm is contagious 🙂 Using a cylinder for the surface calculation is much faster, but the detour via this weird shape, the name of which I can't even remember, was interesting too. Thanks so much!

Kinda convenient that I'm taking a calc 2 exam over this same stuff tomorrow. Thanks for the vid

I didn't expect to learn the basics of integrals when I clicked this video. No regrets.