See part 2 at kzbin.info/www/bejne/ombKhqV6nJVkmbM

They clearly knew what they were doing with that title

My thought is that this is equivalent to the problem: "Given three points on a line, if you pick one at random, what is the probability that you pick the middle one." And of course, the answer is 1/3.

at 1:30 in I'm going to say the chance is 1/3 since this situation is analogous to picking three points on the cake, then picking one of the three points to be the cut and letting the other two be the candles. For every possible triplet of points each piece has a candle exactly when the middle point is chosen as the cut. There is a 1/3 chance of the middle point being picked, hence the answer is 1/3.

I enjoy when Ben shows up on the channel. While the problems he brings are clever, I at least feel like I can wrap my dumb brain around them.

Imagine if you also needed a letter for the cake. It would also be c. So then you'd be talking about 2 candles, 1 kut and 1 qake.

I immediately went to my trusted integrals, and calculated 2 times the integral from 0 to 1 of x*(1-x) dx; so the chance of any candle being to the left of the cut, multiplied by the chance of any candle being to the right of the cut, this for every cut, and multiplied by 2 because it doesn't matter which candle is to the left of the cut, and which is to the right of the cut. This yielded 1/3 as the probability.

Ben Sparks is rapidly becoming one of my favourite numberphile presenters. He has this very gentle "older brother" vibe and presents things in a way that gets me thinking on deeper levels. Great video!

12:26 "And now you're going to record a thousand shots of me randomly cutting a cake" Not gonna lie, was half expecting this to suddenly cut to Matt Parker there...

"Being able to draw in 3D is a surprisingly useful skill for a mathematician." - Ben Sparks

I believe this also proves that the distance between the two candles averages to 1/3rd of the cake length.

I really enjoy Ben's manner, humor, topics and explanations.

When he got to the bit where he was asking whether we had to be able to distinguish one candle from the other or if their identical, I’m reminded of the old physics problems where everything is a sphere of uniform density.

I enjoy all the Numberphile videos, but I especially enjoy them when Ben is on. The interaction between him and Brody is infectious.

Another way I was thinking about this, was: With 2 candles, they will segment the cake into 3 separate regions that add up to the total cake. As it's all random, there is no reason to think any region is going to be larger or smaller than any other, so there's no reason to expect the cut to have anything but an equal chance to hit each of the three regions, specifically the region between the two candles, or a 1/3 chance.

Not only is he a great mathematician but also a fascinating conversationalist

I was confused for a while. 1/3 of the way into a Ben Sparks video and no Geogebra. But eventually it delivered.

Another way to think of the intuition for the "ordering" method is to imagine that instead of two candles and a cut, it's two blue candles and one red candle. Then we'll take out the red candle and cut wherever it landed. Hence, we're really just asking what the chance is that the red candle is the middle one of the three. If we place all three randomly, each candle has a 1/3 chance of being in the middle, so our answer is 1/3. Much more intuitive than the first way I did it, as an integral from 0 to 1 of 2k(1-k) dk... though that also gets the right answer.

Here's my method: Suppose the cut is at point X ∈ [0, 1] The probability that a candle is to the left is X. The probability that a candle is to the right is 1 - X. This means that the probability that they are on different sides is: X * (1 - X) + (1 - X) * X which is equal to: 2 * X - 2 * X² Now we are going to divide the [0, 1] interval in segments of length ΔX, and average over each possibility, we get: Σ (2 * X - 2 * X²) * ΔX summing over X going from 0 to 1 by steps of length ΔX. Now we take the limit when ΔX goes to 0, the sum becomes an integral: ∫ (2 * X - 2 * X²) dX from 0 to 1, which is equal to: [ X² - 2/3 * X³ ] evaluated between 0 and 1: ( 1² - 2/3 * 1³ ) - ( 0² - 2/3 * 0³ ) = 1/3 - 0 = 1/3

my thought is the probability of the cut being between the two candles, since the length of the cake is one, is the same as the average distance between the candles. if that's the case then we also know the average distance of two random points on a line through probability

Here's some Python code to simulate the experiment: import numpy as np # assume a cake of length 1 candle1 = np.random.random(size=100_000) candle2 = np.random.random(size=100_000) cut = np.random.random(size=100_000) cond1 = (candle1 < cut) & (cut < candle2) # the odering is: candle1 then cut then candle2 cond2 = (candle2 < cut) & (cut < candle1) # the odering is: candle2 then cut then candle1 cond = cond1 | cond2 # if any of these conditions satisfy, then we have a candle on each piece res = np.sum(cond) / 100_000 print(res) # should be around 0.33 => 1/3 is the answer.

My initial thought was 1/3, and this was my thinking: The two candles divide the cake into 3 segments of random length (the segment to the left of the leftmost candle, the one to the right of the rightmost candle, and the segment between the two candles). The cut will come in randomly on one of those 3 segments. it seems reasonable to assume that, on average, each of those segments would be of equal value. Or put another way, there seems to be no reason to assume that any one of those segments would be bigger nor smaller than any other, on average. Since only one of those segments, the one between the two candles, would satisfy the problem, that gives a result of 1/3.

As a homage to the two Ronnies, please make a follow up episode about what happens when four candles are used 🕯🕯🕯🕯🍴

Another way to look at the problem is to say there are n+1 evenly spaced holes (including the edges of the cake) you can put the candles in. Assuming your cake is one unit long, the probability of your knife falling between the candles is proportional to the distance between them. For n+1 pegs, this gives us n*(n+1)/2 configurations, so the probability of falling between the candles is the sum of the distances of each configuration divided by the number of configurations. The sum of said distances turns out to be the sum of the first n triangular numbers divided by n, so the overall equation simplifies to 2/(3n)+1/3. As n approaches infinity, the probability approaches 1/3.

Ben: Let's imagine a cake.. Camera: (points to laptop) Ben: Better still, let's code a cake using GeoGebra.

This was a fun one to try before watching. Began by trying a case with N equally spaced discrete candle positions where the knife could cut in a continuous range. Running the numbers gave a general formula for the probability for N positions as (N+1)/(3(N-1)), taking the limit for N -> infinity to get 1/3.

You can also integrate the probability that the candles fall on either side of the knife, which is the integral from zero to one of x*(1-x) dx, but you need to multiply the result by two because the candles could swap places at every knife position.

That cake looks nice and all, but that is one delicious-looking graph. That's my favorite here.

I was praying you wouldn't superimpose the word "cut" with a "k" on the video. Thank god you didn't. I think I speak for all Dutch viewers 🙂

My initial thought: calculate the average distance between the two candles, call it d. Then then probability that the knife hits between the two candles is d/D, where D is the length of the cake. Checked it and it gives 1/3.

Yeeeees a Ben Sparks video ! Always a pleasure to watch

Of course, if the cake was ACTUALLY a Battenberg, you could also talk about what colour order the squares in the cut could be, since they alternate. Wouldn't that be fun!

First instinct was 1/3, just ordering Candle1 Candle2 and Cut as three things in a row, youve got 2 of 6 permutations with the cut in the middle.

another method: let the cake have a length of 1. let x be the distance from the end of the cake at which the cake is cut. as such, it is also the amount of the cake on one slice. 1-x is the amount of the cake on the other slice. then, the probability that both candles are on different slices, given a cut x, will be the probability that they are not on the same slice. this works out to 1-(x^2+(1-x)^2). to find the total probability, take the integral between 0 and 1.

12:37 I love that Ben also immediately thought of Doc Brown.

Here's my conceptualization of the question that's being asked: What are the odds that a

My initial thoughts: find the average interval between the candles, then that size (normalize the whole cake to 1 for simplicity) is the probability of a uniform thing falling in that range.

I gave it a try and got 1/3. Time to watch the video and see the correct answer! Edit: Yay, I got it! I used an integral but the geometric solution is my favourite. It is crazy how many approaches exist for such simple problem.

My initial impulse was to draw a tree diagram, starting with three sided dice and the probability to get the third number in between the first two. Then I moved forward to a four sided dice, then a five sided dice, and then I was thinking about doing complete induction to prove that for any given sided dice the chances will be 1/3. I love it how many different ways are found in the video and the commentary to solve the problem

Almost all videos with Ben are very high on my favourites list. Can't wait to see what he'll show us next.

There's of course infinite solutions to this problem, but the one that came most naturally to me was to solve the integral of 2 * x * (1-x) dx from 0 to 1 - the chance of a candle on each side given x, the position of the cut. This value is of course 1/3. Edit: I originally wrote (x-1), but this should be (1-x).

Before Numberphile, I never would have paused the video, worked out a guess, then come up with two less mathematically rigorous but more intuitive (to me, only) versions of the first solutions shown. I don't know the formal math as well as I ought, but with all the cool problem solving you see on this channel (and Grant's as well), it's made a difference. I really was shocked at how close my methods were to the proper methods in the video. Keep up the great work.

My first intuition was Monte Carlo. I also considered Integration. But the ordering method mentioned in the video is just the most delicate and smartest method. Thank you.

I was in fact worried if the two specific candles mattered, I am no longer worried. Thanks.

First guess: 2 out of 6. Explanation: 1 cut and 2 candles will end up in a row with a random distribution. Short answer, there is 1/3 of a chance that the cut ends up in the middle.

Love all the stuff in the background Ben!

Best maths teacher in numberphile

The combinatorial solution is probably the most elegant… but let me share another! First , I want to note that if the cake has length 1, the chance that the knife lands between the candles is exactly the same as the average distance between the two candles. What is this distance? Call it ‘x’ for now and consider the following recursive argument. The two candles could be distributed either one in each half of the cake, or both in the same half, each with probability 1/2. In the first case, one candle will be on average 1/4 of the way along the cake, the other on average 3/4 of the way making for an average distance of 1/2. In the second case, we end up with the same problem but on a cake half the size , ie what’s the average distance between two candles on a cake of size 1/2? Which would be our ‘x’ but divided by 2. So we must then have that x = 50%*1/2 + 50% * x/2, which can be rearranged to find x=1/3

These are the kinds of math problems I love seeing from numberphile

great work i just love your videos keep it up Numberphile

As a further check, we know the probability density function of the uniform distribution. So we can label the candles x and y, and the cut z, and just calculate the probabilities x < z < y and y < z < x and add them up. The actual calculation is left as an exercise for the student. (But it better be 1/3.)

Pretty easy to show the 1/2 guess is wrong: if the cut is in the middle, the odds are 1/2, and if the cut is towards one edge, the odds are very small, so the answer must be smaller than 1/2. (This leads to a solution by integration.)

Number 1 on numberphile

Another great video guys! Truly enjoyed it.

That black and blue Mandelbrot set used to be my desktop wallpaper too. It really is a beautiful picture.

Intuitively a minute and 33 seconds and I’m going to say 1/3 chance.

Before I watch this all through, I just took the cake to be of length 1 and the cut at distance x from one end. Then the probability of any single candle being in the first section is simply x, which means that the probability of it note being in that section is 1-x of course. So the possibility of both being in the first section is p(2)= x^2, and of none being p(0)=(1-x)^2. That must mean the probability of just 1 is 1-p(0)-p(2)=1-1+2x-x^2-x^2=2x-2x^2. Now integrate 2x-2x^2 between the limits of 0 & 1 and you get [x^2-x^3/3+c] between the limits of 0 and 1, which works out at 1-2/3+c-c = 1/3. So I make the probability of each piece having exactly one candle 1/3. I'm sure there's a much simpler and elegant way of doing it, but my approach wasn't too difficult. That's assuming I have it right of course... my particular trick for sanity checking such problems is to cheat and use Excel to model it in actual numbers, which is not something mathematicians might approve of. *** now I've watched the video, it seems I have used a completely different technique, albeit it feels like a sledgehammer to break a nut.

Place first candle then cut the cake. The cake can now be represented by three regions: - from edge to candle, - from candle to cut, -from cut to the other edge. By symmetry there is no reason for any of those regions to be bigger than to other. As only one of those equal regions result in success we conclude that the probability is 1/3. By symmetry the different ordering of placing candles and cuts yields the same answer.

The crucial part of the ordering approach is that because each items position comes from the same distribution independently any permutation is equally likely (one reason is the computation of P(a

33% - you've got 3 points on one line. Non of the points is unique, they are all the same, so there is the same probability that any of them is in the middle between two others. Each piece of cake has one candle only when the "cutting" point is in the middle, so 1 case out of 3.

Finally a topic I can grasp 😅 I am slightly disappointed there wasn't a reference to the Two Ronnies' Four Candles.

Another interesting Numberphile video. I love the use of a Battenburg cake. I like those and it makes me wish I could get one locally. :)

2 girls one cup*

If you write a simulation you have to generate three random numbers and choose what order to assign them. You can assign them candle 1, candle 2, and knife or candle 2, knife, candle 1, or whatever. As we saw in the video, there are 6 ways to assign these random numbers (6:40). If you have three random numbers, one will always be in the middle (ignoring when two or more are the same), and it will be in the middle in two ways--c1=smallest, knife=middle, c2=largest or c1=largest, knife=middle, c2=smallest--that means that two out of the six ways will have the knife in the middle, giving one third.

Excellent video. Thanks Math Damon.

I love Ben Sparks with all my heart

I am simple man. I see a thumbnail with Ben Sparks in it, I click it and watch the video.

A slightly less elegant way I solved this is a double integral: Integral from 0 to 1 of (Integral from 0 to 1 of ( | x - y | ) with respect to x) with respect to y. I imagine this as a function f(x,y) mapping the positions of the two candles to a probability that the cut will be between them. Thus forming a probability distribution not-unlike the cube shown in the video. This probability distribution can be summed to yield the 1/3 chance.

I am in love with this man´s bookshelf

I just so proud (as an American) that Australian-British Brady Haran, all around brilliant guy, maker of awesome videos, and deep diver into the best objects know to British mankind, has had the time and energy to have learned that in American baseball a strike is represented by a K.

This was exceptional! Would like more multiple perspectives videos

I find this really interesting, given that I am visiting a measure- and probability theory class at university, and the Volume enclosed by that space is very fitting given the lebesgue measure and the lebesgue integral, yet I hope we stay more within the theory on how to construct somethign like this than the actual calculations of specific probabilities

I'm over here doing an integral and Ben is just like "there are only 3 possibilities and they're equally likely".

My intuition was 1/3, but I couldn't immediately come up with an explanation or an argument for it. Happy to find I was correct.

*Lover's Theme faintly plays in the background*

I paused the video to think and came up with 1/3, now I'll tackle this day with newly found confidence. :D

Klein bottle, rubik's cube, Game Boy, and a lightsaber, now that's a nice shelf.

My guess before I watch the whole thing, let's see if I'm right: the probability is the volume of the set of points in the unit cube that satisfy x < y < z ∨ z < y < x. This set consists of two disjoint sets of the same volume. Each of those is a tetrahedron, a pyramid with with half-triangle of the unit square as the base and unit as the height, so its volume is 1/3 * 1/2 * 1 = 1/6, and the answer should be twice that i.e. 1/3.

Here's how I would model the situation in a program: Pick random numbers between 0 and 1 for variables A,B,C If A>B>C OR A

I think this is the first time my intuition matched the solution on a numberphile video

“Cut with a K is now going to be in my head forever” is an interesting sentence if you’re Dutch

Ben, if it helps you not be surprised, the number of decimal places of the probability that you get with a Monte Carlo method goes like the order of magnitude of the number of trials. I know how you feel though, I always found it weird until that penny dropped for me. Each sucessive trial's impact on the probability figure goes like the inverse of the number of trials.

A solve our silly intuition: swap the cuts and the candles. If the problem was: "Make two random cuts on a cake then place a candle randomly. What's the likelihood that the candle will be in the middle slice?" Then our intuition immediately gets it right. The semiotic connotations of the symbols of "candle" and "cut" mess with our intuition. Strip that away and it's easier to solve :) Love this channel! :D

“I’ve deliberately got a linear cake” another addition to “quotes only a mathematician would make”

I paused the video immediately, and ordering was my first idea! I came up with 1/3 too.

shoutouts to this video making me dust off my knowledge of integrals to solve it. And then making me feel like an idiot for forgetting I could just look at it from an ordering perspective.

As a lazy / bad mathematician I would have jumped straight to a Monte Carlo model - I’m glad you got there in the end! And the key advantage is that when the going gets tough (multi-dimensional cakes?) the MC method is definitely easier :-)

Having just finished a Combinatorics class, my first thought was simplifying to a discreet case. Instead of the candles and cut being any real number along the cake, split the cake into n regions and place them each in one region at random. If the cut is in the same region as one or both candles, count it in favor of the candles being on different slices. The probability we're looking for would then be the limit as n gets larger. The probability of the candles being on different slices is the number of outcomes where that's true divided by the total number of outcomes. Assuming the two candles are indistinguishable, they can either be in the same region (n possible orientations) or different regions (n choose 2 orientations), so there are n + n(n-1)/2 = n(n+1)/2 ways to place the candles. The cut can then be made in any of the n regions, so there are n * n(n+1)/2 = n^2(n+1)/2 possible outcomes. There are n ways to place the two candles on the same region and 1 way to successfully cut between the candles afterwards, there are n-1 ways to place the candles in adjacent regions and 2 regions to successfully cut, etc. In general, there are n-i+1 ways to place the candles i-1 regions apart and i ways to successfully cut the cake afterwards, for any i between 1 and n. The number of successful outcomes is then the sum from i=1 to n of i(n-i+1) which according to Wolfram Alpha has a closed form of n(n+1)(n+2)/6. The probability of cutting between the candles with n regions is then (n(n+1)(n+2)/6)/(n^2(n+1)/2) = 2(n+2)/(6n) = 1/3 * (n+2)/n The probability of the continuous case is lim as n -> infinity of (1/3 * (n+2)/n) = 1/3 * lim as n -> infinity of (n+2)/n = infinity/infinity, apply L'Hospital's rule: 1/3 * lim as n -> infinity of (d/dn(n+2))/(d/dn(n)) = 1/3 * lim as n -> infinity of 1/1 = 1/3

2:15 "Can I ask a question?" When people say that to me, I reply "You just did!"

Fourth method: calculus! Let the cut be at the number x. We win if one candle is less than x and the other candle is greater than x, which occurs with probability 2x(1-x). Integrating this from 0 to 1 gives 1/3. [Similarly, the probability that both candles are less than x is x^2, and the probability that both candles are greater than x is (1-x)^2, each of which also integrates to 1/3.]

From this you can also conclude that the average distance between 2 random points on a 0-1 line segment is 1/3.

this 3 part cube is the first demonstration i made. The teacher asked us to build something related to maths. I wanted something that had a meaning and came up with that.

Bro i saw this guy do a talk on numbers he is actually rlly chill

I was thinking about Bertrand's Paradox when I was watching this.

This is cutting edge science. The video is also well-cut. I'll stop with the puns, I don't want you to cut your arteries out of cringe.

2:25 - It's not just that the cut can't happen where the candle is. Random placement ought to say if the candles can be together or have some minimum space between.

My first idea was that (assuming the cake to be of length 1) the required probability is the same as the expected value of the distance between the two candles. To find this, we first imagine placing the first candle at some position x and then if the second candle is on the left of x (with probability x), it is expected to be at a distance of x/2 from the first candle and if it is to the right of x (with probability 1-x), it is expected to be at a distance of (1-x)/2 from the first candle. Hence, the answer is the integral from 0 to 1 of x • (x/2) + (1-x) • (1-x)/2, and by King's property this is the integral of x² from 0 to 1, i.e. ⅓. I felt that the method with arrangement was really elegant... The fact that it requires no calculus is amazing

We're 33 sec in and I already have strong Bertrand's Paradox with 3Blue1Brown vibes.

it makes sense without numbers or graphs or writing out the possible answers. the candles can be anywhere and equally likely to be everywhere. you've got two equal dividers in a cake, cut anything into equal size pieces twice and you've made thirds from the whole. you can think of the middle slice as the target, it's one third the total cake. you don't need a 3D plot, 2d is just fine.

I got 1/3 by turning the continuous cake into a line of discreet points, started with three possible positions, got a third. Kept going with four and got a third again. Then I checked the comments and saw one that reframes the questions as picking three random points, randomly declaring one as a cut and the other two as candles, and looking at the chances of the cut being the centermost of the three points. It doesn't matter how far apart they can be, how many discrete positions the points can have, there's always one chance out of three that the cut lands between the two candles.