probability - Book Proofs

Elf music

This holiday-themed Riddler problem is about probability:

In Santa’s workshop, elves make toys during a shift each day. On the overhead radio, Christmas music plays, with a program randomly selecting songs from a large playlist.

During any given shift, the elves hear 100 songs. A cranky elf named Cranky has taken to throwing snowballs at everyone if he hears the same song twice. This has happened during about half of the shifts. One day, a mathematically inclined elf named Mathy tires of Cranky’s sodden outbursts. So Mathy decides to use what he knows to figure out how large Santa’s playlist actually is.

Help Mathy out: How large is Santa’s playlist?

Here is my solution:
[Show Solution]

Beer pong

This interesting twist on the game of Beer Pong appeared on the Riddler blog. Here it goes:

The balls are numbered 1 through N. There is also a group of N cups, labeled 1 through N, each of which can hold an unlimited number of ping-pong balls. The game is played in rounds. A round is composed of two phases: throwing and pruning.

During the throwing phase, the player takes balls randomly, one at a time, from the infinite supply and tosses them at the cups. The throwing phase is over when every cup contains at least one ping-pong ball. Next comes the pruning phase. During this phase the player goes through all the balls in each cup and removes any ball whose number does not match the containing cup. Every ball drawn has a uniformly random number, every ball lands in a uniformly random cup, and every throw lands in some cup. The game is over when, after a round is completed, there are no empty cups.

How many rounds would you expect to need to play to finish this game? How many balls would you expect to need to draw and throw to finish this game?

Here is my solution:
[Show Solution]

We’ll address the second question first: How many balls would you expect to need to draw and throw to finish the game? For this question, the rounds don’t matter at all. The game will end once there is at least one correct ball in each cup, and the pruning phase at the end of each round only removes incorrect balls so we can effectively neglect it.

Each time a ball is thrown, there is a $1/N$ chance it will land in the correct cup. This is a classical coupon collector problem (see my write-up on the card collection completion problem for more background). The solution rests on the fact that if some trial is successful with probability $p$, then we must perform $1/p$ trials on average before we obtain our first success. The probability of landing our first correct ball is $1/N$ so it will take an average of $N$ tosses to do so. The probability of landing our next new correct ball (in a different cup) is $\tfrac{1}{N}\cdot \tfrac{N-1}{N}$. This takes on average $\tfrac{N^2}{N-1}$ more tosses. Continuing in this fashion and summing up all of the intervals until each cup is filled, the total expected number of tosses is:

$\displaystyle
T_\text{tot} = N^2 \sum_{k=1}^N \frac{1}{k} \approx N^2(\log N + \gamma)
$

where $\gamma \approx 0.5772$ is the Euler-Mascheroni constant.

Now let’s turn our attention to the first question: How many rounds would you expect to play to finish this game? This is a much more complicated question, so to illustrate the approach I’ll solve it for the case $N=3$. We’ll begin by breaking each round into a number of stages, which track the progress of cups as they are filled. In the diagram below, each cup is either empty (no ball), is red (incorrect ball), or is green (correct ball). We can also figure out all the transition probabilities and write them on the arrows.

In this diagram, self-loops have whatever probability is required so that the outgoing arrows sum to $1$. This is an example of a Markov chain. We start on the left (all cups empty), and we work our way to the right (all cups full). Here is what the transition matrix looks like for $N=3$ when we arrange the states from top to bottom and left to right:
\[
A =
\begin{bmatrix}
0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\
2/3 & 2/9 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\
1/3 & 1/9 & 1/3 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\
0 & 4/9 & 0 & 4/9 & 0 & 0 & 0 & 0 & 0 & 0 \\
0 & 2/9 & 4/9 & 2/9 & 5/9 & 0 & 0 & 0 & 0 & 0 \\
0 & 0 & 2/9 & 0 & 1/9 & 2/3 & 0 & 0 & 0 & 0 \\
0 & 0 & 0 & 2/9 & 0 & 0 & 1 & 0 & 0 & 0 \\
0 & 0 & 0 & 1/9 & 2/9 & 0 & 0 & 1 & 0 & 0 \\
0 & 0 & 0 & 0 & 1/9 & 2/9 & 0 & 0 & 1 & 0 \\
0 & 0 & 0 & 0 & 0 & 1/9 & 0 & 0 & 0 & 1
\end{bmatrix}
\begin{array}{c}
(k=0,j=0)\\
(k=1,j=0)\\
(k=1,j=1)\\
(k=2,j=0)\\
(k=2,j=1)\\
(k=2,j=2)\\
(k=3,j=0)\\
(k=3,j=1)\\
(k=3,j=2)\\
(k=3,j=3)\\
\end{array}
\]Note that the columns sum to $1$ since all outgoing probabilities must sum to $1$. The question is: what is the probability that we’ll end up in each of the possible ending point? (the four last states). This is called the limiting distribution. In our case, we can compute it easily. First, we can eliminate the self-loops by normalizing. This works because we don’t actually care how much time is spent at each stage. See below for an illustration of this normalization.

Here is what our transition matrix looks like after normalization
\[
A_\text{norm} =
\begin{bmatrix}
0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\
2/3 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\
1/3 & 1/7 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\
0 & 4/7 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\
0 & 2/7 & 2/3 & 2/5 & 0 & 0 & 0 & 0 & 0 & 0 \\
0 & 0 & 1/3 & 0 & 1/4 & 0 & 0 & 0 & 0 & 0 \\
0 & 0 & 0 & 2/5 & 0 & 0 & 1 & 0 & 0 & 0 \\
0 & 0 & 0 & 1/5 & 1/2 & 0 & 0 & 1 & 0 & 0 \\
0 & 0 & 0 & 0 & 1/4 & 2/3 & 0 & 0 & 1 & 0 \\
0 & 0 & 0 & 0 & 0 & 1/3 & 0 & 0 & 0 & 1
\end{bmatrix}
\begin{array}{c}
(k=0,j=0)\\
(k=1,j=0)\\
(k=1,j=1)\\
(k=2,j=0)\\
(k=2,j=1)\\
(k=2,j=2)\\
(k=3,j=0)\\
(k=3,j=1)\\
(k=3,j=2)\\
(k=3,j=3)\\
\end{array}
\]Once again, the columns sum to $1$, but this time only the absorbing states have self-loops. Finding the limiting distribution simply amounts to finding the limit $\lim_{t\to\infty} A_\text{norm}^t$. Since the upper-left block of $A_\text{norm}$ is nilpotent (the diagonal is zero), powers of the matrix will eventually be constant. It suffices to evaluate $A_{\text{norm}}^{2N}$. Extracting the last N+1 rows and the columns corresponding to the states $\{1,3,6,\dots,\tfrac{(N+1)(N+2)}{2}\}$ (the states where we have exactly $k$ correct balls in cups, for $k=0,1,\dots,N$), we obtain the transition matrix for one round of the game. Here is the result we obtain in the case $N=3$:
\[
P = \begin{bmatrix}
16/105 & 0 & 0 & 0 \\
41/105 & 1/3 & 0 & 0 \\
5/14 & 1/2 & 2/3 & 0 \\
1/10 & 1/6 & 1/3 & 1
\end{bmatrix}
\begin{array}{c}
(k=0)\\
(k=1)\\
(k=2)\\
(k=3)\\
\end{array}
\]In other words, $P_{ij}$ is the probability that if we currently have $j$ correct balls in cups, we will have $i$ after the next round is over. From here, our next task is to compute the expected number of rounds it will take to travel from $k=0$ to $k=N$. This can be computed as follows: if we call $E_k$ the expected number of rounds starting from $k$, then we have:
\begin{align}
E_0 &= 1 + P_{00} E_0 + P_{10}E_1 + \cdots + P_{N0}E_N \\
E_1 &= 1 + P_{01} E_0 + P_{11}E_1 + \cdots + P_{N1}E_N \\
&\vdots \\
E_{N-1} &= 1 + P_{0,N-1} E_0 + P_{1,N-1}E_1 + \cdots + P_{N,N-1} E_N \\
E_N &= 0
\end{align}Or, in matrix-vector notation: $E = \mathbb{1} – e_N + P^\mathsf{T} E$. This can be solved via simple matrix inversion. We can then extract $E_0$ from the solution, which is the expected number of rounds starting with all empty cups. As far as I can tell, there does not appear to be an easy way to extract an analytic formula, but all the steps above are very easy to compute numerically. Here are plots of the results for small values of $N$:

I also overlayed a result obtained via Monte-Carlo simulation using $1000$ simulated games. This shows that the analytical results agree well with simulation. Here are further numerical results, this time extended up to $N=100$:

It appears that the number of rounds required grows approximately linearly with $N$ while the number of balls required grows quadratically. This latter result is to be expected, since we know the formula in this case is approximately $N^2 \log N$.

Hand sort

A card-rearranging problem on the Riddler blog. Here it goes:

You play so many card games that you’ve developed a very specific organizational obsession. When you’re dealt your hand, you want to organize it such that the cards of a given suit are grouped together and, if possible, such that no suited groups of the same color are adjacent. (Numbers don’t matter to you.) Moreover, when you receive your randomly ordered hand, you want to achieve this organization with a single motion, moving only one adjacent block of cards to some other position in your hand, maintaining the original order of that block and other cards, except for that one move.

Suppose you’re playing pitch, in which a hand has six cards. What are the odds that you can accomplish your obsessive goal? What about for another game, where a hand has N cards, somewhere between 1 and 13?

Here is my solution:
[Show Solution]

I was unable to find an analytic or closed-form expression for the solution to this problem, so I’ll present an old fashioned brute-force solution. The idea is simple:

Enumerate all possible hands
For each hand, enumerate all possible moves that consist of moving some group of adjacent cards to somewhere else in the hand.
If any such move succeeds in sorting the hand, mark the hand as “good”.
Once we’re done, count all “good” hands and divide that by the total number of hands

Simple, right? I’d like to point out is that this is not an approximate solution; there is no simulation involved. I’m counting all the possible scenarios, so this approach produces the exact answer. The only problem is that there are a lot of hands to check, and the bigger the hands get, the longer it takes to check them, since there are more possible moves. Successfully solving this problem requires coding it up in a way that a computer can find the solution in a reasonable amount of time. In order to make this work, I used several tricks to reduce the computation required:

We don’t have to enumerate all possible hands because only the suits matter, but we do have to be careful about how we count. We begin with a full deck of cards (52 distinct cards). Let’s suppose we want to count hands of size 2. There are $52\cdot 51 = 2652$ possible hands. But since numbers don’t matter, we can remove the number and just look at suits. There are then 16 possible hands:
\[
\begin{array}{cccc}
♠♠ & ♠♣ & ♠\color{red}{♥} & ♠\color{red}{♦} \\
♣♠ & ♣♣ & ♣\color{red}{♥} & ♣\color{red}{♦} \\
\color{red}{♥}♠ & \color{red}{♥}♣ & \color{red}{♥}\color{red}{♥} & \color{red}{♥}\color{red}{♦} \\
\color{red}{♦}♠ & \color{red}{♦}♣ & \color{red}{♦}\color{red}{♥} & \color{red}{♦}\color{red}{♦}
\end{array}
\]suppose for example that the hands with different suits but same color are not sortable. There are four such hands: $\{ ♠♣, ♣♠, \color{red}{♥}\color{red}{♦}, \color{red}{♦}\color{red}{♥} \}$. Then we might conclude that $\tfrac{4}{16} = 0.25$ of hands are not sortable. But this would be wrong! (thanks to Guy Moore for pointing this out). The reason is that these 16 hands don’t all occur with equal probability. There are $13\cdot 13 = 169$ ways of picking two cards of different suits, but only $13\cdot 12 = 156$ ways of picking two cards of the same suit! So each type of card should be weighted by its likelihood of occurrence. This means the probability of picking an unsortable hand should really be:
\[
\frac{4\cdot 169}{4\cdot 156 + 12\cdot 169} = \frac{13}{51} \approx 0.2549
\]So we can collapse the large number of possible hands to this more manageable size as long as we compensate by appropriately weighting the different items. In combinatorics, this collapsed group of cards (where we care about the order and the suit, but not the number of the card) is an example of a multiset permutation.

Note: If we don’t weigh the hands according to likelihood (i.e. assume all hands are equally likely), this is equivalent to assuming the deck has infinitely many cards (but the same number of cards in each suit).
Adjacent cards of the same suit can be collapsed to a single card. This is because there is never any benefit to moving a block of cards if it splits an existing contiguous block. So for example:
\[
\{♠,♠,\color{red}{♥},\color{red}{♥},\color{red}{♦}\} \implies \{♠,\color{red}{♥},\color{red}{♦}\}.
\]This greatly reduces the computations because if two different hands collapse to the same reduced hand, we only need to do the work for one of them! In computer programming, this technique of storing the values of computations so that you don’t end up computing the same thing many times is called memoization.
If a hand consists of $N$ cards (after we collapse adjacent suit repetitions as described above), then there are $\binom{N+1}{3}$ possible moves we can make. This is because every move is characterized by three locations. I’ll illustrate this with an example. Say our hand looks like this: $\{♠,\color{red}{♥},\color{red}{♦},♠,\color{red}{♥},♣\}$ and we want to sort it by moving cards 4 and 5 and inserting them between cards 1 and 2. In other words, we want to perform:
\[
\{♠,\color{red}{♥},\color{red}{♦},(♠,\color{red}{♥}),♣\} \implies \{♠,(♠,\color{red}{♥}),\color{red}{♥},\color{red}{♦},♣\}
\implies \{♠,\color{red}{♥},\color{red}{♦},♣\}
\]where we did one final collapse at the end. This transformation can be represented by inserting three “bars” between cards as follows. Then the swap simply consists of exchanging the cards between the two pairs of bars! Here is the diagram:
\[
\{\,♠\,\,|\underbrace{\color{red}{♥}\,\,\color{red}{♦}}_\text{swap this}|\underbrace{♠\,\,\color{red}{♥}}_\text{with this}|\,\,♣\,\}
\implies \{♠, ♠, \color{red}{♥},\color{red}{♥},\color{red}{♦},♣\}
\]Each triplet of bars corresponds to a possible swap, and we can insert bars in $N+1$ possible spots (in between each card and on either end).
If the hand has 8 or more cards in it after we perform the collapse, then it’s impossible to sort it in one move. This is because our final hand can have at most 4 groups of cards in it, and a single move can cause at most 3 collapses. With 8 cards, we can get down to 5 but not 4. Here is an example of a 7-card hand that can be sorted in one move:
\[
\{\,♠\,|\,\color{red}{♥}\,♣\,|\,♠\,\color{red}{♥}\,|\,♣\,\color{red}{♦}\,\}
\implies \{\,♠\,♠\,\color{red}{♥}\,\color{red}{♥}\,♣\,♣\,\color{red}{♦}\,\}
\implies \{\,♠\,\color{red}{♥}\,♣\,\color{red}{♦}\,\}
\]

Numerical results

There was a bit of confusion as to how to interpret the meaning of the requirement “the cards of a given suit are grouped together and, if possible, such that no suited groups of the same color are adjacent”. One way to interpret this statement is that we only require cards of a different suit but same color to be separated if it’s actually possible to separate them. For example, the two-card hand $\{\color{red}{♥}\,\color{red}{♦}\}$ counts as being sorted because there are no spades or clubs that can be placed between the heart and the diamond. In this scenario, here are the results:

Note that hands of up to size $N=4$ are always sortable in one move. The exact solution for the case $N=6$ using this interpretation is $\tfrac{51083}{83895} \approx 60.8892\%$. Another way to interpret the requirement is that cards of a different suit but same color can never be adjacent. This means that hands like $\{\color{red}{♥}\,\color{red}{♦}\}$ are never sortable no matter what you do. In this case, we get the result:

It’s interesting to note that the probability of a “sortable” hand in this interpretation actually reaches a maximum when $N=4$ and then decreases afterwards. The exact solution for the case $N=6$ using this interpretation is $\tfrac{1735996}{2936325} \approx 59.1214\%$.

I wrote my code in Julia, and you can view my notebook here. The computation gets slower in an exponential fashion as we increase $N$. The cases $N \leq 8$ take on the order of seconds, but computation time quadruples every time $N$ increases by 1. The last case, $N=13$, took about 40 minutes! While there is a significant amount of computation to do, there is also significant computational overhead due to using exact arithmetic instead of making approximations. For this, I used Julia’s BigInt datatype. So the solutions I obtained were exact. For example, the probability of a sortable hand for $N=13$ (using the first interpretation) turns out to be:
\[
\tfrac{10954472929065768960}{3954242643911239680000} = \tfrac{30785713171}{11112737293000} \approx 0.27703\%
\]Using approximations the whole way leads to a computation time of less than 10 minutes for the most complicated case.

Card collection completion

This Riddler puzzle is a classic probability problem: how long can one expect to wait until the entire set of cards is collected?

My son recently started collecting Riddler League football cards and informed me that he planned on acquiring every card in the set. It made me wonder, naturally, how much of his allowance he would have to spend in order to achieve his goal. His favorite set of cards is Riddler Silver; a set consisting of 100 cards, numbered 1 to 100. The cards are only sold in packs containing 10 random cards, without duplicates, with every card number having an equal chance of being in a pack.

Each pack can be purchased for \$1. If his allowance is \$10 a week, how long would we expect it to take before he has the entire set?

What if he decides to collect the more expansive Riddler Gold set, which has 300 different cards?

Here is my solution:
[Show Solution]

This problem is a twist on the classical Coupon Collector Problem. In this problem, there are $n$ different coupons in a basket. For one dollar, we get to pick a coupon at random from the basket. We then return the coupon to the basket. We keep doing this until we’ve seen each of the $n$ different coupons at least once. How many dollars will we spend on average?

Simpler version: packs of one

Let’s start by solving the standard coupon collector problem. First, we’ll need the following fact: if a coin comes up Heads with probability $p$, then we have to flip it on average $1/p$ times before we obtain our first Heads. To see why, let $x$ be the expected number of flips. If the first flip is Heads, (probability $p$), then we have performed 1 flip and we stop. If the first flip is Tails, (probability $1-p$), then we have performed 1 flip but we will need to perform $x$ more on average. Mathematically, this amounts to:
\[
x = p\cdot 1 + (1-p)\cdot (1+x)
\]Solving for $x$ yields $x=1/p$. You can also solve this using recursion, as in my solution to the Monsters’ gems puzzle.

We can think of the coupon collection problem by asking how many draws are required before we pick our next new coupon. Our first coupon is always new (probability 1) and will take 1 draw. The probability of picking our next new coupon is $\tfrac{n-1}{n}$ since any of the $n-1$ remaining coupons will do, and this will take on average $\tfrac{n}{n-1}$ draws. Next, our probability is $\tfrac{n-2}{n}$, which takes on average $\tfrac{n}{n-2}$ draws, and so on. Therefore, the expected number of draws $C_n$ in order to pick all $n$ coupons is:
\begin{align}
C_n
&= \frac{n}{n} + \frac{n}{n-1} + \frac{n}{n-2} + \cdots + \frac{n}{1} \\
&= n \left( 1 + \frac{1}{2} + \cdots + \frac{1}{n} \right) \\
&\approx n (\log n + \gamma)
\end{align}Where $\gamma \approx 0.5772$ is the Euler-Mascheroni constant and the approximation becomes exact as $n\to\infty$. This is a harmonic sum and it has surfaced in several past problems (bears, camels, dwarfs).

Full version: multi-packs

Let’s now assume that we draw $m$ coupons at a time from the basket, which contains $n$ distinct coupons. This is precisely the original problem (with $m=10$ and $n=100$). Let’s call $X_k$ the expected number of additional draws required to obtain all $n$ coupons given that we have already collected $k$ coupons. We could get lucky and obtain several new coupons in our draw, or we could strike out and receive all duplicates. In general, there are $\binom{k}{m-i}\binom{n-k}{i}$ ways to obtain $i$ new coupons (out of $\binom{n}{m}$ total possible draws), since we can choose $i$ out of the $n-k$ possible new coupons remaining and $m-i$ out of the $k$ already-seen coupons. Upon drawing our $i$ new coupons, we will have to make $X_{k+i}$ further draws. We therefore have the recursion:
\[
X_k = 1 + \sum_{i=0}^m \frac{\binom{k}{m-i}\binom{n-k}{i}}{\binom{n}{m}} X_{k+i}
\]Noting that $X_k$ occurs on both sides, we can simplify and obtain:
\[
X_k = \frac{1}{\binom{n}{m}-\binom{k}{m}}\left( \binom{n}{m} + \sum_{i=1}^m \binom{k}{m-i}\binom{n-k}{i} X_{k+i} \right)
\]Now each $X_k$ depends on $X_{k+1},X_{k+2},\dots$, and we have the terminal condition $X_n = 0$. So we can work backwards, first evaluating $X_{n-1}$, then $X_{n-2}$, and so on until we arrive at $X_0$, which is the final answer we seek. As a side note, the fact that the probabilities above sum to $1$ is a consequence of Vandermonde’s Identity, which I discussed in my post on double counting.

It doesn’t appear that there is a nice closed-form expression for $X_0$, however it’s straightforward to do this numerically, as long as care is taken with the binomials causing integer overflow when $n$ and $m$ get large. We can also approximate the solution decently well: the $m=1$ case (one card per pack) requires approximately $n(\log(n)+\gamma)$ packs to collect all cards, so one might expect that with $m$ cards per pack, one could collect all cards roughly $m$ times faster. This turns out to be a good approximation!

In the plot below, I computed the exact expectation and also showed the approximation $\tfrac{n}{m}(\log(n)+\gamma)$.

Numerical solutions

The original problem statement asked about the case of $m=10$ cards per pack, with either $n=100$ or $n=300$ total different cards. Here is Julia code that evaluates the solution rather quickly:

# Julia 0.6.4
# define binomial for large values of n (use infinite precision)
binom(n,m) = binomial(big(n),m)
function expected_draws(n,m)
    X = zeros(n+m+1)
    for k = n-1:-1:0
        q0 = binom(n,m)/(binom(n,m)-binom(k,m))
        q = [ binom(k,m-i)*binom(n-k,i)/(binom(n,m)-binom(k,m)) for i in 1:m ]
        X[k+1] = q0 + sum(q .* X[k+2:k+1+m])
    end
    X[1]
end
println("100 cards, packs of 10: Number of packs = ", expected_draws(100,10))
println("300 cards, packs of 10: Number of draws = ", expected_draws(300,10))

and the output of the above code is:

100 cards, packs of 10: Number of packs = 49.94456605666412
300 cards, packs of 10: Number of draws = 186.0851712198894

Therefore, it requires about 50 packs (5 weeks allowance) on average to collect all cards in the 100-set, and about 186 packs (18.6 weeks allowance) for the 300-card set. If we use the approximation $\tfrac{n}{m}(\log(n)+\gamma)$, we actually come pretty close to the exact answer:

100/10 * (log(100) + γ) = 51.8238585088962
300/10 * (log(300) + γ) = 188.429944186732

Hoop hop showdown

This Riddler puzzle is a shout-out to this YouTube video of a game called “Hoop hop showdown”.

Here is an idealized list of its rules:

Kids stand at either end of N hoops.
At the start of the game, one kid from each end starts hopping at a speed of one hoop per second until they run into each other, either in adjacent hoops or in the same hoop.
At that point, they play rock-paper-scissors at a rate of one game per second until one of the kids wins.
The loser goes back to their end of the hoops, a new kid immediately steps up at that end, and the winner and the new player hop until they run into each other.
This process continues until someone reaches the opposing end. That player’s team wins!

You’ve just been hired as the gym teacher at Riddler Elementary. You’re having a bad day, and you want to make sure the kids stay occupied for the entire class. If you put down eight hoops, how long on average will the game last? How many hoops should you put down if you want the game to last for the entire 30-minute period, on average?

Here is a derivation of how I solved the problem:
[Show Solution]

Note: The wording in the problem is a bit ambiguous with regards to a few details. e.g. Do the players start outside and jump into the first hoop when they start or do they start inside the first hoop? Does the game end when you win at the last hoop, or one second later when you jump out? I made assumptions that I thought were reasonable in formulating the problem. While slight changes in details regarding the problem could change the final answer, the same general solution approach should still apply.

There are $N$ hoops but there are $k=1,2,\dots,2N-1$ possible ways in which two kids can stop to have a rock-paper-scissors (RPS) match. This is because the two kids can land in the same hoop or in adjacent hoops. Here is a diagram for $N=3$ showing all possible pairs:

Here is an example of how the game might play out in this simple scenario:

When the game starts, both kids are outside the hoops. After 2 seconds, we end up in the $k=3$ case.
Suppose blue wins. Then 1 second later we are in $k=5$.
Suppose orange wins. Then 1 second later we are in $k=2$.
Suppose orange wins. Then 1 second later we are in $k=1$.
Suppose orange wins. Then the game ends.

Let’s generalize this process to any number of hoops. We’ll call $f(k)$ the expected number of seconds we have to wait for the game to end if we are currently in state $k$. If we are at state $k$, here are the options:

If orange wins RPS, the next showdown occurs at state $\left\lfloor \frac{k}{2} \right\rfloor$ after $\left\lfloor \frac{k+2}{4} \right\rfloor$ seconds unless $k=1$, in which case the game ends.
If blue wins RPS, the next showdown occurs at state $\left\lfloor \frac{2N+k+1}{2} \right\rfloor$ after $\left\lfloor \frac{2N-k+2}{4} \right\rfloor$ seconds unless $k=2N-1$, in which case the game ends.

Note that we’re using the notation $\left\lfloor x \right\rfloor$ which is the floor function (round $x$ down to the nearest integer). We must also account for how many seconds a game of RPS lasts on average. Let’s call this $r$. There are nine equally likely possible games, and one third of them end in a tie (so we must play again). So the game duration satisfies: $r = 1 + \frac{1}{3}r$. In other words, we have $r=\frac{3}{2}$. Putting everything together, the function $f(k)$ satisfies:
\begin{multline}
f(k) = \frac{3}{2} + \frac{1}{2}\left( \left\lfloor \frac{k+2}{4} \right\rfloor + f\biggl(\left\lfloor \frac{k}{2} \right\rfloor\biggr) \right)\\
+ \frac{1}{2}\left( \left\lfloor \frac{2N-k+2}{4} \right\rfloor + f\biggl( \left\lfloor \frac{2N+k+1}{2} \right\rfloor \right) \biggr)
\end{multline}with the boundary conditions $f(0)=f(2N)=0$. These are in fact linear equations in the variables $f(k)$ for $k=0,1,\dots,2N$. Ultimately, we want to know the average duration of a game. The first showdown always occurs at state $N$ and is preceded by $\left\lfloor\frac{N+1}{2}\right\rfloor$ hops. So we’re ultimately looking to find:
\[
T_\text{avg} = \left\lfloor\frac{N+1}{2}\right\rfloor + f(N)
\]Here is how you would solve the problem in the $N=3$ case. The equations that relate the different $f(k)$ can be written out in matrix-vector form:
\[
\begin{bmatrix}
1 & 0 & 0 & -\tfrac{1}{2} & 0 \\
-\tfrac{1}{2} & 1 & 0 & -\tfrac{1}{2} & 0 \\
-\tfrac{1}{2} & 0 & 1 & 0 & -\tfrac{1}{2} \\
0 & -\tfrac{1}{2} & 0 & 1 & -\tfrac{1}{2} \\
0 & -\tfrac{1}{2} & 0 & 0 & 1
\end{bmatrix}
\begin{bmatrix}
f(1)\\ f(2) \\ f(3) \\ f(4)\\ f(5)
\end{bmatrix}
=\begin{bmatrix}
2\\\tfrac{5}{2}\\\tfrac{5}{2}\\\tfrac{5}{2}\\2
\end{bmatrix}
\]Solving these equations produces $f(3)=11.5$ and therefore $T_\text{avg} = 13.5\text{ sec}$. As we add more hoops (increase $N$), the procedure is analogous, and we can write code that rapidly solves these equations for a wide range of $N$ values… But we can do better!

Note that we don’t actually care about the other values of $f(k)$. We only need to know the middle one, $f(N)=f(3)$. Also note that the columns of the matrix all sum to zero except the middle one… So if we sum all columns (equivalent to summing all our equations together), we obtain:
\[
f(3) = 2+\tfrac{5}{2}+\tfrac{5}{2}+\tfrac{5}{2}+2 = 11.5
\]which is the same answer as we found by solving the whole system! In fact, this pattern persists for all $N$. Our matrix will always have dimensions $(2N-1)\times(2N-1)$ and all columns will sum to zero except the middle one! So in general, we can write the solution for the case of $N$ hoops as:
\begin{align}
T_\text{avg} &= \left\lfloor\frac{N+1}{2}\right\rfloor + f(N) \\
&= \left\lfloor\frac{N+1}{2}\right\rfloor+\sum_{k=1}^{2N-1} \left( \frac{3}{2} + \frac{1}{2}\left\lfloor \frac{k+2}{4} \right\rfloor + \frac{1}{2}\left\lfloor \frac{2N-k+2}{4} \right\rfloor \right) \\
&= \frac{3}{2}(2N-1) + \left\lfloor\frac{N+1}{2}\right\rfloor+\sum_{k=1}^{2N-1} \left( \frac{1}{2}\left\lfloor \frac{k+2}{4} \right\rfloor + \frac{1}{2}\left\lfloor \frac{2N-k+2}{4} \right\rfloor \right) \\
&= \frac{3}{2}(2N-1) + \sum_{k=1}^{2N} \left\lfloor \frac{k+2}{4} \right\rfloor \\
&= \frac{3}{2}(2N-1) + \sum_{m=1}^{N} \left( \left\lfloor \frac{2m+1}{4} \right\rfloor + \left\lfloor \frac{2m+2}{4} \right\rfloor \right) \\
&= \frac{3}{2}(2N-1) + \sum_{m=1}^{N} m \\
&= \frac{3}{2}(2N-1) + \frac{1}{2}N(N+1) \\
&= \frac{1}{2}(N^2+7N-3)
\end{align}The simplification in the third last step follows by letting $m = 2q+r$ where $r\in\{0,1\}$. Then we may write:
\begin{align}
\left\lfloor \frac{2m+1}{4} \right\rfloor + \left\lfloor \frac{2m+2}{4} \right\rfloor
&=\left\lfloor \frac{4q+2r+1}{4} \right\rfloor + \left\lfloor \frac{4q+2r+2}{4} \right\rfloor \\
&=2q+\left\lfloor \frac{2r+1}{4} \right\rfloor + \left\lfloor \frac{2r+2}{4} \right\rfloor\\
&=2q+r\\
&=m
\end{align}

And if you just want to see the solutions:
[Show Solution]

Rug quality control

This Riddler puzzle is about rug manufacturing. How likely are we to avoid defects if manufacture the rugs randomly?

A manufacturer, Riddler Rugs™, produces a random-pattern rug by sewing 1-inch-square pieces of fabric together. The final rugs are 100 inches by 100 inches, and the 1-inch pieces come in three colors: midnight green, silver, and white. The machine randomly picks a 1-inch fabric color for each piece of a rug. Because the manufacturer wants the rugs to look random, it rejects any rug that has a 4-by-4 block of squares that are all the same color. (Its customers don’t have a great sense of the law of large numbers, or of large rugs, for that matter.)

What percentage of rugs would we expect Riddler Rugs™ to reject? How many colors should it use in the rug if it wants to manufacture a million rugs without rejecting any of them?

Here is my solution:
[Show Solution]

Since every possible rug is equally likely to occur, the probability of a rug being rejected is equal to the total number of defective rugs divided by the total number of rugs. Let’s assume the rug is $n\times n$, there are $d$ distinct color choices, and we’re looking to avoid $m\times m$ same-color patches. There are $N = (n-m+1)^2$ different $m\times m$ patches on the rug. For easier bookkeeping, let’s number these using a single index $1 \le i \le N$. Let’s define the following event:
\[
X_{i} = \left\{
\begin{array}{l}\text{the }i^\text{th} \text{ }m\times m \text{ patch}\\\text{is all the same color}\end{array}\right.
\]The union of these events $X = \bigcup_{i=1}^N X_{i}$ describes the case where there is at least one same-color patch on the rug and therefore the rug must be rejected. We seek to compute the probability $\mathbb{P}(X)$.

The inclusion-exclusion principle allows us to express $X$ in terms of the $X_i$, which will be useful because of the inherent symmetry present in the problem. Specifically, each $X_i$ has the same probability of occurrence! If we define the probabilities:
\begin{align}
S_1 &= \sum_{1\le i \le N} \mathbb{P}(X_i) \\
S_2 &= \sum_{1\le i\lt j\le N} \mathbb{P}(X_i \cap X_j) \\
&\,\,\,\vdots \\
S_k &= \sum_{1\le i_1 \lt\cdots\lt i_k\le n} \mathbb{P}(X_{i_1} \cap \cdots \cap X_{i_k})
\end{align}then the inclusion-exclusion principle states that:
\[
\mathbb{P}(X) = \sum_{k=1}^N (-1)^{k-1}S_k
\]We mentioned that the individual probabilities $\mathbb{P}(X_i)$ are easy to compute. Indeed, each color occurs with probability $1/d$ and there are $m^2$ cells in each patch. So the probability that all cells are of a particular color is $1/d^{m^2}$. Multiplying by $d$ to account for the $d$ possible colors, we obtain:
\[
\mathbb{P}(X_i) = \frac{1}{d^{m^2-1}}\qquad\text{for all }i
\]Therefore, $S_1 = N/d^{m^2-1}$. Setting $n=100,\,m=4,\,d=3$, we find:
\[
S_1 = 0.065573\%
\]To compute $S_2$, we must compute the probability of the intersection of two events, i.e. the probability that two patches are simultaneously mono-colored. There are two possibilities:
\[
\mathbb{P}(X_i \cap X_j) = \begin{cases}
\frac{1}{d^{2(m^2-1)}} & \begin{array}{l}\text{if the patches don’t overlap}\end{array}\\
\frac{1}{d^{c-1}} & \begin{array}{l}
\text{if the patches overlap and}\\
\text{together cover }c\text{ cells in total}
\end{array}
\end{cases}
\]This follows because when patches don’t overlap, the events are independent, so the probability that both patches are mono-colored is the product of probabilities that each is mono-colored. When the patches overlap, however, they can only both be mono-colored if they are both the same color! And here, the probability depends on how much the patches overlap. I wrote a simple script that loops over all pairs of patches, computes the above probabilities, and sums them up. The result was:
\[
S_2 = 0.0017071\%
\]We could continue in this fashion, computing $S_3,S_4,\dots$ but this is a hopeless endeavor as we must account for the probability that $k$ patches are simultaneously mono-colored… which will get messy in a hurry. Instead, we’ll use an additional piece to the inclusion-exclusion principle, called the Bonferroni inequality, which states that as we add and subtract the $S_k$ terms on our way to computing $\mathbb{P}(X)$, they alternate between providing upper and lower bounds!. This means that we can use $S_1$ and $S_2$ to compute an approximation:
\[
S_1-S_2 \le \mathbb{P}(X) \le S_1
\]Substituting the numbers we computed above, we obtain:

$\displaystyle
0.063866\% \lt \mathbb{P}(\text{rug is rejected}) \lt 0.065573\%
$

It’s reasonable to expect that $S_k$ will continue to decrease as $k$ increases. If we assume that the $S_k$ will decrease geometrically, that would give us $S_3 \approx 0.000044\%$, which would tighten our bound to $0.06387 \lt \mathbb{P}(X) \lessapprox 0.06391\%$. So if I had to guess a single number, it would be that the probability of rejection is about $0.0639\%$.

For the second part of the problem, we are asked about how many colors we should use in order to be ensured that we can manufacture one million rugs and have no rejections. Each rug is independently manufactured, so if we call $p$ the probability of one rug being rejected, the probability that no rugs get rejected after one million rugs are made is:
\[
\mathbb{P}(\text{no rejections}) = (1-p)^{1,000,000}
\]Since we don’t know the exact value of $p$, we can again compute upper and lower bounds. Since we want a conservative estimate of how many colors to use, it makes sense to under-estimate the probability of having no rejections. This amounts to using our upper bound for $p$. Here is a plot showing the probability of no rejections in the entire batch, as a function of $d$, the number of colors used.

Remember that these are lower bounds on the probability that no rugs get rejected. The true probability will be higher. Based on this fact, we’ll likely be safe if we pick $6$ colors.

Here are the probabilities in tabular form, and I also included the corresponding upper bound using the Bonferroni inequality discussed earlier.

Colors	lower bound on probability	upper bound on probability
$3$	$0$	$3.9\times 10^{-8}$
$4$	$0.01564\%$	$93.320\%$
$5$	$73.4684\%$	$99.901\%$
$6$	$98.0188\%$	$99.996\%$
$7$	$99.802\%$	$100\%$
$8$	$99.973\%$	$100\%$
$9$	$99.9954\%$	$100\%$
$10$	$99.9991\%$	$100\%$

The upper bound makes a big jump when we add a fourth color, and as discussed previously, this bound is likely the tighter of the two. So although we argued for 6 colors before, this is probably overly conservative and we could get away with using 5 colors.

A coin-flipping game

This Riddler puzzle involves a particular coin-flipping game. Here is the problem:

I flip a coin. If it’s heads, I’ve won the game. If it’s tails, then I have to flip again, now needing to get two heads in a row to win. If, on my second toss, I get another tails instead of a heads, then I now need three heads in a row to win. If, instead, I get a heads on my second toss (having flipped a tails on the first toss) then I still need to get a second heads to have two heads in a row and win, but if my next toss is a tails (having thus tossed tails-heads-tails), I now need to flip three heads in a row to win, and so on. The more tails you’ve tossed, the more heads in a row you’ll need to win this game.

I may flip a potentially infinite number of times, always needing to flip a series of N heads in a row to win, where N is T + 1 and T is the number of cumulative tails tossed. I win when I flip the required number of heads in a row.

What are my chances of winning this game? (A computer program could calculate the probability to any degree of precision, but is there a more elegant mathematical expression for the probability of winning?)

Here is my solution:
[Show Solution]

Nightmare Solitaire

This Riddler problem is a probability question about an old favorite: Solitaire!

While killing some time at your desk one afternoon, you fire up a new game of Solitaire (also called Klondike, and specifically the version where you deal out three cards from the deck at a time). But your boredom quickly turns to rage because your game is unplayable — you can flip through your deck, but you never have any legal moves! What are the odds?

Here is my solution:
[Show Solution]

I hope you’re in the mood for some counting! First, the basics: the deck contains 52 cards. Once we deal the cards, there are 7 face-up and 21 face-down. That leaves 24 cards in the deck. If we cycle through the deck 3 cards at a time and don’t play any of them, then we will see the same 8 cards over and over again. So whether a particular instance of Solitaire qualifies as “Nightmare” or not is completely characterized by the 7 face-up cards and the 8 deck cards we get to see.

To compute the probability of dealing a Nightmare game, we’ll count the number of Nightmare games and divide it by the total number of games. When counting, we can restrict our attention to possible choices of the 7+8 cards we see. Of course, the games will play out differently depending on the hidden cards, but these don’t matter for the purpose of counting Nightmare games. Let’s start with the denominator because that’s the easiest thing to calculate:

Total number of games

Since there are 52 total cards, we must choose 7 to be face-up and then choose 8 deck cards. Therefore, the total number of games is:
\[
N_\text{tot} = \binom{52}{7}\binom{52-7}{8} = \frac{52!}{7!\cdot 8!\cdot 37!} = 28,837,689,349,669,200
\]As mentioned earlier, we didn’t distinguish between games where the cards we see are the same but the hidden cards are different. You might be wondering why the total number of games isn’t just $\binom{52}{7+8}$. The reason is that the face-up cards and deck cards are not interchangeable. For example, if you have a face-up $3♣$ and a $\color{red}{4♥}$ in the deck, there are no legal moves. If instead you have a face-up $\color{red}{4♥}$ and a $3♣$ in the deck, you can play the 3 on the 4 when it comes up.

Counting nightmare games

This counting is a bit involved, so we’ll do it in steps. We can partition the cards into two groups:
\begin{align}
\text{Group }1:&\quad \left\{
\begin{array}{rrrrrr}
2♠ & 4♠ & 6♠ & 8♠ & 10♠ & \text{Q}♠ \\
\color{red}{3♥} & \color{red}{5♥} & \color{red}{7♥} & \color{red}{9♥} & \color{red}{\text{J}♥} & \color{red}{\text{K}♥} \\
2♣ & 4♣ & 6♣ & 8♣ & 10♣ & \text{Q}♣ \\
\color{red}{3♦} & \color{red}{5♦} & \color{red}{7♦} & \color{red}{9♦} & \color{red}{\text{J}♦} & \color{red}{\text{K}♦}
\end{array}\right\} \\[3mm]
\text{Group }2:&\quad \left\{
\begin{array}{rrrrrr}
3♠ & 5♠ & 7♠ & 9♠ & \text{J}♠ & \text{K}♠ \\
\color{red}{2♥} & \color{red}{4♥} & \color{red}{6♥} & \color{red}{8♥} & \color{red}{10♥} & \color{red}{\text{Q}♥} \\
3♣ & 5♣ & 7♣ & 9♣ & \text{J}♣ & \text{K}♣ \\
\color{red}{2♦} & \color{red}{4♦} & \color{red}{6♦} & \color{red}{8♦} & \color{red}{10♦} & \color{red}{\text{Q}♦}
\end{array}\right\}
\end{align}These groups were chosen in a particular way: cards from each group can only be played on other cards from the same group. For example, $\color{red}{6♥}$, which is in Group 2, can only be played on $7♠$ or $7♣$, which are also in Group 2. Cards from the two groups never interact with one another. The four aces have been left out because any visible ace (either face-up or in the deck) is always playable. Let’s take it one step at a time.

A 12-card deck, face-up only. Let’s start with a simpler problem. What if the deck only consisted of the top half of Group 1, namely:
\[
\text{Mini-deck}:\quad \left\{
\begin{array}{rrrrrr}
2♠ & 4♠ & 6♠ & 8♠ & 10♠ & \text{Q}♠ \\
\color{red}{3♥} & \color{red}{5♥} & \color{red}{7♥} & \color{red}{9♥} & \color{red}{\text{J}♥} & \color{red}{\text{K}♥}
\end{array}\right\}
\]In this $n$-card deck ($n=12$), how many ways can we choose $k$ face-up cards so that there are no moves available? This is a classic “stars and bars” problem. This is equivalent to counting the subsets of size $k$ such that no two adjacent cards are picked. Since we are choosing $k$ cards, we must exclude $k-1$ buffer cards in between the chosen cards. Therefore, there are $f(n,k) = \binom{n-k+1}{k}$ possible choices.

12-card deck, full version. Using the same mini-deck as above, let’s ask a harder question: How many ways can we choose $k$ face-up cards and $p$ deck cards so that there are no moves available? This is a bit trickier. A card in the deck is playable precisely when it is one less than one of the face-up cards. However, the number of cards that are one less depends on whether we have a face-up $2$ or not (since our deck has no aces). So let’s distinguish two cases:

We have a face-up $2$, which means we can’t use a face-up $3$ either. There are therefore $f(n-2,k-1) = \binom{n-k}{k-1}$ possible choices. There are also $k-1$ cards that are one less than the face-up cards. We must therefore choose our $p$ deck cards from the remaining $n-k-(k-1)$ cards.
We do not have a face-up $2$. There are $f(n-1,k) = \binom{n-k}{k}$ possible choices. There are also $k$ cards that are one less than the face-up cards we chose. We must therefore choose our $p$ deck cards from the remaining $n-2k$ cards.

So in total, there are $\binom{n-k}{k-1}\binom{n-2k+1}{p}+\binom{n-k}{k}\binom{n-2k}{p}$ ways of choosing our $k$ face-up cards and $p$ deck cards in the mini-deck case.

Group 1 deck, full version. Let’s expand our deck to include all the cards from Group 1. Again, we want to pick $k$ face-up cards and $p$ deck cards such that no moves are possible. Let $m$ be how many different card numbers we use (e.g. if we only use 2’s and 6’s, then $m=2$). This is similar to the mini-deck case, except now we’re picking how many different card numbers there will be, and then picking the cards themselves. For example, if we have a face-up $2$, then there are $f(n-2,m-1) = \binom{n-m}{m-1}$ possible choices of for the card numbers. To pick the cards themselves, we must choose $k$ cards from $m$ groups of $2$, with at least one card picked per group. There are $\binom{m}{k-m}$ ways of picking the cards if the cards in each group are indistinguishable, but since they are not, we must also multiply by $2$ for each group that only had one card picked, i.e. $m-(k-m)$. Now for the $p$ deck cards… There were $m$ groups picked (including the groups of two), which means $m-1$ groups are forbidden. They have $2$ cards each, so that’s $2m-2$ cards we can’t use. We started with $2n$ cards and we picked $k$ already. This means we must choose the $p$ deck cards from the remaining $2n-(2m-2)-k$. Putting everything together and including the case with no face-up $2$s, we have:
\begin{multline}
g(n,k,p) = \sum_{m=0}^k \left[ \binom{n-m}{m-1}\binom{2n-2m-k+2}{p}\right.\\
+\left.\binom{n-m}{m}\binom{2n-2m-k}{p} \right] \binom{m}{k-m} 2^{2m-k}
\end{multline}The reason we’re summing over $m$ is because we must account for every possible number of card distinct card number, which naturally can’t exceed $k$. Here, binomial coefficients are being interpreted in the combinatorial sense, so we’re using the convention that $\binom{a}{b} = 0$ if $a\lt 0$, $b\lt 0$, or $b\gt a$.

The full deck. For the full deck, it turns out most of the work has already been done! When combining the cards from Group 1 and Group 2, they don’t ever interact with one another. So ultimately, we just need to decide how many cards from each of the groups we should include in the face-up and deck cards so there are 7 and 8 in total, respectively. The net result is:
\begin{align}
N_\text{nightmare} &= \sum_{i=0}^7 \sum_{j=0}^8 g(12,i,j)\cdot g(12,7-i,8-j) \\
&= 72,099,595,172,416
\end{align}

Taking the ratio $\frac{N_\text{nightmare}}{N_\text{total}}$ and simplifying we obtain our final answer:

$\displaystyle
\mathbb{P}(\text{nightmare game}) = \frac{643746385468}{257479369193475} \approx 0.25\%
$

To get an idea for the size of this number, here is a plot that shows the probability of having had at least one nightmare game given that you’ve played $N$ games in total. In other words, if $p$ is the probability of having a nightmare game, this is a plot of $1-(1-p)^N$.

You would have to play roughly 277 games of solitaire so that the probability of having encountered at least one nightmare game is 50%.

Bonus: alternative rules

If instead we play the variant of Solitaire where you flip only one card at a time, then we can compute the probability of a nightmare game using the same tools as above. The only difference is that we have $24$ deck cards rather than $8$. The probability of a nightmare game using these rules is:
\begin{align}
&\hspace{-1cm}\mathbb{P}(\text{nightmare game, 1-card variant}) \\
&= \frac{ \sum_{i=0}^7 \sum_{j=0}^{24} g(12,i,j)\cdot g(12,7-i,24-j) }{ \binom{52}{7}\binom{52-7}{24} } \\
&= 1.77016\times 10^{-7}
\end{align}The probability is much smaller for this 1-card variant because we see so much more of the deck; a lot more has to “go wrong” to have a nightmare scenario. Here is what the graph looks like for the 1-card variant; it looks similar to the 3-card graph, but shifted far to the right ($N$ is much larger).

To put this in context, when you go from the 3-card variant to the 1-card variant, nightmare games are $14,\!100$ times more unlikely.

The Dodgeball duel

This is a game theory problem from the Riddler. Three dodgeball players, who survives?

Three expert dodgeballers engage in a duel — er, a “truel” — where they all pick up a ball simultaneously and attempt to hit one of the others. Any survivors then immediately start over, attempting to hit each other again. They are equally fast but unequally accurate. Name them Abbott, Bob and Costello. Each has an accuracy of a, b and c, respectively. That is, if Abbott aims at something, he hits it with probability a, Bob with probability b and Costello with probability c. The abilities of each player are known by the others. Let’s say Abbott is a perfect shot: a = 1. Suppose the players follow an optimal strategy, with the goal being survival. Which player, for every possible combination of Bob and Costello’s abilities (b and c), is favored to survive this truel?

Here is my solution:
[Show Solution]

Before I begin, I’d like to thank commenters Guy Moore and Jason Weisman for sharing their own solutions and for pointing out a different way of interpreting the problem. The “Random-ball” variant is due to Guy Moore. Ok, here we go…

What is a solution, anyway?

The problem talks about “optimal strategies”, so it’s worth discussing what this means so we’re all on the same page. An optimal strategy is a Nash equilibrium. It’s a set of strategies for each player such that if any one player changed their strategy (while the others held their strategies fixed), it would result in a worse outcome for that player. Hence, no player has any incentive to change their strategy.

A strategy is a rule that tells you what to do based on what you observe. In this game, an example of a strategy would be “always aim to hit the remaining player with the best accuracy”. This is an example of a pure strategy because each player always behaves the same way no matter what they observe. Not every game is guaranteed to have a Nash equilibrium consisting of pure strategies. In some games, such as rock-paper-scissors, it’s optimal to use a mixed strategy. That is, a probabilistic strategy such as “pick rock paper or scissors randomly and with equal probability”. If you used a pure strategy in rock-paper-scissors, your opponents would counter you and you would lose every time!

It turns out that every finite game has at least one mixed Nash equilibrium. So we need not worry about the case where there is no optimal solution. That being said, it’s entirely possible for there to exist many Nash equilibria! So we shouldn’t be surprised if this turns out to be the case…

Murder-ball vs Coinflip-ball vs Random-ball

There are at least three ways of interpreting the problem. In the first interpretation, if two players target each other and hit, then both players are eliminated. I’ll call this variant “Murder-ball”. In Murder-ball, it’s possible for nobody to win! The second interpretation is that whenever two players hit each other, we should flip a coin and the loser of the coin flip gets eliminated. We also flip a 3-way coin to deal with the case where all three players would be simultaneously eliminated. I’ll call this “Coinflip-ball”. Finally, we could interpret the game as having a randomly chosen shooting order for the players. I’ll call this variant “Random-ball”. In Random-ball, if A hits B and B hits C, but the order is such that A shoots first, then B gets eliminated before shooting C and C survives. All these variants have different solutions!

Two players

Let’s start by considering the case with only two players $P$ and $Q$; a duel! In this case, there are no decisions to make. The players always target each other. Suppose the two players have probabilities of $p$ and $q$ to hit each other, respectively, and we want to figure out the probability that either player will win the duel. In Murder-ball, Player $P$ can only win if he hits $Q$ and $Q$ misses $P$. The probability of this occurring is $p(1-q)$. But if both players miss (probability $(1-p)(1-q)$) then the game repeats. So the chance that $P$ is the ultimate winner is:
\begin{align}
\mathbb{P}_P &= p(1-q)\biggl(1+(1-p)(1-q)+(1-p)^2(1-q)^2+\cdots\biggr) \\
&= \frac{p(1-q)}{1-(1-p)(1-q)}
\end{align}Repeating a similar argument for the other player, we find the probabilities of interest are:
\begin{gather}
\mathbb{P}_P = \frac{p(1-q)}{1-(1-p)(1-q)},
\qquad
\mathbb{P}_Q = \frac{(1-p)q}{1-(1-p)(1-q)}, \\
\qquad
\mathbb{P}_0 = \frac{pq}{1-(1-p)(1-q)}.
\end{gather}Here, $\mathbb{P}_0$ is the probability that the two players simultaneously hit each other, so nobody wins. Naturally, the three probabilities above sum to $1$.

In Coinflip-ball and Random-ball, Player $P$ can also win if both players hit each other but he wins the coin flip. It turns out that in this case, it’s impossible for nobody to win, and $\mathbb{P}_0$ from the solution above gets split evenly between both players.

Three players

I will solve the Murder-ball case in detail. With three players, each has a choice of who to target. We will make no assumptions about the nature of the strategies used, and we will allow for the possibility of using a mixed strategy. An example of a mixed strategy would be “Player $A$ should target $B$ with probability $0.4$ and $C$ with probability $0.6$”. In some games, such as rock-paper-scissors, it’s optimal to use a mixed strategy because if you always did the same thing, your opponents would realize this and you would lose every time! So, let’s define the numbers $x,y,z$ as follows:
\begin{align}
&A\text{ targets }B\text{ with prob }x\text{ and targets }C\text{ with prob }(1-x)\\
&B\text{ targets }C\text{ with prob }y\text{ and targets }A\text{ with prob }(1-y)\\
&C\text{ targets }A\text{ with prob }z\text{ and targets }B\text{ with prob }(1-z)
\end{align}We can compute the probabilities that any player will win by enumerating the possible ways it can happen. I’ll give one example to illustrate. To compute the probability that $A$ wins, it can happen in two main ways:

$B$ and $C$ are eliminated simultaneously and $A$ survives. This can happen in three ways. Either $B$ and $C$ hit each other, or $B$ hits $C$ and $A$ hits $B$, or $C$ hits $B$ and $A$ hits $C$. We can also have everybody survive for some number of rounds first! The total probability is:
\[
\frac{a b (1-c) x y + a (1-b) c (1-x) (1-z) + b c y (1-z)}{1-(1-a)(1-b)(1-c)}
\]
$B$ is eliminated first, and then $A$ wins the duel with $C$ (a case we already solved with $p$ and $q$ above). In any case, $B$ must miss his shot. Either $A$ and $C$ both target $B$ and at least one of them hits, or only one of them targets $B$ and the other misses. The total probability in this case is:
\[
\frac{a(1-c)}{1-(1-a)(1-c)} \frac{(1-b)\left(a (1-c) x + (1-a) c (1-z) + a c x (1-z)\right)}{1-(1-a)(1-b)(1-c)}
\]
$C$ is eliminated first, and then $A$ wins the duel with $B$. This case is similar to the previous one and the total probability is:
\[
\frac{a(1-b)}{1-(1-a)(1-b)} \frac{(1-c)\left(a (1-b) (1-x) + (1-a) b y + a b (1-x) y\right)}{1-(1-a)(1-b)(1-c)}
\]

Summing the three probabilities above, we get $\mathbb{P}_A$, the probability that $A$ wins. We can do a similar computation to get the probability that $B$ wins, that $C$ wins, and that nobody wins (all four probabilities will sum to $1$). By symmetry, the formula for $\mathbb{P}_B$ can be obtained by just cyclically permuting all variables: $a\to b\to c \to a$ and $x \to y \to z \to x$. Finally, the probability that nobody wins is such that all four probabilities sum to one: $\mathbb{P}_0 =1-\mathbb{P}_A-\mathbb{P}_B-\mathbb{P}_C$.

Murder-ball optimal strategies

We now have the probabilities that each player wins, and these are the functions:
\[
\mathbb{P}_A(x,y,z),\quad \mathbb{P}_B(x,y,z),\quad \mathbb{P}_C(x,y,z).
\]Each function is parameterized by $a,b,c$, the accuracy of each player, and is a function of $(x,y,z)$, the (mixed) strategy being used. Our goal is to find a choice of $(x,y,z)$ such that no change in $x$ alone can improve $\mathbb{P}_A$, no change in $y$ alone can improve $\mathbb{P}_B$, and no change in $z$ alone can improve $\mathbb{P}_C$. A key observation that will help us solve the problem is that all three functions are linear in $x$, $y$, and $z$ separately. When optimizing a linear function, the maximum always occurs at a boundary. This implies that there must exist pure Nash equilibria!!! So we can restrict our search to cases where $x$, $y$, and $z$ are each $0$ or $1$. So there are 8 strategies in total.

I computed the Nash equilibria via an exhaustive search. For each value of $(a,b,c)$, I computed the values of $(\mathbb{P}_A,\mathbb{P}_B,\mathbb{P}_C)$ for all 8 strategies, tried changing $(x,y,z)$ for each one to see if it was a Nash equilibrium, and if I found multiple Nash equilibria, I chose one at random. Then, I made a plot illustrating who wins when. When $a=1$, we obtain the following picture:

What a mess! There are many Nash equilibria here, and pretty much anything can happen. The reason is that without a coinflip, the player targeted by Abbott will always lose. So, in fact, anything that player does is optimal! That losing player has a big effect on which remaining player wins, and hence the messy solutions. However, these Nash equilibria are mostly unstable. That is, if we change Abbott’s accuracy to $a=0.99$, the picture changes completely:

Coinflip-ball optimal strategies

I will omit the derivations for Coinflip-ball because the algebra is quite lengthy and tedious to write out, but the idea is similar in spirit to how I derived the probabilities for the Murder-ball variant. As in the Murder-ball case, all probabilities are linear in $(x,y,z)$, so once again, pure Nash equilibria must exist. As above, I used an exhaustive search to plot the probability of winning for each player. Here is what I obtained in the case where $a=1$.

For most of the cases, the strategies are obvious. For example, when $b=0.8$ and $c=0.5$, the optimal strategy is for Abbott and Bob to target each other and for Costello to target Abbott. In this case, it turns out Costello wins most of the time! In the top right corner, you’ll notice that there is a mixture of possible outcomes because there are multiple Nash equilibria there. In that region, all three players are highly accurate and the strategy of ganging up on Abbott is no longer optimal. In this regime, it’s Nash-optimal for the three players to target each other in a chain (A to B to C to A) or (A to C to B to A). This is a result of the rules of the game. In my interpretation of Coinflip-ball, if all three players hit each other simultaneously, the outcome of the game is decided by a coin flip where each player has an equal chance to win.

Random-ball optimal strategies

Again, I omit the derivation. This case yields a solution similar to the other two, where pure Nash equilibria always exist. However, in this case, it’s even nicer: the Nash equilibria are unique! This means there is an unambiguous best strategy for all players. Here is what I obtained in the case where $a=1$.

The uniqueness of the Nash equilibria is reflected in the fact that every region is solid; there is no overlap anywhere.

Inaccurate Abbott

Of course, I had to see what would happen in the case where Abbott is not perfectly accurate. Prepare to have your mind blown…

Here is the case of Coinflip-ball:

You’ll notice that when $a=0$ the optimal solution is just split along the line $b=c$, where the more accurate player wins. This makes sense; Abbott will always lose no matter what he does so it’s up to the remaining two players to duke it out.

Here is the case of Murder-ball:

This time, in the case $a=0$, Bob and Costello are not threatened by Abbott so they target each other. If both Bob and Costello are very accurate, then there is a good chance that they eliminate each other, and in this case Abbott wins!

Finally, here is the case of Random-ball:

Inscribed triangles and tetrahedra

The following problems appeared in The Riddler. They involve randomly picking points on a circle or sphere and seeing if the resulting shape contains the center or not.

Problem 1: Choose three points on a circle at random and connect them to form a triangle. What is the probability that the center of the circle is contained in that triangle?

Problem 2: Choose four points at random (independently and uniformly distributed) on the surface of a sphere. What is the probability that the tetrahedron defined by those four points contains the center of the sphere?

Here is my solution to both problems:
[Show Solution]

This problem also appeared as Problem A-6 in the 1992 William Lowell Putnam math competition. After writing this blog post, I also discovered an amazing video about this problem by @3Blue1Brown. The video is exceptionally clear and well-produced; I highly recommend it! The solution I present below is similar to the one in the video, except that I also included a section at the end that provides more mathematical details.

Both the 2D and 3D versions of the problem can be solved in a similar fashion, using the same key observation. I will point out this observation and then prove it mathematically. We’ll start with the first problem because it’s a bit simpler, but the logic is the same for both.

Problem 1: triangle and circle

Instead of picking three points on the circle at random, the symmetry in the problem allows us (without any loss of generality) to fix the first point and then pick the remaining two uniformly at random. Let’s suppose that the first point is fixed to be at the top of the circle. For the two remaining points, each one has a “mirror point” that lies directly opposite it on the other side of the circle. In mathspeak, a point and its mirror point are said to be diametrically opposed.

Since the points on the circle are chosen uniformly at random, each point is as likely to be chosen as its diametrically opposed counterpart. Therefore, instead of picking the remaining two points uniformly at random, we’ll do the following equivalent thing:

Pick two lines through the center of the circle uniformly at random.
For each line, pick one of its two endpoints at random.

For each choice of two diameters ($BB’$ and $CC’$), there are four possible triangles we can make depending on which endpoints of the diameters are chosen: $ABC$, $AB’C$, $ABC’$, and $AB’C’$. Here is a diagram illustrating the choices of triangles.

One of the four triangles contain the center point $O$. This is no accident! No matter which two diameters $BB’$ and $CC’$ we select, exactly one of the four resulting triangles will contain the center point $O$ almost surely. Moreover, each of these four triangles is equally likely because each choice of endpoint ($B$ or $B’$ and $C$ or $C’$) is equally likely. It follows that the probability that the triangle will contain the center point $O$ is $\frac{1}{4}$.

Problem 2: tetrahedron and sphere

For this problem, we can apply the exact same logic as in the 2D case: fix one point to be at the top of the sphere and select the remaining three points by first picking three diameters at random, and then for each diameter choosing one of its endpoints at random. Once again, it turns out that exactly one of the 8 possible tetrahedra will contain the center of the sphere. Each triangle is equally likely, so the probability that the random tetrahedron contains the center of the sphere is $\frac{1}{8}$.

Mathematical proof

The results above rely on the observation that exactly one of the 4 triangles (in the 2D case) or one of the 8 tetrahedra (in the 3D case) contains the center of the circle or sphere. We will now prove this fact more rigorously by using the notion of barycentric coordinates. Suppose the vertices of the tetrahedron are located at $\vec{p}$, $\vec{q}$, $\vec{r}$, $\vec{s}$. Given a point $\vec{x}$ (not necessarily on the surface of the sphere), we can represent it as a linear combination:
\[
\vec{x} = \lambda_1 \vec{p} + \lambda_2 \vec{q} + \lambda_3 \vec{r} + \lambda_4 \vec{s}
\]The quadruple $(\lambda_1,\lambda_2,\lambda_3,\lambda_4)$ are the barycentric coordinates of $\vec{x}$ with respect to the tetrahedron. This representation is not unique, but it becomes unique if we add a normalizing constraint such as $\lambda_1+\lambda_2+\lambda_3+\lambda_4=1$. A key property of barycentric coordinates is that $\vec{x}$ lies inside the tetrahedron if and only if all coordinates have the same sign. The reason is that the interior of the tetrahedron is also the convex hull of its vertices.

We can use the property above to solve our problem. Let $\vec{o}$ be the center of the sphere and suppose it’s located at the origin. This means that the point diametrically opposed to any point $\vec{y}$ is simply $-\vec{y}$. As before, we’ll fix $\vec{p}$. The 8 possible (equally likely) tetrahedra are formed by using the vertices:
\[
\vec{p}
\quad\text{and}\quad
(\vec{q}\text{ or }-\vec{q})
\quad\text{and}\quad
(\vec{r}\text{ or }-\vec{r})
\quad\text{and}\quad
(\vec{s}\text{ or }-\vec{s})
\]We want to test whether $\vec{x}=\vec{o}$ is inside the tetrahedron or not. Therefore, the 8 equations we should solve for the 8 possible tetrahedra are:
\begin{align}
\vec{o} &= \lambda_1 \vec{p}+\lambda_2 \vec{q}+\lambda_3 \vec{r}+\lambda_4 \vec{s}, &
\vec{o} &= \lambda_1 \vec{p}+\lambda_2 \vec{q}+\lambda_3 \vec{r}-\lambda_4 \vec{s}, \\
\vec{o} &= \lambda_1 \vec{p}+\lambda_2 \vec{q}-\lambda_3 \vec{r}+\lambda_4 \vec{s}, &
\vec{o} &= \lambda_1 \vec{p}+\lambda_2 \vec{q}-\lambda_3 \vec{r}-\lambda_4 \vec{s}, \\
\vec{o} &= \lambda_1 \vec{p}-\lambda_2 \vec{q}+\lambda_3 \vec{r}+\lambda_4 \vec{s}, &
\vec{o} &= \lambda_1 \vec{p}-\lambda_2 \vec{q}+\lambda_3 \vec{r}-\lambda_4 \vec{s}, \\
\vec{o} &= \lambda_1 \vec{p}-\lambda_2 \vec{q}-\lambda_3 \vec{r}+\lambda_4 \vec{s}, &
\vec{o} &= \lambda_1 \vec{p}-\lambda_2 \vec{q}-\lambda_3 \vec{r}-\lambda_4 \vec{s}.
\end{align}But these equations have very similar solutions! Indeed, if $(\lambda_1,\lambda_2,\lambda_3,\lambda_4)$ solves the first equation, then the solutions to the equations above are:
\begin{align}
&(\lambda_1,\lambda_2,\lambda_3,\lambda_4), &
&(\lambda_1,\lambda_2,\lambda_3,-\lambda_4), \\
&(\lambda_1,\lambda_2,-\lambda_3,\lambda_4), &
&(\lambda_1,\lambda_2,-\lambda_3,-\lambda_4), \\
&(\lambda_1,-\lambda_2,\lambda_3,\lambda_4), &
&(\lambda_1,-\lambda_2,\lambda_3,-\lambda_4), \\
&(\lambda_1,-\lambda_2,-\lambda_3,\lambda_4), &
&(\lambda_1,-\lambda_2,-\lambda_3,-\lambda_4),
\end{align}respectively. It’s clear that exactly one of these quadruples has all entries with the same sign. In other words, exactly one of the 8 tetrahedra contains the center of the sphere. The argument above also works in the 2D case using a similar notion of 2D barycentric coordinates.

Tag: probability

Elf music

Beer pong

Hand sort

Numerical results

Card collection completion

Simpler version: packs of one

Full version: multi-packs

Numerical solutions

Hoop hop showdown

Rug quality control

A coin-flipping game

Nightmare Solitaire

Total number of games

Counting nightmare games

Bonus: alternative rules

Other solutions

The Dodgeball duel

What is a solution, anyway?

Murder-ball vs Coinflip-ball vs Random-ball

Two players

Three players

Murder-ball optimal strategies

Coinflip-ball optimal strategies

Random-ball optimal strategies

Inaccurate Abbott

Inscribed triangles and tetrahedra

Problem 1: triangle and circle

Problem 2: tetrahedron and sphere

Mathematical proof