Contract bridge probabilities

Let ${\displaystyle P'(a,b,n_{e},n_{w})}$ be the probability of an East player with ${\displaystyle n_{e}}$ unknown cards holding ${\displaystyle a}$ cards in a given suit and a West player with ${\displaystyle n_{w}}$ unknown cards holding ${\displaystyle b}$ cards in the given suit. The total number of arrangements of ${\displaystyle (a+b)}$ cards in the suit in ${\displaystyle (n_{e}+n_{w})}$ spaces is ${\displaystyle T={\frac {(n_{e}+n_{w})!}{(n_{e}+n_{w}-a-b)!(a+b)!}}}$ i.e. the number of permutations of ${\displaystyle (n_{e}+n_{w})}$ objects of which cards in the suit are indistinguishable and cards not in the suit are indistinguishable. The number of arrangements of which correspond to East having ${\displaystyle a}$ cards in the suit and West ${\displaystyle b}$ cards in the suit is given by ${\displaystyle S={\frac {n_{e}!}{a!(n_{e}-a)!}}\times {\frac {n_{w}!}{b!(n_{w}-b)!}}}$. Therefore,

$${\displaystyle P'(a,b,n_{e},n_{w})={\frac {S}{T}}={\frac {(a+b)!}{a!b!}}\times {\frac {n_{e}!n_{w}!(n_{e}+n_{w}-a-b)!}{(n_{e}+n_{w})!(n_{e}-a)!(n_{w}-b)!}}={\binom {a+b}{a}}{\frac {n_{e}!n_{w}!(n_{e}+n_{w}-a-b)!}{(n_{e}+n_{w})!(n_{e}-a)!(n_{w}-b)!}}={\frac {{\binom {a+b}{a}}{\binom {n_{e}+n_{w}-a-b}{n_{e}-a}}}{\binom {n_{e}+n_{w}}{n_{e}}}}}$$

If the direction of the split is unimportant (it is only required that the split be ${\displaystyle a}$-${\displaystyle b}$, not that East is specifically required to hold ${\displaystyle a}$ cards), then the overall probability is given by

$${\displaystyle P(a,b,n_{e},n_{w})=P'(a,b,n_{e},n_{w})+(1-\delta _{a,b})P'(b,a,n_{e},n_{w})}$$

where the Kronecker delta ensures that the situation where East and West have the same number of cards in the suit is not counted twice. The above probabilities assume ${\displaystyle n_{e}=n_{w}=13}$ and that the direction of the split is unimportant, and so are given by

$${\displaystyle P(a,b)=P(a,b,13,13)={\binom {a+b}{a}}{\frac {13!13!(26-a-b)!}{26!(13-a)!(13-b)!}}(2-\delta _{a,b})}$$

The more general formula can be used to calculate the probability of a suit breaking if a player is known to have cards in another suit from e.g. the bidding. Suppose East is known to have 7 spades from the bidding and after seeing dummy you deduce West to hold 2 spades; then if your two lines of play are to hope either for diamonds 5-3 or clubs 4-2, the a priori probabilities are 47% and 48% respectively but ${\displaystyle P(5,3,13-7,13-2)\thickapprox 42\%}$ and ${\displaystyle P(4,2,13-7,13-2)\thickapprox 47\%}$ so now the club line is significantly better than the diamond line.