In mathematics, Pascal's rule (or Pascal's formula) is a combinatorialidentity about binomial coefficients. It states that for positive natural numbersn and k, where is a binomial coefficient; one interpretation of the coefficient of the xk term in the expansion of (1 + x)n. There is no restriction on the relative sizes of n and k,[1] since, if n < k the value of the binomial coefficient is zero and the identity remains valid.
Pascal's rule can also be viewed as a statement that the formula solves the linear two-dimensional difference equation over the natural numbers. Thus, Pascal's rule is also a statement about a formula for the numbers appearing in Pascal's triangle.
Pascal's rule has an intuitive combinatorial meaning, that is clearly expressed in this counting proof.[2]: 44
Proof. Recall that equals the number of subsets with k elements from a set with n elements. Suppose one particular element is uniquely labeled X in a set with n elements.
To construct a subset of k elements containing X, include X and choose k − 1 elements from the remaining n − 1 elements in the set. There are such subsets.
To construct a subset of k elements not containing X, choose k elements from the remaining n − 1 elements in the set. There are such subsets.
Every subset of k elements either contains X or not. The total number of subsets with k elements in a set of n elements is the sum of the number of subsets containing X and the number of subsets that do not contain X, .
Pascal's rule can be generalized to multinomial coefficients.[2]: 144 For any integerp such that , and , where is the coefficient of the term in the expansion of .
The algebraic derivation for this general case is as follows.[2]: 144 Let p be an integer such that , and . Then