In combinatorics, Vandermonde's identity (or Vandermonde's convolution) is the following identity for binomial coefficients:

for any nonnegative integers r, m, n. The identity is named after Alexandre-Théophile Vandermonde (1772), although it was already known in 1303 by the Chinese mathematician Zhu Shijie.[1]

There is a q-analog to this theorem called the q-Vandermonde identity.

Vandermonde's identity can be generalized in numerous ways, including to the identity

Proofs

edit

Algebraic proof

edit

In general, the product of two polynomials with degrees m and n, respectively, is given by

 

where we use the convention that ai = 0 for all integers i > m and bj = 0 for all integers j > n. By the binomial theorem,

 

Using the binomial theorem also for the exponents m and n, and then the above formula for the product of polynomials, we obtain

 

where the above convention for the coefficients of the polynomials agrees with the definition of the binomial coefficients, because both give zero for all i > m and j > n, respectively.

By comparing coefficients of xr, Vandermonde's identity follows for all integers r with 0 ≤ r ≤ m + n. For larger integers r, both sides of Vandermonde's identity are zero due to the definition of binomial coefficients.

Combinatorial proof

edit

Vandermonde's identity also admits a combinatorial double counting proof, as follows. Suppose a committee consists of m men and n women. In how many ways can a subcommittee of r members be formed? The answer is

 

The answer is also the sum over all possible values of k, of the number of subcommittees consisting of k men and r − k women:

 

Geometrical proof

edit

Take a rectangular grid of r x (m+nr) squares. There are

 

paths that start on the bottom left vertex and, moving only upwards or rightwards, end at the top right vertex (this is because r right moves and m+n-r up moves must be made (or vice versa) in any order, and the total path length is m + n). Call the bottom left vertex (0, 0).

There are   paths starting at (0, 0) that end at (k, mk), as k right moves and mk upward moves must be made (and the path length is m). Similarly, there are   paths starting at (k, mk) that end at (r, m+nr), as a total of rk right moves and (m+nr) − (mk) upward moves must be made and the path length must be rk + (m+nr) − (mk) = n. Thus there are

 

paths that start at (0, 0), end at (r, m+nr), and go through (k, mk). This is a subset of all paths that start at (0, 0) and end at (r, m+nr), so sum from k = 0 to k = r (as the point (k, mk) is confined to be within the square) to obtain the total number of paths that start at (0, 0) and end at (r, m+nr).

Generalizations

edit

Generalized Vandermonde's identity

edit

One can generalize Vandermonde's identity as follows:

 

This identity can be obtained through the algebraic derivation above when more than two polynomials are used, or through a simple double counting argument.

On the one hand, one chooses   elements out of a first set of   elements; then   out of another set, and so on, through   such sets, until a total of   elements have been chosen from the   sets. One therefore chooses   elements out of   in the left-hand side, which is also exactly what is done in the right-hand side.

Chu–Vandermonde identity

edit

The identity generalizes to non-integer arguments. In this case, it is known as the Chu–Vandermonde identity (see Askey 1975, pp. 59–60) and takes the form

 

for general complex-valued s and t and any non-negative integer n. It can be proved along the lines of the algebraic proof above by multiplying the binomial series for   and   and comparing terms with the binomial series for  .

This identity may be rewritten in terms of the falling Pochhammer symbols as

 

in which form it is clearly recognizable as an umbral variant of the binomial theorem (for more on umbral variants of the binomial theorem, see binomial type). The Chu–Vandermonde identity can also be seen to be a special case of Gauss's hypergeometric theorem, which states that

 

where   is the hypergeometric function and   is the gamma function. One regains the Chu–Vandermonde identity by taking a = −n and applying the identity

 

liberally.

The Rothe–Hagen identity is a further generalization of this identity.

The hypergeometric probability distribution

edit

When both sides have been divided by the expression on the left, so that the sum is 1, then the terms of the sum may be interpreted as probabilities. The resulting probability distribution is the hypergeometric distribution. That is the probability distribution of the number of red marbles in r draws without replacement from an urn containing n red and m blue marbles.

See also

edit

References

edit
  1. ^ See Askey, Richard (1975), Orthogonal polynomials and special functions, Regional Conference Series in Applied Mathematics, vol. 21, Philadelphia, PA: SIAM, pp. 59–60 for the history.