Asymptotic enumeration of sparse nonnegative integer matrices with specified row and column sums

Abstract

Let = (s1,...,sm) and = (t1,...,tn) be vectors of nonnegative integer-valued functions of m,n with equal sum S = sumi=1m si = sumj=1n tj. Let M(,) be the number of m*n matrices with nonnegative integer entries such that the i-th row has row sum si and the j-th column has column sum tj for all i,j. Such matrices occur in many different settings, an important example being the contingency tables (also called frequency tables) important in statistics. Define s=maxi si and t=maxj tj. Previous work has established the asymptotic value of M(,) as m,n∞ with s and t bounded (various authors independently, 1971-1974), and when , are constant vectors with m/n,n/m,s/n >= c/log n for sufficiently large (Canfield and McKay, 2007). In this paper we extend the sparse range to the case st=o(S(2/3)). The proof in part follows a previous asymptotic enumeration of 0-1 matrices under the same conditions (Greenhill, McKay and Wang, 2006). We also generalise the enumeration to matrices over any subset of the nonnegative integers that includes 0 and 1.