A Faster Approximation Algorithm for the Gibbs Partition Function

Abstract

We consider the problem of estimating the partition function Z(β)=Σx (-β(H(x)) of a Gibbs distribution with a Hamilton H(·), or more precisely the logarithm of the ratio q= Z(0)/Z(β). It has been recently shown how to approximate q with high probability assuming the existence of an oracle that produces samples from the Gibbs distribution for a given parameter value in [0,β]. The current best known approach due to Huber [9] uses O(q n·[ q + n+-2]) oracle calls on average where is the desired accuracy of approximation and H(·) is assumed to lie in \0\[1,n]. We improve the complexity to O(q n·-2) oracle calls. We also show that the same complexity can be achieved if exact oracles are replaced with approximate sampling oracles that are within O(2q n) variation distance from exact oracles. Finally, we prove a lower bound of (q· -2) oracle calls under a natural model of computation.