Origins of the Combinatorial Basis of Entropy

Abstract

The combinatorial basis of entropy, given by Boltzmann, can be written H = N-1 W, where H is the dimensionless entropy, N is the number of entities and W is number of ways in which a given realization of a system can occur (its statistical weight). This can be broadened to give generalized combinatorial (or probabilistic) definitions of entropy and cross-entropy: H= (φ(W) +C) and D=- (φ(P) +C), where P is the probability of a given realization, φ is a convenient transformation function, is a scaling parameter and C an arbitrary constant. If W or P satisfy the multinomial weight or distribution, then using φ(·)=(·) and =N-1, H and D asymptotically converge to the Shannon and Kullback-Leibler functions. In general, however, W or P need not be multinomial, nor may they approach an asymptotic limit. In such cases, the entropy or cross-entropy function can be defined so that its extremization ("MaxEnt'' or "MinXEnt"), subject to the constraints, gives the ``most probable'' (``MaxProb'') realization of the system. This gives a probabilistic basis for MaxEnt and MinXEnt, independent of any information-theoretic justification. This work examines the origins of the governing distribution P.... (truncated)