Mean-field equations for higher-order quantum statistical models : an information geometric approach

Abstract

This work is a simple extension of NNjpa. We apply the concepts of information geometry to study the mean-field approximation for a general class of quantum statistical models namely the higher-order quantum Boltzmann machines (QBMs). The states we consider are assumed to have at most third-order interactions with deterministic coupling coefficients. Such states, taken together, can be shown to form a quantum exponential family and thus can be viewed as a smooth manifold. In our work, we explicitly obtain naive mean-field equations for the third-order classical and quantum Boltzmann machines and demonstrate how some information geometrical concepts, particularly, exponential and mixture projections used to study the naive mean-field approximation in NNjpa can be extended to a more general case. Though our results do not differ much from those in NNjpa, we emphasize the validity and the importance of information geometrical point of view for higher dimensional classical and quantum statistical models.