Quantum mutual information redistribution by Number Partitioning algorithm

Abstract

Quantum information distribution in a tripartite state plays a fundamental role in quantum information processes. Here we investigate how a bipartite unitary transformation UAB redistributes the quantum mutual information with the third party C in a tripartite pure state |ABC in a dA× dB× dC dimensional Hilbert space. In particular, we focus on finding out the optimal unitary transformation UAB that maximizes the quantum mutual entropy between party A and party C, I(A:C)=S(A)-S(B)+S(C). We show that the mutual entropy I(A:C) is upper bounded by 2S(C) derived from the Araki-Lieb inequality. This upper bound can be realized via an optimal unitary transformation for any pure state with the rank rC of C satisfying rC dA. For a generic pure state with rC> dA, the upper bound can not be realized by any bipartite unitary transformation. To maximize the mutual entropy in the latter case, we propose a fast numerical algorithm to produce an approximate optimal unitary transformation, where our optimization is transformed into a modified number partition problem. The validness of our algorithm is confirmed by its comparison with the results from the Adam algorithm for parameterized unitary transformations. Our approximate algorithm thus provides a practical protocol to implement redistribution of quantum mutual information for a tripartite quantum state with high dimensions.