Estimating classical mutual information between quantum subsystems with neural networks

• URL: http://arxiv.org/abs/2508.07652v1
• Date: Mon, 11 Aug 2025 06:04:38 GMT
• Title: Estimating classical mutual information between quantum subsystems with neural networks
• Authors: D. A. Konyshev, V. V. Mazurenko,
• Abstract summary: We show the possibility to reconstruct the classical mutual information and specific entropy of a quantum system with neural network approach.<n>We show that the neural network approach gives reliable estimates of the classical mutual information even in the case of paramagnetic wave functions delocalized in the state space.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Characterizing correlations in a quantum system on the basis of the results of the projective measurements can be performed with different means including the calculation of the classical mutual information. Generally, estimating such information-entropy-based quantities requires having complete statistics of the system's states. Here we explore the possibility to reconstruct the classical mutual information and specific entropy of a quantum system with neural network approach on the basis of limited number of projective measurements. As a prominent example we consider the antiferromagnetic quantum Ising model in transverse and longitudinal magnetic fields which is in demand in both condensed matter physics and quantum computing. We show that the neural network approach gives reliable estimates of the classical mutual information even in the case of paramagnetic wave functions delocalized in the state space. In addition, the phase diagram of the considered quantum system is reconstructed with a special focus on discriminating various types of disordered states.

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