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Helping restricted Boltzmann machines with quantum-state representation by restoring symmetry

Yusuke Nomura

2021Journal of Physics Condensed Matter64 citationsDOIOpen Access PDF

Abstract

Abstract The variational wave functions based on neural networks have recently started to be recognized as a powerful ansatz to represent quantum many-body states accurately. In order to show the usefulness of the method among all available numerical methods, it is imperative to investigate the performance in challenging many-body problems for which the exact solutions are not available. Here, we construct a variational wave function with one of the simplest neural networks, the restricted Boltzmann machine (RBM), and apply it to a fundamental but unsolved quantum spin Hamiltonian, the two-dimensional J 1 – J 2 Heisenberg model on the square lattice. We supplement the RBM wave function with quantum-number projections, which restores the symmetry of the wave function and makes it possible to calculate excited states. Then, we perform a systematic investigation of the performance of the RBM. We show that, with the help of the symmetry, the RBM wave function achieves state-of-the-art accuracy both in ground-state and excited-state calculations. The study shows a practical guideline on how we achieve accuracy in a controlled manner.

Topics & Concepts

AnsatzRestricted Boltzmann machineWave functionSymmetry (geometry)Boltzmann machineFunction (biology)Artificial neural networkRepresentation (politics)QuantumStatistical physicsComputer scienceConstruct (python library)Boltzmann constantPhysicsSpin (aerodynamics)Excited stateMathematicsQuantum computerQuantum mechanicsTopology (electrical circuits)Square (algebra)Order (exchange)AlgorithmApplied mathematicsQuantum algorithmQuantum many-body systemsMachine Learning in Materials ScienceQuantum Computing Algorithms and Architecture