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Quantum imaginary time evolution steered by reinforcement learning

Chenfeng Cao, Zheng An, Shi‐Yao Hou, D. L. Zhou, Bei Zeng

2022Communications Physics30 citationsDOIOpen Access PDF

Abstract

Abstract The quantum imaginary time evolution is a powerful algorithm for preparing the ground and thermal states on near-term quantum devices. However, algorithmic errors induced by Trotterization and local approximation severely hinder its performance. Here we propose a deep reinforcement learning-based method to steer the evolution and mitigate these errors. In our scheme, the well-trained agent can find the subtle evolution path where most algorithmic errors cancel out, enhancing the fidelity significantly. We verified the method’s validity with the transverse-field Ising model and the Sherrington-Kirkpatrick model. Numerical calculations and experiments on a nuclear magnetic resonance quantum computer illustrate the efficacy. The philosophy of our method, eliminating errors with errors, sheds light on error reduction on near-term quantum devices.

Topics & Concepts

Reinforcement learningQuantumIsing modelImaginary timeComputer scienceQuantum computerFidelityPath integral formulationPath (computing)Term (time)Statistical physicsPhysicsAlgorithmArtificial intelligenceQuantum mechanicsOpen quantum systemProgramming languageTelecommunicationsSupersymmetric quantum mechanicsQuantum Computing Algorithms and ArchitectureQuantum many-body systemsNeural Networks and Reservoir Computing