Reinforcement learning for semi-autonomous approximate quantum eigensolver

Francisco Albarrán-Arriagada; Juan Carlos Retamal; Lucas Lamata; Enrique Solano

Reinforcement learning for semi-autonomous approximate quantum eigensolver

ORAL

Abstract

The characterization of an operator by its eigenvectors and eigenvalues allows us to know its action over any quantum state. Here, we propose a protocol to obtain an approximation of the eigenvectors of an arbitrary Hermitian quantum operator. This protocol is based on measurement and feedback processes, which characterize a reinforcement learning protocol. With this proposal, we can obtain an approximation of the eigenvectors of a random qubit operator with average fidelity over 90% in less than 10 iterations, and surpass 98% in less than 300 iterations. Moreover, for the two-qubit cases, the four eigenvectors are obtained with fidelities above 89% in 8000 iterations for a random operator, and fidelities of 99% for an operator with the Bell states as eigenvectors.

March 18, 2021, 6:24 PM – March 18, 2021, 6:36 PM

Presenters

Francisco Albarrán-Arriagada

Shanghai University

Authors

Francisco Albarrán-Arriagada

Shanghai University
Juan Carlos Retamal

Fisica, Universidad De Santiago de Chile
Lucas Lamata

Fisica atomica, molecular y nuclear, Universidad de Sevilla
Enrique Solano

IQM Germany, Shanghai University