Approximate Autonomous Quantum Error Correction with Reinforcement Learning
Abstract
Autonomous quantum error correction (AQEC) protects logical qubits by engineered dissipation and thus circumvents the necessity of frequent, error-prone measurement-feedback loops. Bosonic code spaces, where single-photon loss represents the dominant source of error, are promising candidates for AQEC due to their flexibility and controllability. While existing proposals have demonstrated the in-principle feasibility of AQEC with bosonic code spaces, these schemes are typically based on the exact implementation of the Knill-Laflamme conditions and thus require the realization of Hamiltonian distances . Implementing such Hamiltonian distances requires multiple nonlinear interactions and control fields, rendering these schemes experimentally challenging. Here, we propose a bosonic code for approximate AQEC by relaxing the Knill-Laflamme conditions. Using reinforcement learning (RL), we identify the optimal bosonic set of codewords (denoted here by RL code), which, surprisingly, is composed of the Fock states and . As we show, the RL code, despite its approximate nature, successfully suppresses single-photon loss, reducing it to an effective dephasing process that well surpasses the break-even threshold. It may thus provide a valuable building block toward full error protection. The error-correcting Hamiltonian, which includes ancilla systems that emulate the engineered dissipation, is entirely based on the Hamiltonian distance , significantly reducing model complexity. Single-qubit gates are implemented in the RL code with a maximum distance .
Cite
@article{arxiv.2212.11651,
title = {Approximate Autonomous Quantum Error Correction with Reinforcement Learning},
author = {Yexiong Zeng and Zheng-Yang Zhou and Enrico Rinaldi and Clemens Gneiting and Franco Nori},
journal= {arXiv preprint arXiv:2212.11651},
year = {2023}
}