Extending echo state property for quantum reservoir computing
Abstract
The echo state property (ESP) represents a fundamental concept in the reservoir computing (RC) framework that ensures output-only training of reservoir networks by being agnostic to the initial states and far past inputs. However, the traditional definition of ESP does not describe possible non-stationary systems in which statistical properties evolve. To address this issue, we introduce two new categories of ESP: , designed for potentially non-stationary systems, and , designed for systems whose subsystems have ESP. Following the definitions, we numerically demonstrate the correspondence between non-stationary ESP in the quantum reservoir computer (QRC) framework with typical Hamiltonian dynamics and input encoding methods using non-linear autoregressive moving-average (NARMA) tasks. We also confirm the correspondence by computing linear/non-linear memory capacities that quantify input-dependent components within reservoir states. Our study presents a new understanding of the practical design of QRC and other possibly non-stationary RC systems in which non-stationary systems and subsystems are exploited.
Cite
@article{arxiv.2403.02686,
title = {Extending echo state property for quantum reservoir computing},
author = {Shumpei Kobayashi and Quoc Hoan Tran and Kohei Nakajima},
journal= {arXiv preprint arXiv:2403.02686},
year = {2024}
}
Comments
16 pages, 14 figures