Memory-Nonlinearity Trade-off across Quantum Reservoir Computing Frameworks
Abstract
Quantum reservoir computing (QRC) harnesses driven quantum dynamics for time-series processing, yet the mechanisms behind the differing performance levels across its many implementations remain unclear. We show that apparently unrelated approaches-including memory restriction, weak measurements, operation near the edge of quantum chaos, and dissipative dynamics-are in fact governed by the same underlying principle, namely a tunable balance between memory retention and nonlinear response. Using the information processing capacity, a dynamical measure from nonlinear systems theory, we place these behaviors in a unified framework and identify the regimes in which quantum reservoirs surpass the standard protocol. Our results reveal a fundamental connection between memory and nonlinear response. This provides a general design principle for enhanced information processing and enables systematic analysis and optimization inspired by classical dynamical quantifiers.
Cite
@article{arxiv.2603.21371,
title = {Memory-Nonlinearity Trade-off across Quantum Reservoir Computing Frameworks},
author = {Saud Čindrak and Lara Giebeler and Niclas Götting and Christopher Gies and Kathy Lüdge},
journal= {arXiv preprint arXiv:2603.21371},
year = {2026}
}
Comments
12 pages, 6 figures