Solving the time-complexity problem and tuning the performance of quantum reservoir computing by artificial memory restriction

TL;DR

This paper introduces a method to reduce the time complexity of quantum reservoir computing by artificially restricting memory, enabling more efficient and tunable quantum time-series prediction.

Contribution

It proposes a novel memory restriction technique that transforms quadratic time complexity into linear, improving efficiency and allowing performance tuning in quantum reservoir computing.

Findings

Linear algorithm reduces computational cost significantly

Memory restriction enables performance optimization

Numerical studies confirm effectiveness on quantum models

Abstract

Quantum reservoir computing is a computing approach which aims at utilising the complexity and high-dimensionality of small quantum systems, together with the fast trainability of reservoir computing, in order to solve complex tasks. The suitability of quantum reservoir computing for solving temporal tasks is hindered by the collapse of the quantum system when measurements are made. This leads to the erasure of the memory of the reservoir. Hence, for every output, the entire input signal is needed to reinitialise the reservoir, leading to quadratic time complexity. Overcoming this issue is critical to the hardware implementation of quantum reservoir computing. We propose artificially restricting the memory of the quantum reservoir by only using a small number inputs to reinitialise the reservoir after measurements are performed, leading to linear time complexity. This not only substantially reduces the number of quantum operations needed to perform timeseries prediction tasks, it also provides a means of tuning the nonlinearity of the response of the reservoir, which can lead to significant performance improvement. We numerically study the linear and quadratic algorithms for a fully connected transverse Ising model and a quantum processor model. We find that our proposed linear algorithm not only significantly reduces the computational cost but also provides an experimental accessible means to optimise the task specific reservoir computing performance.