On the solvable-unsolvable transition due to noise-induced chaos in digital memcomputing

TL;DR

This paper investigates how noise-induced chaos affects the performance of digital memcomputing machines, revealing a transition from solvability to failure linked to chaotic dynamics and Lyapunov exponents.

Contribution

It provides a detailed analysis of how numerical and physical noise induce chaos in DMMs, affecting their problem-solving ability, and suggests using power spectra to control their dynamical regime.

Findings

Noise induces a chaotic transition in DMMs affecting solvability

Positive Lyapunov exponents can coexist with successful problem-solving

Power spectra distinguish between regular and chaotic dynamical regimes

Abstract

Digital memcomputing machines (DMMs) have been designed to solve complex combinatorial optimization problems. Since DMMs are fundamentally classical dynamical systems, their ordinary differential equations (ODEs) can be efficiently simulated on modern computers. This provides a unique platform to study their performance under various conditions. An aspect that has received little attention so far is how their performance is affected by the numerical errors in the solution of their ODEs and the physical noise they would be naturally subject to if built in hardware. Here, we analyze these two aspects in detail by varying the integration time step (numerical noise) and adding stochastic perturbations (physical noise) into the equations of DMMs. We are particularly interested in understanding how noise induces a chaotic transition that marks the shift from successful problem-solving to failure in these systems. Our study includes an analysis of power spectra and Lyapunov exponents depending on the noise strength. The results reveal a correlation between the instance solvability and the sign of the ensemble averaged mean largest Lyapunov exponent. Interestingly, we find a regime in which DMMs with positive mean largest Lyapunov exponents still exhibit solvability. Furthermore, the power spectra provide additional information about our system by distinguishing between regular behavior (peaks) and chaotic behavior (broadband spectrum). Therefore, power spectra could be utilized to control whether a DMM operates in the optimal dynamical regime. Overall, we find that the qualitative effects of numerical and physical noise are mostly similar, despite their fundamentally different origin.