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Bibliographic Details
Main Authors: Dell'Anna, Federico, Grotti, Matteo, Giardinelli, Vito
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.06778
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author Dell'Anna, Federico
Grotti, Matteo
Giardinelli, Vito
author_facet Dell'Anna, Federico
Grotti, Matteo
Giardinelli, Vito
contents We study probabilistic cellular automata (PCA) and quantum cellular automata (QCA) as frameworks for solving the Maximum Independent Set (MIS) problem. We first introduce a synchronous PCA whose dynamics drives the system toward the manifold of maximal independent sets. Numerical evidence shows that the MIS convergence probability increases significantly as the activation probability p tends to 1, and we characterize how the steps required to reach the absorbing state scale with system size and graph connectivity. Motivated by this behavior, we construct a QCA combining a pure dissipative phase with a constraint-preserving unitary evolution that redistributes probability within this manifold. Tensor Network simulations reveal that repeated dissipative--unitary cycles concentrate population on MIS configurations. We also provide an empirical estimate of how the convergence time scales with graph size, suggesting that QCA dynamics can provide an efficient alternative to adiabatic and variational quantum optimization methods based exclusively on local and translationally invariant rules.
format Preprint
id arxiv_https___arxiv_org_abs_2512_06778
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Maximum Independent Set via Probabilistic and Quantum Cellular Automata
Dell'Anna, Federico
Grotti, Matteo
Giardinelli, Vito
Quantum Physics
We study probabilistic cellular automata (PCA) and quantum cellular automata (QCA) as frameworks for solving the Maximum Independent Set (MIS) problem. We first introduce a synchronous PCA whose dynamics drives the system toward the manifold of maximal independent sets. Numerical evidence shows that the MIS convergence probability increases significantly as the activation probability p tends to 1, and we characterize how the steps required to reach the absorbing state scale with system size and graph connectivity. Motivated by this behavior, we construct a QCA combining a pure dissipative phase with a constraint-preserving unitary evolution that redistributes probability within this manifold. Tensor Network simulations reveal that repeated dissipative--unitary cycles concentrate population on MIS configurations. We also provide an empirical estimate of how the convergence time scales with graph size, suggesting that QCA dynamics can provide an efficient alternative to adiabatic and variational quantum optimization methods based exclusively on local and translationally invariant rules.
title Maximum Independent Set via Probabilistic and Quantum Cellular Automata
topic Quantum Physics
url https://arxiv.org/abs/2512.06778