Diffusion Computation versus Quantum Computation: A Comparative Model for Order Finding and Factoring

Abstract

We study a hybrid computational model for integer factorization in which the only non-classical resource is access to an iterated diffusion process on a finite graph. Concretely, a diffusion step is defined to be one application of a symmetric stochastic matrix (the half-lazy walk operator) to an 1--normalized state vector, followed by an optional readout of selected coordinates. Let N 3 be an odd integer which is neither prime nor a prime power, and let b∈(Z/NZ) have odd multiplicative order r= ordN(b). We construct, without knowing r in advance, a weighted Cayley graph whose vertex set is the cyclic subgroup b and whose edges correspond to the powers b 2t for t 2 N+1. Using an explicit spectral decomposition together with an elementary doubling lemma, we show that r can be recovered from a single heat-kernel value after at most O((2 N)2) diffusion steps, with an effective bound. We then combine this order-finding model with the standard reduction from factoring to order finding (in the spirit of Shor's framework) to obtain a randomized factorization procedure whose success probability depends only on the number m of distinct prime factors of N. Our comparison with Shor's algorithm is conceptual and model-based. We replace unitary 2 evolution by Markovian 1 evolution, and we report complexity in two cost measures: digital steps and diffusion steps. Finally, we include illustrative examples and discussion of practical implementations.