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Stable algorithms cannot reliably find isolated perceptron solutions

Computational Complexity 2026-04-02 v1 Data Structures and Algorithms Mathematical Physics math.MP Probability

Abstract

We study the binary perceptron, a random constraint satisfaction problem that asks to find a Boolean vector in the intersection of independently chosen random halfspaces. A striking feature of this model is that at every positive constraint density, it is expected that a 1oN(1)1-o_N(1) fraction of solutions are \emph{strongly isolated}, i.e. separated from all others by Hamming distance Ω(N)\Omega(N). At the same time, efficient algorithms are known to find solutions at certain positive constraint densities. This raises a natural question: can any isolated solution be algorithmically visible? We answer this in the negative: no algorithm whose output is stable under a tiny Gaussian resampling of the disorder can \emph{reliably} locate isolated solutions. We show that any stable algorithm has success probability at most 31794+oN(1)0.84233\frac{3\sqrt{17}-9}{4}+o_N(1)\leq 0.84233. Furthermore, every stable algorithm that finds a solution with probability 1oN(1)1-o_N(1) finds an isolated solution with probability oN(1)o_N(1). The class of stable algorithms we consider includes degree-DD polynomials up to Do(N/logN)D\leq o(N/\log N); under the low-degree heuristic \cite{hopkins2018statistical}, this suggests that locating strongly isolated solutions requires running time exp(Θ~(N))\exp(\widetilde{\Theta}(N)). Our proof does not use the overlap gap property. Instead, we show via Pitt's correlation inequality that after a random perturbation of the disorder, the number of solutions located close to a pre-existing isolated solution cannot concentrate at 11.

Keywords

Cite

@article{arxiv.2604.00328,
  title  = {Stable algorithms cannot reliably find isolated perceptron solutions},
  author = {Shuyang Gong and Brice Huang and Shuangping Li and Mark Sellke},
  journal= {arXiv preprint arXiv:2604.00328},
  year   = {2026}
}

Comments

27 pages, 1 figure

R2 v1 2026-07-01T11:47:23.505Z