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On linear-combinatorial problems associated with subspaces spanned by $\{\pm 1\}$-vectors

Combinatorics 2024-05-09 v1 Discrete Mathematics Algebraic Topology Probability

Abstract

A complete answer to the question about subspaces generated by {±1}\{\pm 1\}-vectors, which arose in the work of I.Kanter and H.Sompolinsky on associative memories, is given. More precisely, let vectors v1,,vp,v_1, \ldots , v_p, pn1,p\leq n-1, be chosen at random uniformly and independently from {±1}nRn.\{\pm 1\}^n \subset {\bf R}^n. Then the probability P(p,n){\mathbb P}(p, n) that span v1,,vp{{±1}n{±v1,,±vp}} span \ \langle v_1, \ldots , v_p \rangle \cap \left\{ \{\pm 1\}^n \setminus \{\pm v_1, \ldots , \pm v_p\}\right\} \ne \emptyset \ is shown to be 4(p3)(34)n+O((58+on(1))n)\mboxasn,4{p \choose 3}\left(\frac{3}{4}\right)^n + O\left(\left(\frac{5}{8} + o_n(1)\right)^n\right) \quad \mbox{as} \quad n\to \infty, where the constant implied by the OO-notation does not depend on pp. The main term in this estimate is the probability that some 3 vectors vj1,vj2,vj3v_{j_1}, v_{j_2}, v_{j_3} of vjv_j, j=1,,p,j= 1, \ldots , p, have a linear combination that is a {±1}\{\pm 1\}-vector different from ±vj1,±vj2,±vj3.\pm v_{j_1}, \pm v_{j_2}, \pm v_{j_3}.

Cite

@article{arxiv.2405.05082,
  title  = {On linear-combinatorial problems associated with subspaces spanned by $\{\pm 1\}$-vectors},
  author = {Anwar A. Irmatov},
  journal= {arXiv preprint arXiv:2405.05082},
  year   = {2024}
}

Comments

13 pages

R2 v1 2026-06-28T16:20:48.509Z