English

Proof of a conjecture on monomial graphs

Combinatorics 2015-07-21 v1

Abstract

Let ee be a positive integer, pp be an odd prime, q=peq=p^{e}, and Fq\Bbb F_q be the finite field of qq elements. Let f,gFq[X,Y]f,g \in \Bbb F_q [X,Y]. The graph G=Gq(f,g)G=G_q(f,g) is a bipartite graph with vertex partitions P=Fq3P=\Bbb F_q^3 and L=Fq3L=\Bbb F_q^3, and edges defined as follows: a vertex (p)=(p1,p2,p3)P(p)=(p_1,p_2,p_3)\in P is adjacent to a vertex [l]=[l1,l2,l3]L[l] = [l_1,l_2,l_3]\in L if and only if p2+l2=f(p1,l1)p_2 + l_2 = f(p_1,l_1) and p3+l3=g(p1,l1)p_3 + l_3 = g(p_1,l_1). Motivated by some questions in finite geometry and extremal graph theory, Dmytrenko, Lazebnik and Williford conjectured in 2007 that if ff and gg are both monomials and GG has no cycle of length less than eight, then GG is isomorphic to the graph Gq(XY,XY2)G_q(XY,XY^2). They proved several instances of the conjecture by reducing it to the property of polynomials Ak=Xk[(X+1)kXk]A_k= X^k[(X+1)^k - X^k] and Bk=[(X+1)2k1]Xq1k2Xq1B_k= [(X+1)^{2k} - 1] X^{q-1-k} - 2X^{q-1} being permutation polynomials of Fq\Bbb F_q. In this paper we prove the conjecture by obtaining new results on the polynomials AkA_k and BkB_k, which are also of interest on their own.

Keywords

Cite

@article{arxiv.1507.05306,
  title  = {Proof of a conjecture on monomial graphs},
  author = {Xiang-dong Hou and Stephen D. Lappano and Felix Lazebnik},
  journal= {arXiv preprint arXiv:1507.05306},
  year   = {2015}
}

Comments

22 pages

R2 v1 2026-06-22T10:14:38.727Z