Resolving problems on the polynomial identity characterization of daisy cubes

Abstract

Let X⊂eq\0,1\n be a set of binary strings of length n. The daisy cube Qn(X) is the subgraph of the hypercube Qn induced by the union of the intervals I(x,0n) for x∈ X. As a subclass of partial cubes, it generalizes Fibonacci cubes and Lucas cubes. For a graph G and a vertex u∈ V(G), we consider the cube polynomial CG(x), the distance cube polynomial DG,u(x,y), and the polynomial WG,u(x), which count k-cubes, k-cubes at distance from u, and vertices at distance k from u, respectively. In this paper, we prove that for a partial cube G with a vertex u∈ V(G), G is a daisy cube and u=0n if and only if one of the following equivalent conditions holds: (1) CG(x)=WG,u(x+1); (2) DG,u(x,y)=WG,u(x+y); (3) DG,u(x,y)=CG(x+y-1). In particular, conditions (1) and (3) give affirmative answers to two open problems posed by Klavzar and Mollard [European J. Combin., 80 (2019) 214--223]. Further, we obtain that for arbitrary partial cube G, DG,u(x,y)≤ WG,u(x+y) and CG(x)≤ WG,u(x+1). Besides, another bound for CG(x) due to Xie et al. [J. Graph Theory, 106 (2024) 907--922] is given by the clique polynomial ClG\#(x+1) of the crossing graph of G. We also compare these two bounds and show that the simplex graphs form the unique class of graphs for which the two bounds coincide.

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…