Parity balance of the i-th dimension edges in Hamiltonian cycles of the hypercube

Abstract

Let n≥ 2 be an integer, and let i∈\0,...,n-1\. An i-th dimension edge in the n-dimensional hypercube Qn is an edge v1v2 such that v1,v2 differ just at their i-th entries. The parity of an i-th dimension edge v1v2 is the number of 1's modulus 2 of any of its vertex ignoring the i-th entry. We prove that the number of i-th dimension edges appearing in a given Hamiltonian cycle of Qn with parity zero coincides with the number of edges with parity one. As an application of this result it is introduced and explored the conjecture of the inscribed squares in Hamiltonian cycles of the hypercube: Any Hamiltonian cycle in Qn contains two opposite edges in a 4-cycle. We prove this conjecture for n 7, and for any Hamiltonian cycle containing more than 2n-2 edges in the same dimension. This bound is finally improved considering the equi-independence number of Qn-1, which is a concept introduced in this paper for bipartite graphs.