An upper bound for Cubicity in terms of Boxicity

An axis-parallel b-dimensional box is a Cartesian product R₁×R₂×?×R_b where each R_i (for 1≤i≤b) is a closed interval of the form a_i,b_i] on the real line. The boxicity of any graph G, is the minimum positive integer b such that G can be represented as the intersection graph of axis-parallel b-dimensional boxes. A b-dimensional cube is a Cartesian product R₁×R₂×?×R_b, where each R_i (for 1≤i≤b) is a closed interval of the form a_i,a_i+1] on the real line. When the boxes are restricted to be axis-parallel cubes in b-dimension, the minimum dimension b required to represent the graph is called the cubicity of the graph (denoted by ). In this paper we prove that , where n is the number of vertices in the graph. We also show that this upper bound is tight.Some immediate consequences of the above result are listed below:

1.

Planar graphs have cubicity at most 3⌈log₂n⌉.

2.

Outer planar graphs have cubicity at most 2⌈log₂n⌉.

3.

Any graph of treewidth tw has cubicity at most (tw+2)⌈log₂n⌉. Thus, chordal graphs have cubicity at most (ω+1)⌈log₂n⌉ and circular arc graphs have cubicity at most (2ω+1)⌈log₂n⌉, where ω is the clique number.

The above upper bounds are tight, but for small constant factors.