Characterization and Lower Bounds for Branching Program Size using Projective Dimension

Abstract

We study projective dimension, a graph parameter (denoted by pd(G) for a graph G), introduced by (Pudl\'ak, R\"odl 1992), who showed that proving lower bounds for pd(Gf) for bipartite graphs Gf associated with a Boolean function f imply size lower bounds for branching programs computing f. Despite several attempts (Pudl\'ak, R\"odl 1992 ; Babai, R\'onyai, Ganapathy 2000), proving super-linear lower bounds for projective dimension of explicit families of graphs has remained elusive. We show that there exist a Boolean function f (on n bits) for which the gap between the projective dimension and size of the optimal branching program computing f (denoted by bpsize(f)), is 2(n). Motivated by the argument in (Pudl\'ak, R\"odl 1992), we define two variants of projective dimension - projective dimension with intersection dimension 1 (denoted by upd(G)) and bitwise decomposable projective dimension (denoted by bitpdim(G)). As our main result, we show that there is an explicit family of graphs on N = 2n vertices such that the projective dimension is O(n), the projective dimension with intersection dimension 1 is (n) and the bitwise decomposable projective dimension is (n1.5 n). We also show that there exist a Boolean function f (on n bits) for which the gap between upd(Gf) and bpsize(f) is 2(n). In contrast, we also show that the bitwise decomposable projective dimension characterizes size of the branching program up to a polynomial factor. That is, there exists a constant c>0 and for any function f, bitpdim(Gf)/6 bpsize(f) (bitpdim(Gf))c. We also study two other variants of projective dimension and show that they are exactly equal to well-studied graph parameters - bipartite clique cover number and bipartite partition number respectively.