Velocity Polytopes of Periodic Graphs and a No-Go Theorem for Digital Physics

Abstract

A periodic graph in dimension d is a directed graph with a free action of d with only finitely many orbits. It can conveniently be represented in terms of an associated finite graph with weights in d, corresponding to a d-bundle with connection. Here we use the weight sums along cycles in this associated graph to construct a certain polytope in d, which we regard as a geometrical invariant associated to the periodic graph. It is the unit ball of a norm on d describing the large-scale geometry of the graph. It has a physical interpretation as the set of attainable velocities of a particle on the graph which can hop along one edge per timestep. Since a polytope necessarily has distinguished directions, there is no periodic graph for which this velocity set is isotropic. In the context of classical physics, this can be viewed as a no-go theorem for the emergence of an isotropic space from a discrete structure.