Reconstruction of graph colourings

Abstract

A k-deck of a (coloured) graph is a multiset of its induced k-vertex subgraphs. Given a graph G, when is it possible to reconstruct with high probability a uniformly random colouring of its vertices in r colours from its k-deck? In this paper, we study this question for grids and random graphs. Reconstruction of random colourings of d-dimensional n-grids from the deck of their k-subgrids is one of the most studied colour reconstruction questions. The 1-dimensional case is motivated by the problem of reconstructing DNA sequences from their `shotgunned' stretches. It was comprehensively studied and the above reconstruction question was completely answered in the '90s. In this paper, we get a very precise answer for higher d. For every d≥ 2 and every r≥ 2, we present an almost linear algorithm that reconstructs with high probability a random r-colouring of vertices of a d-dimensional n-grid from the deck of all its k-subgrids for every k≥(dr n)1/d+1/d+ and prove that the random r-colouring is not reconstructible with high probability if k≤ (dr n)1/d-. This answers the question of Narayanan and Yap (that was asked for d≥ 3) on "two-point concentration" of the minimum k so that k-subgrids determine the entire colouring. Next, we prove that with high probability a uniformly random r-colouring of vertices of a uniformly random graph G(n,1/2) is reconstructible from its full k-deck if k≥ 22 n+8 and is not reconstructible with high probability if k≤22 n. We further show that the colour reconstruction algorithm for random graphs can be modified and used for graph reconstruction: we prove that with high probability G(n,1/2) is reconstructible from its full k-deck if k≥ 22 n+11 while it is not reconstructible with high probability if k≤ 22 n.