Minor-embedding in adiabatic quantum computation: II. Minor-universal graph design

In Choi (Quantum Inf Process, 7:193–209, 2008), we introduced the notion of minor-embedding in adiabatic quantum optimization. A minor-embedding of a graph G in a quantum hardware graph U is a subgraph of U such that G can be obtained from it by contracting edges. In this paper, we describe the intertwined adiabatic quantum architecture design problem, which is to construct a hardware graph U that satisfies all known physical constraints and, at the same time, permits an efficient minor-embedding algorithm. We illustrate an optimal complete-graph-minor hardware graph. Given a family F{mathcal{F}} of graphs, a (host) graph U is called F{mathcal{F}}-minor-universal if for each graph G in F, U{mathcal{F}, U} contains a minor-embedding of G. The problem for designing a F{{mathcal{F}}}-minor-universal hardware graph U _sparse in which F{{mathcal{F}}} consists of a family of sparse graphs (e.g., bounded degree graphs) is open.