XY-mixers: analytical and numerical results for QAOA

Abstract

The Quantum Alternating Operator Ansatz (QAOA) is a promising gate-model meta-heuristic for combinatorial optimization. Applying the algorithm to problems with constraints presents an implementation challenge for near-term quantum resources. This work explores strategies for enforcing hard constraints by using XY-Hamiltonians as mixing operators (mixers). Despite the complexity of simulating the XY model, we demonstrate that for problems represented through one-hot-encoding, certain classes of the mixer Hamiltonian can be implemented without Trotter error in depth O() where is the number of assignable colors. We also specify general strategies for implementing QAOA circuits on all-to-all connected hardware graphs and linearly connected hardware graphs inspired by fermionic simulation techniques. Performance is validated on graph coloring problems that are known to be challenging for a given classical algorithm. The general strategy of using XY-mixers is borne out numerically, demonstrating a significant improvement over the general X-mixer, and moreover the generalized W-state yields better performance than easier-to-generate classical initial states when XY mixers are used.