We present methods for constructing any target coupling graph using limited global controls in an Ising-like quantum spin system. Our approach is motivated by implementing the quantum approximate optimization algorithm (QAOA) on trapped ion quantum hardware to find approximate solutions to Max-Cut. We present a mathematical description of the problem and provide approximately optimal algorithmic constructions that generate arbitrary unweighted coupling graphs with n nodes in O(n) global entangling operations and weighted graphs with m edges in O(m) operations. These upper bounds are not tight in general, and we formulate a mixed-integer program to solve the graph coupling problem to optimality. We perform numeric experiments on small graphs with n≤8 and show that optimal sequences, which use fewer operations, can be found using mixed-integer programs. Noisy simulations of Max-Cut QAOA show that our implementation is less susceptible to noise than the standard gate-based compilation.
@article{arxiv.2011.08165,
title = {Generating Target Graph Couplings for QAOA from Native Quantum Hardware Couplings},
author = {Joel Rajakumar and Jai Moondra and Bryan Gard and Swati Gupta and Creston D. Herold},
journal= {arXiv preprint arXiv:2011.08165},
year = {2023}
}