Towards large-scale quantum optimization solvers with few qubits

Abstract

We introduce a variational quantum solver for combinatorial optimizations over m=O(nk) binary variables using only n qubits, with tunable k>1. The number of parameters and circuit depth display mild linear and sublinear scalings in m, respectively. Moreover, we analytically prove that the specific qubit-efficient encoding brings in a super-polynomial mitigation of barren plateaus as a built-in feature. This leads to unprecedented quantum-solver performances. For m=7000, numerical simulations produce solutions competitive in quality with state-of-the-art classical solvers. In turn, for m=2000, an experiment with n=17 trapped-ion qubits featured MaxCut approximation ratios estimated to be beyond the hardness threshold 0.941. To our knowledge, this is the highest quality attained experimentally on such sizes. Our findings offer a novel heuristics for quantum-inspired solvers as well as a promising route towards solving commercially-relevant problems on near term quantum devices.