Litcius/Paper detail

Scaling whole-chip QAOA for higher-order ising spin glass models on heavy-hex graphs

Elijah Pelofske, Andreas Bärtschi, Łukasz Cincio, John Golden, Stephan Eidenbenz

2024npj Quantum Information15 citationsDOIOpen Access PDF

Abstract

Abstract We show that the quantum approximate optimization algorithm (QAOA) for higher-order, random coefficient, heavy-hex compatible spin glass Ising models has strong parameter concentration across problem sizes from 16 up to 127 qubits for p = 1 up to p = 5, which allows for computationally efficient parameter transfer of QAOA angles. Matrix product state (MPS) simulation is used to compute noise-free QAOA performance. Hardware-compatible short-depth QAOA circuits are executed on ensembles of 100 higher-order Ising models on noisy IBM quantum superconducting processors with 16, 27, and 127 qubits using QAOA angles learned from a single 16-qubit instance using the JuliQAOA tool. We show that the best quantum processors find lower energy solutions up to p = 2 or p = 3, and find mean energies that are about a factor of two off from the noise-free distribution. We show that p = 1 QAOA energy landscapes remain very similar as the problem size increases using NISQ hardware gridsearches with up to a 414 qubit processor.

Topics & Concepts

QubitIsing modelQuantum computerScalingStatistical physicsQuantumSpin (aerodynamics)Computer scienceQuantum mechanicsMathematicsPhysicsAlgorithmGeometryThermodynamicsQuantum Computing Algorithms and ArchitectureQuantum many-body systemsQuantum and electron transport phenomena