Litcius/Paper detail

Classical variational simulation of the Quantum Approximate Optimization Algorithm

Matija Medvidović, Giuseppe Carleo

2021npj Quantum Information82 citationsDOIOpen Access PDF

Abstract

Abstract A key open question in quantum computing is whether quantum algorithms can potentially offer a significant advantage over classical algorithms for tasks of practical interest. Understanding the limits of classical computing in simulating quantum systems is an important component of addressing this question. We introduce a method to simulate layered quantum circuits consisting of parametrized gates, an architecture behind many variational quantum algorithms suitable for near-term quantum computers. A neural-network parametrization of the many-qubit wavefunction is used, focusing on states relevant for the Quantum Approximate Optimization Algorithm (QAOA). For the largest circuits simulated, we reach 54 qubits at 4 QAOA layers, approximately implementing 324 RZZ gates and 216 RX gates without requiring large-scale computational resources. For larger systems, our approach can be used to provide accurate QAOA simulations at previously unexplored parameter values and to benchmark the next generation of experiments in the Noisy Intermediate-Scale Quantum (NISQ) era.

Topics & Concepts

Quantum computerQuantum algorithmQubitBenchmark (surveying)Quantum phase estimation algorithmQuantumComputer scienceQuantum gateQuantum error correctionQuantum sortAlgorithmQuantum circuitQuantum simulatorQuantum informationWave functionKey (lock)Quantum networkMathematicsParametrization (atmospheric modeling)Quantum technologyOpen quantum systemComponent (thermodynamics)Quantum stateTheoretical computer scienceQuantum processQuantum Fourier transformOptimization problemQuantum operationQuantum Turing machineElectronic circuitQuantum Computing Algorithms and ArchitectureQuantum many-body systemsQuantum Information and Cryptography