Litcius/Paper detail

Spoofing Cross-Entropy Measure in Boson Sampling

Changhun Oh, Liang Jiang, Bill Fefferman

2023Physical Review Letters25 citationsDOIOpen Access PDF

Abstract

Cross-entropy (XE) measure is a widely used benchmark to demonstrate quantum computational advantage from sampling problems, such as random circuit sampling using superconducting qubits and boson sampling (BS). We present a heuristic classical algorithm that attains a better XE than the current BS experiments in a verifiable regime and is likely to attain a better XE score than the near-future BS experiments in a reasonable running time. The key idea behind the algorithm is that there exist distributions that correlate with the ideal BS probability distribution and that can be efficiently computed. The correlation and the computability of the distribution enable us to postselect heavy outcomes of the ideal probability distribution without computing the ideal probability, which essentially leads to a large XE. Our method scores a better XE than the recent Gaussian BS experiments when implemented at intermediate, verifiable system sizes. Much like current state-of-the-art experiments, we cannot verify that our spoofer works for quantum-advantage-size systems. However, we demonstrate that our approach works for much larger system sizes in fermion sampling, where we can efficiently compute output probabilities. Finally, we provide analytic evidence that the classical algorithm is likely to spoof noisy BS efficiently.

Topics & Concepts

Computer scienceStatistical physicsAlgorithmSampling (signal processing)Measure (data warehouse)GaussianEntropy (arrow of time)Probability distributionImportance samplingBosonPhysicsMonte Carlo methodQuantum mechanicsMathematicsStatisticsData miningDetectorTelecommunicationsQuantum Computing Algorithms and ArchitectureAdvancements in Semiconductor Devices and Circuit DesignQuantum Information and Cryptography