More Optimal Simulation of Universal Quantum Computers

Abstract

Validating whether a quantum device confers a computational advantage often requires classical simulation of its outcomes. The worst-case sampling cost of L1-norm based simulation has plateaued at (2+2)t δ-1 in the limit that t → ∞, where δ is the additive error and t is the stabilizer extent of a t-qubit magic state. We reduce this prefactor 68-fold by a leading-order reduction in t through correlated sampling. The result exceeds even the average-case of the prior state-of-the-art and current simulators accurate to multiplicative error. Numerical demonstrations support our proofs. The technique can be applied broadly to reduce the cost of L1 minimization.