Variational Quantum Fidelity Estimation

Abstract

Computing quantum state fidelity will be important to verify and characterize states prepared on a quantum computer. In this work, we propose novel lower and upper bounds for the fidelity F(,σ) based on the "truncated fidelity" F(m, σ), which is evaluated for a state m obtained by projecting onto its m-largest eigenvalues. Our bounds can be refined, i.e., they tighten monotonically with m. To compute our bounds, we introduce a hybrid quantum-classical algorithm, called Variational Quantum Fidelity Estimation, that involves three steps: (1) variationally diagonalize , (2) compute matrix elements of σ in the eigenbasis of , and (3) combine these matrix elements to compute our bounds. Our algorithm is aimed at the case where σ is arbitrary and is low rank, which we call low-rank fidelity estimation, and we prove that a classical algorithm cannot efficiently solve this problem. Finally, we demonstrate that our bounds can detect quantum phase transitions and are often tighter than previously known computable bounds for realistic situations.