Short-depth circuits for efficient expectation value estimation

Abstract

The evaluation of expectation values Tr[ O] for some pure state and Hermitian operator O is of central importance in a variety of quantum algorithms. Near optimal techniques developed in the past require a number of measurements N approaching the Heisenberg limit N=O(1/ε) as a function of target accuracy ε. The use of Quantum Phase Estimation requires however long circuit depths C=O(1/ε) making their implementation difficult on near term noisy devices. The more direct strategy of Operator Averaging is usually preferred as it can be performed using N=O(1/ε2) measurements and no additional gates besides those needed for the state preparation. In this work we use a simple but realistic model to describe the bound state of a neutron and a proton (the deuteron) and show that the latter strategy can require an overly large number of measurement in order to achieve a reasonably small relative target accuracy εr. We propose to overcome this problem using a single step of QPE and classical post-processing. This approach leads to a circuit depth C=O(εμ) (with μ≥0) and to a number of measurements N=O(1/ε2+) for 0<≤1. We provide detailed descriptions of two implementations of our strategy for =1 and ≈0.5 and derive appropriate conditions that a particular problem instance has to satisfy in order for our method to provide an advantage.