Inference-Based Quantum Sensing

TL;DR

This paper introduces an inference-based quantum sensing method that characterizes system responses with minimal measurements, enabling accurate parameter estimation even with noise and arbitrary states, demonstrated on real hardware.

Contribution

It presents a novel inference framework for quantum sensing that requires only a small number of measurements and applies broadly to various states and noise conditions.

Findings

Inference error can be kept below δ with measurements scaling as Ω(log^3(n)/δ^2).

The method is valid for arbitrary probe states and measurement schemes.

Successful implementation demonstrated on real quantum hardware and simulations.

Abstract

In a standard Quantum Sensing (QS) task one aims at estimating an unknown parameter $\theta$, encoded into an $n$-qubit probe state, via measurements of the system. The success of this task hinges on the ability to correlate changes in the parameter to changes in the system response $\mathcal{R}(\theta)$ (i.e., changes in the measurement outcomes). For simple cases the form of $\mathcal{R}(\theta)$ is known, but the same cannot be said for realistic scenarios, as no general closed-form expression exists. In this work we present an inference-based scheme for QS. We show that, for a general class of unitary families of encoding, $\mathcal{R}(\theta)$ can be fully characterized by only measuring the system response at $2n+1$ parameters. This allows us to infer the value of an unknown parameter given the measured response, as well as to determine the sensitivity of the scheme, which characterizes its overall performance. We show that inference error is, with high probability, smaller than $\delta$, if one measures the system response with a number of shots that scales only as $\Omega(\log^3(n)/\delta^2)$. Furthermore, the framework presented can be broadly applied as it remains valid for arbitrary probe states and measurement schemes, and, even holds in the presence of quantum noise. We also discuss how to extend our results beyond unitary families. Finally, to showcase our method we implement it for a QS task on real quantum hardware, and in numerical simulations.