Heisenberg-limited calibration of entangling gates with robust phase estimation

TL;DR

This paper introduces a robust phase estimation technique achieving Heisenberg-limited precision for calibrating multi-qubit entangling gates, significantly improving calibration efficiency and gate fidelity in quantum computing hardware.

Contribution

The work presents a novel calibration method using robust phase estimation that reaches Heisenberg limit, reducing complexity and enhancing accuracy for multi-qubit gate calibration.

Findings

Achieved Heisenberg-limited error estimates for two-qubit gates.

Demonstrated improved gate performance on superconducting qubits.

Applicable to various quantum hardware platforms and multi-qubit gates.

Abstract

The calibration of high-quality two-qubit entangling gates is an essential component in engineering large-scale, fault-tolerant quantum computers. However, many standard calibration techniques are based on randomized circuits that are only quadratically sensitive to calibration errors. As a result, these approaches are inefficient, requiring many experimental shots to achieve acceptable performance. In this work, we demonstrate that robust phase estimation can enable high-precision, Heisenberg-limited estimates of coherent errors in multi-qubit gates. Equipped with an efficient estimator, the calibration problem may be reduced to a simple optimization loop that minimizes the estimated coherent error. We experimentally demonstrate our calibration protocols by improving the operation of a two-qubit controlled-Z gate on a superconducting processor, and we validate the improved performance with gate set tomography. Our methods are applicable to gates in other quantum hardware platforms such as ion traps and neutral atoms, and on other multi-qubit gates, such as CNOT or iSWAP.