A Data-Driven Gradient Algorithm for High-Precision Quantum Control

TL;DR

This paper introduces d-GRAPE, a data-driven gradient algorithm that enhances quantum gate precision by learning from both models and experimental data, effectively correcting errors in quantum control.

Contribution

The paper proposes a novel data-driven gradient optimization method, d-GRAPE, which improves quantum control accuracy by integrating model-based and experimental data for error correction.

Findings

d-GRAPE can correct all deterministic gate errors

The algorithm performs well with broadband controls and many parameters

Simulations show improved two-qubit CNOT gate implementation

Abstract

In the quest to achieve scalable quantum information processing technologies, gradient-based optimal control algorithms (e.g., GRAPE) are broadly used for implementing high-precision quantum gates, but their performance is often hindered by deterministic or random errors in the system model and the control electronics. In this paper, we show that GRAPE can be taught to be more effective by jointly learning from the design model and the experimental data obtained from process tomography. The resulting data-driven gradient optimization algorithm (d-GRAPE) can in principle correct all deterministic gate errors, with a mild efficiency loss. The d-GRAPE algorithm may become more powerful with broadband controls that involve a large number of control parameters, while other algorithms usually slow down due to the increased size of the search space. These advantages are demonstrated by simulating the implementation of a two-qubit CNOT gate.