Using deep learning to understand and mitigate the qubit noise environment

Understanding the spectrum of noise acting on a qubit can yield valuable information about its environment, and crucially underpins the optimization of dynamical decoupling protocols that can mitigate such noise. However, extracting accurate noise spectra from typical time-dynamics measurements on q...

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Bibliographic Details
Published in:arXiv.org 2021-01
Main Authors: Wise, David F, Morton, John J L, Dhomkar, Siddharth
Format: Article
Language:English
Subjects:
Algorithms
Decoupling
Deep learning
Machine learning
Magnetic resonance
Natural language processing
Neural networks
Noise
Noise spectra
Object recognition
Optimization
Protocol (computers)
Quantum computing
Qubits (quantum computing)
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Summary:Understanding the spectrum of noise acting on a qubit can yield valuable information about its environment, and crucially underpins the optimization of dynamical decoupling protocols that can mitigate such noise. However, extracting accurate noise spectra from typical time-dynamics measurements on qubits is intractable using standard methods. Here, we propose to address this challenge using deep learning algorithms, leveraging the remarkable progress made in the field of image recognition, natural language processing, and more recently, structured data. We demonstrate a neural network based methodology that allows for extraction of the noise spectrum associated with any qubit surrounded by an arbitrary bath, with significantly greater accuracy than the current methods of choice. The technique requires only a two-pulse echo decay curve as input data and can further be extended either for constructing customized optimal dynamical decoupling protocols or for obtaining critical qubit attributes such as its proximity to the sample surface. Our results can be applied to a wide range of qubit platforms, and provide a framework for improving qubit performance with applications not only in quantum computing and nanoscale sensing but also in material characterization techniques such as magnetic resonance.
ISSN:2331-8422
DOI:10.48550/arxiv.2005.01144