Communication-efficient Quantum Federated Learning Optimization for Multi-Center Healthcare Data

In the healthcare sector, the scarcity of data and privacy concerns present formidable challenges to the widespread adoption of machine learning. In the present-day scenario, Federated Learning (FL) emerges as a pivotal solution, fostering the rapid evolution of distributed machine learning paradigm...

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Published in	IEEE-EMBS International Conference on Biomedical and Health Informatics (BHI ...) (Online) pp. 1 - 8
Main Authors	Singh Bhatia, Amandeep, Saggi, Mandeep Kaur, Kais, Sabre
Format	Conference Proceeding
Language	English
Published	IEEE 10.11.2024
Subjects	Cancer Computational modeling Convergence Data privacy Distributed databases Federated learning healthcare Medical services Optimization Quantum circuit quantum machine learning quantum optimization Tuning variational quantum circuit
Online Access	Get full text
ISSN	2641-3604
DOI	10.1109/BHI62660.2024.10913485

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Abstract	In the healthcare sector, the scarcity of data and privacy concerns present formidable challenges to the widespread adoption of machine learning. In the present-day scenario, Federated Learning (FL) emerges as a pivotal solution, fostering the rapid evolution of distributed machine learning paradigms while adeptly addressing the problem of data governance and privacy. It allows distributed clients to collaboratively train a global model by synchronizing their local updates without sharing private data. In recent years, federated learning and quantum computing have individually shown great promise to revolutionize various sectors, including healthcare, finance, and manufacturing, where privacy protection is paramount. In this article, we propose a communication-efficient Quantum Federated Learning (QFL) framework based on a variational circuit that enables clients to efficiently train and transmit quantum model parameters, thereby reducing communication rounds significantly and enhancing QFL performance using quantum natural gradient descent (QNGD) optimization. This paper demonstrates the feasibility of a QFL framework for predicting the presence of coronary heart disease, diagnosing whether a patient is suffering from diabetes or not, and differentiating malignant and benign cancer by distributing the UCI datasets unbalanced among healthcare institutions. The proposed framework has the potential to incorporate privacy, security, and the expedited processing of distributed data. QNGD outperformed classical GD by reducing communication rounds by a range of 5% to 60%. In addition to reducing the communication rounds by optimizing the QFL training algorithm and achieving quicker convergence, it also determines the important features regardless of the data imbalance among the clients.
AbstractList	In the healthcare sector, the scarcity of data and privacy concerns present formidable challenges to the widespread adoption of machine learning. In the present-day scenario, Federated Learning (FL) emerges as a pivotal solution, fostering the rapid evolution of distributed machine learning paradigms while adeptly addressing the problem of data governance and privacy. It allows distributed clients to collaboratively train a global model by synchronizing their local updates without sharing private data. In recent years, federated learning and quantum computing have individually shown great promise to revolutionize various sectors, including healthcare, finance, and manufacturing, where privacy protection is paramount. In this article, we propose a communication-efficient Quantum Federated Learning (QFL) framework based on a variational circuit that enables clients to efficiently train and transmit quantum model parameters, thereby reducing communication rounds significantly and enhancing QFL performance using quantum natural gradient descent (QNGD) optimization. This paper demonstrates the feasibility of a QFL framework for predicting the presence of coronary heart disease, diagnosing whether a patient is suffering from diabetes or not, and differentiating malignant and benign cancer by distributing the UCI datasets unbalanced among healthcare institutions. The proposed framework has the potential to incorporate privacy, security, and the expedited processing of distributed data. QNGD outperformed classical GD by reducing communication rounds by a range of 5% to 60%. In addition to reducing the communication rounds by optimizing the QFL training algorithm and achieving quicker convergence, it also determines the important features regardless of the data imbalance among the clients.
Author	Saggi, Mandeep Kaur Kais, Sabre Singh Bhatia, Amandeep
Author_xml	– sequence: 1 givenname: Amandeep surname: Singh Bhatia fullname: Singh Bhatia, Amandeep email: drasinghbhatia@gmail.com organization: North Carolina State University,Department of Electrical and Computer Engineering,Raleigh,North Carolina,USA,27606 – sequence: 2 givenname: Mandeep Kaur surname: Saggi fullname: Saggi, Mandeep Kaur email: drmandeepsaggi@gmail.com organization: North Carolina State University,Department of Electrical and Computer Engineering,Raleigh,North Carolina,USA,27606 – sequence: 3 givenname: Sabre surname: Kais fullname: Kais, Sabre email: skais@ncsu.edu organization: North Carolina State University,Department of Electrical and Computer Engineering,Raleigh,North Carolina,USA,27606
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SubjectTerms	Cancer Computational modeling Convergence Data privacy Distributed databases Federated learning healthcare Medical services Optimization Quantum circuit quantum machine learning quantum optimization Tuning variational quantum circuit
Title	Communication-efficient Quantum Federated Learning Optimization for Multi-Center Healthcare Data
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