Distributed and deep vertical federated learning with big data

Liu, Ji; Zhou, Xuehai; Mo, Lei; Ji, Shilei; Liao, Yuan; Li, Zheng; Gu, Qing; Dou, Dejing

doi:10.1002/cpe.7697

Concurrency and Computation

2023

DOI: 10.1002/cpe.7697

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Distributed and deep vertical federated learning with big data

Ji Liu

Xuehai Zhou

Lei Mo

et al.

Abstract: SummaryIn recent years, data are typically distributed in multiple organizations while the data security is becoming increasingly important. Federated learning (FL), which enables multiple parties to collaboratively train a model without exchanging the raw data, has attracted more and more attention. Based on the distribution of data, FL can be realized in three scenarios, that is, horizontal, vertical, and hybrid. In this article, we propose to combine distributed machine learning techniques with vertical FL … Show more

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Cited by 7 publications

References 58 publications

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Efficient asynchronous federated learning with sparsification and quantization

Jia,

Liu,

Zhou

et al. 2024

Concurrency and Computation

Self Cite

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SummaryWhile data is distributed in multiple edge devices, federated learning (FL) is attracting more and more attention to collaboratively train a machine learning model without transferring raw data. FL generally exploits a parameter server and a large number of edge devices during the whole process of the model training, while several devices are selected in each round. However, straggler devices may slow down the training process or even make the system crash during training. Meanwhile, other idle edge devices remain unused. As the bandwidth between the devices and the server is relatively low, the communication of intermediate data becomes a bottleneck. In this article, we propose time‐efficient asynchronous federated learning with sparsification and quantization, that is, TEASQ‐Fed. TEASQ‐Fed can fully exploit edge devices to asynchronously participate in the training process by actively applying for tasks. We utilize control parameters to choose an appropriate number of parallel edge devices, which simultaneously execute the training tasks. In addition, we introduce a caching mechanism and weighted averaging with respect to model staleness to further improve the accuracy. Furthermore, we propose a sparsification and quantitation approach to compress the intermediate data to accelerate the training. The experimental results reveal that TEASQ‐Fed improves the accuracy (up to 16.67% higher) while accelerating the convergence of model training (up to twice faster).

show abstract

Efficient asynchronous federated learning with sparsification and quantization

Jia,

Liu,

Zhou

et al. 2024

Concurrency and Computation

Self Cite

View full text Add to dashboard Cite

show abstract

Enhancing trust and privacy in distributed networks: a comprehensive survey on blockchain-based federated learning

Liu,

Chen,

et al. 2024

Knowl Inf Syst

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Trustworthy federated learning: privacy, security, and beyond

Chen,

Liu,

Tan

et al. 2024

Knowl Inf Syst

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Distributed and deep vertical federated learning with big data

Cited by 7 publications

References 58 publications

Efficient asynchronous federated learning with sparsification and quantization

Efficient asynchronous federated learning with sparsification and quantization

Enhancing trust and privacy in distributed networks: a comprehensive survey on blockchain-based federated learning

Trustworthy federated learning: privacy, security, and beyond

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