Efficient Privacy-Preserving Federated Learning With Improved Compressed Sensing
To solve the data silos issue in distributed machine learning with privacy leakage, privacy-preserving federated learning (PPFL) has been extensively explored in both academic and industrial fields. However, the existing PPFL solutions still suffer from high computation and communication overheads,...
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2023
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sg-smu-ink.sis_research-92942023-11-10T01:48:03Z Efficient Privacy-Preserving Federated Learning With Improved Compressed Sensing ZHANG, Yifan. MIAO, Yinbin. LI, Xinghua. WEI, Linfeng. LIU, Zhiquan CHOO, Kim-Kwang R. DENG, Robert H. To solve the data silos issue in distributed machine learning with privacy leakage, privacy-preserving federated learning (PPFL) has been extensively explored in both academic and industrial fields. However, the existing PPFL solutions still suffer from high computation and communication overheads, which result in excessive consumption of communication bandwidth and slow down the training process of FL. To address these issues, we propose a secure and communication-efficient FL scheme using improved compressed sensing and CKKS homomorphic encryption. Specifically, we implement a lossy compression of the model by using discrete cosine transform, then use CKKS homomorphic encryption to encrypt the data transmitted between clients and center server due to its high efficiency and support for batch encryption. Formal security analysis proves that our scheme is secure against indistinguishability under chosen plaintext attack and extensive experiments demonstrate that our scheme achieves a high accuracy at 0.05% compression rate. 2023-08-30T07:00:00Z text https://ink.library.smu.edu.sg/sis_research/8291 info:doi/10.1109/TII.2023.3297596 Research Collection School Of Computing and Information Systems eng Institutional Knowledge at Singapore Management University CKKS communication costs compression sensing (CS) federated learning (FL) homomorphic encryption Artificial Intelligence and Robotics |
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CKKS communication costs compression sensing (CS) federated learning (FL) homomorphic encryption Artificial Intelligence and Robotics |
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CKKS communication costs compression sensing (CS) federated learning (FL) homomorphic encryption Artificial Intelligence and Robotics ZHANG, Yifan. MIAO, Yinbin. LI, Xinghua. WEI, Linfeng. LIU, Zhiquan CHOO, Kim-Kwang R. DENG, Robert H. Efficient Privacy-Preserving Federated Learning With Improved Compressed Sensing |
| description |
To solve the data silos issue in distributed machine learning with privacy leakage, privacy-preserving federated learning (PPFL) has been extensively explored in both academic and industrial fields. However, the existing PPFL solutions still suffer from high computation and communication overheads, which result in excessive consumption of communication bandwidth and slow down the training process of FL. To address these issues, we propose a secure and communication-efficient FL scheme using improved compressed sensing and CKKS homomorphic encryption. Specifically, we implement a lossy compression of the model by using discrete cosine transform, then use CKKS homomorphic encryption to encrypt the data transmitted between clients and center server due to its high efficiency and support for batch encryption. Formal security analysis proves that our scheme is secure against indistinguishability under chosen plaintext attack and extensive experiments demonstrate that our scheme achieves a high accuracy at 0.05% compression rate. |
| format |
text |
| author |
ZHANG, Yifan. MIAO, Yinbin. LI, Xinghua. WEI, Linfeng. LIU, Zhiquan CHOO, Kim-Kwang R. DENG, Robert H. |
| author_facet |
ZHANG, Yifan. MIAO, Yinbin. LI, Xinghua. WEI, Linfeng. LIU, Zhiquan CHOO, Kim-Kwang R. DENG, Robert H. |
| author_sort |
ZHANG, Yifan. |
| title |
Efficient Privacy-Preserving Federated Learning With Improved Compressed Sensing |
| title_short |
Efficient Privacy-Preserving Federated Learning With Improved Compressed Sensing |
| title_full |
Efficient Privacy-Preserving Federated Learning With Improved Compressed Sensing |
| title_fullStr |
Efficient Privacy-Preserving Federated Learning With Improved Compressed Sensing |
| title_full_unstemmed |
Efficient Privacy-Preserving Federated Learning With Improved Compressed Sensing |
| title_sort |
efficient privacy-preserving federated learning with improved compressed sensing |
| publisher |
Institutional Knowledge at Singapore Management University |
| publishDate |
2023 |
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https://ink.library.smu.edu.sg/sis_research/8291 |
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