TY - JOUR
T1 - Distributed additive encryption and quantization for privacy preserving federated deep learning
AU - Zhu, Hangyu
AU - Wang, Rui
AU - Jin, Yaochu
AU - Liang, Kaitai
AU - Ning, Jianting
PY - 2021
Y1 - 2021
N2 - Homomorphic encryption is a very useful gradient protection technique used in privacy preserving federated learning. However, existing encrypted federated learning systems need a trusted third party to generate and distribute key pairs to connected participants, making them unsuited for federated learning and vulnerable to security risks. Moreover, encrypting all model parameters is computationally intensive, especially for large machine learning models such as deep neural networks. In order to mitigate these issues, we develop a practical, computationally efficient encryption based protocol for federated deep learning, where the key pairs are collaboratively generated without the help of a trusted third party. By quantization of the model parameters on the clients and an approximated aggregation on the server, the proposed method avoids encryption and decryption of the entire model. In addition, a threshold based secret sharing technique is designed so that no one can hold the global private key for decryption, while aggregated ciphertexts can be successfully decrypted by a threshold number of clients even if some clients are offline. Our experimental results confirm that the proposed method significantly reduces the communication costs and computational complexity compared to existing encrypted federated learning without compromising the performance and security.
AB - Homomorphic encryption is a very useful gradient protection technique used in privacy preserving federated learning. However, existing encrypted federated learning systems need a trusted third party to generate and distribute key pairs to connected participants, making them unsuited for federated learning and vulnerable to security risks. Moreover, encrypting all model parameters is computationally intensive, especially for large machine learning models such as deep neural networks. In order to mitigate these issues, we develop a practical, computationally efficient encryption based protocol for federated deep learning, where the key pairs are collaboratively generated without the help of a trusted third party. By quantization of the model parameters on the clients and an approximated aggregation on the server, the proposed method avoids encryption and decryption of the entire model. In addition, a threshold based secret sharing technique is designed so that no one can hold the global private key for decryption, while aggregated ciphertexts can be successfully decrypted by a threshold number of clients even if some clients are offline. Our experimental results confirm that the proposed method significantly reduces the communication costs and computational complexity compared to existing encrypted federated learning without compromising the performance and security.
KW - Federated learning
KW - Deep learning
KW - Homomorphic encryption
KW - Distributed key generation
KW - Quantization
UR - http://www.scopus.com/inward/record.url?scp=85113680178&partnerID=8YFLogxK
U2 - 10.1016/j.neucom.2021.08.062
DO - 10.1016/j.neucom.2021.08.062
M3 - Article
SN - 0925-2312
VL - 463
SP - 309
EP - 327
JO - Neurocomputing
JF - Neurocomputing
ER -