TY - GEN
T1 - Centralized Multi-Key Fully Homomorphic Encryption from CKKS
AU - Fan, Jingjing
AU - Zhang, Chi
AU - Cai, Xuehong
AU - Jiang, Zoe Lin
AU - Au, Man Ho
AU - Yiu, Siu Ming
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - Fully Homomorphic Encryption (FHE) enables computation over encrypted data without revealing its content. However, most existing FHE schemes are designed for singlekey settings, limiting their use in collaborative applications involving multiple data owners. Multi-Key FHE (MKFHE) extends support to such scenarios but often incurs ciphertext expansion proportional to the number of participants and relies on complex, multi-round decryption. We propose a Centralized Multi-key Fully Homomorphic Encryption (CMKFHE) scheme that enables efficient and scalable multiuser computation. Each child node holds a distinct FHE key derived from public parameters generated by the parent, and functions as a standard FHE system. Ciphertexts produced by different children also support homomorphic evaluation, with the result decryptable only by a parent node possessing a master key. Computations within a child domain remain decryptable by that child, while sibling nodes cannot access each other's ciphertexts. We present a construction based on the CKKS framework that supports approximate arithmetic and ciphertext packing while maintaining constant ciphertext size, making it suitable for applications such as federated learning and privacy-preserving analytics.
AB - Fully Homomorphic Encryption (FHE) enables computation over encrypted data without revealing its content. However, most existing FHE schemes are designed for singlekey settings, limiting their use in collaborative applications involving multiple data owners. Multi-Key FHE (MKFHE) extends support to such scenarios but often incurs ciphertext expansion proportional to the number of participants and relies on complex, multi-round decryption. We propose a Centralized Multi-key Fully Homomorphic Encryption (CMKFHE) scheme that enables efficient and scalable multiuser computation. Each child node holds a distinct FHE key derived from public parameters generated by the parent, and functions as a standard FHE system. Ciphertexts produced by different children also support homomorphic evaluation, with the result decryptable only by a parent node possessing a master key. Computations within a child domain remain decryptable by that child, while sibling nodes cannot access each other's ciphertexts. We present a construction based on the CKKS framework that supports approximate arithmetic and ciphertext packing while maintaining constant ciphertext size, making it suitable for applications such as federated learning and privacy-preserving analytics.
KW - CKKS
KW - Fully Homomorphic Encryption
KW - Multi-key Fully Homomorphic Encryption
UR - https://www.scopus.com/pages/publications/105017848851
U2 - 10.1109/CCSB66722.2025.11154294
DO - 10.1109/CCSB66722.2025.11154294
M3 - 会议稿件
AN - SCOPUS:105017848851
T3 - 2025 5th International Conference on Computer Science and Blockchain, CCSB 2025
SP - 245
EP - 251
BT - 2025 5th International Conference on Computer Science and Blockchain, CCSB 2025
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 5th International Conference on Computer Science and Blockchain, CCSB 2025
Y2 - 1 August 2025 through 3 August 2025
ER -