Hardware implementation for secure computation on encrypted data
With the increasing adoption of “as a service” technologies, data-privacy and confidentiality are of increasing concerns in cloud computing platforms. Fully Homomorphic Encryption (FHE) schemes are a key tool in enabling privacy-preserving computing as they are able to perform homomorphic operati...
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Nanyang Technological University
2024
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sg-ntu-dr.10356-1770652024-05-24T15:45:45Z Hardware implementation for secure computation on encrypted data Ding, Dao Xian Chang Chip Hong School of Electrical and Electronic Engineering VIRTUS, IC Design Centre of Excellence ECHChang@ntu.edu.sg Computer and Information Science Engineering Fully homomorphic encryption Number theoretic transform FPGA With the increasing adoption of “as a service” technologies, data-privacy and confidentiality are of increasing concerns in cloud computing platforms. Fully Homomorphic Encryption (FHE) schemes are a key tool in enabling privacy-preserving computing as they are able to perform homomorphic operations over the ciphertext ring, eliminating the need for initial decryption. Despite their potential, FHE cryptosystems often observe huge computation cost and slow performance on general purpose platforms, thus limiting its deployment. In this project, we explore the use of hardware accelerator designs to accelerate a levelled Brakerski-Gentry-Vaikuntanathan (BGV) cryptosystem. We first perform a basic profiling of the BGV cryptosystem on a CPU platform to observe for computation bottlenecks. Based on the profiled results, an FPGA based accelerator is proposed to accelerate the Ring Multiplication Operation. This accelerator can then be used as a co-processor to a larger hardware/software codesign solution to accelerate the server-side operation. For this project, emphasis is placed on the hardware implementation of a 4096-point Residue Number System (RNS) based Number Theoretic Transform (NTT) unit. Within the NTT unit, either one or two butterfly units can used for computation, and a memory controller is used to facilitate communication between butterfly units and BRAMs. The proposed architecture is then pipelined to increase clock frequency, as well as throughput, and then tested on a Zync UltraScale+ MPSoc Evaluation Kit for area size, latency, and throughput estimation. Bachelor's degree 2024-05-24T06:06:48Z 2024-05-24T06:06:48Z 2024 Final Year Project (FYP) Ding, D. X. (2024). Hardware implementation for secure computation on encrypted data. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/177065 https://hdl.handle.net/10356/177065 en B2329-231 application/pdf Nanyang Technological University |
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Computer and Information Science Engineering Fully homomorphic encryption Number theoretic transform FPGA |
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Computer and Information Science Engineering Fully homomorphic encryption Number theoretic transform FPGA Ding, Dao Xian Hardware implementation for secure computation on encrypted data |
| description |
With the increasing adoption of “as a service” technologies, data-privacy and
confidentiality are of increasing concerns in cloud computing platforms. Fully
Homomorphic Encryption (FHE) schemes are a key tool in enabling privacy-preserving
computing as they are able to perform homomorphic operations over the ciphertext ring,
eliminating the need for initial decryption. Despite their potential, FHE cryptosystems
often observe huge computation cost and slow performance on general purpose platforms,
thus limiting its deployment. In this project, we explore the use of hardware accelerator
designs to accelerate a levelled Brakerski-Gentry-Vaikuntanathan (BGV) cryptosystem.
We first perform a basic profiling of the BGV cryptosystem on a CPU platform to observe
for computation bottlenecks. Based on the profiled results, an FPGA based accelerator is
proposed to accelerate the Ring Multiplication Operation. This accelerator can then be
used as a co-processor to a larger hardware/software codesign solution to accelerate the
server-side operation. For this project, emphasis is placed on the hardware
implementation of a 4096-point Residue Number System (RNS) based Number Theoretic
Transform (NTT) unit. Within the NTT unit, either one or two butterfly units can used for
computation, and a memory controller is used to facilitate communication between
butterfly units and BRAMs. The proposed architecture is then pipelined to increase clock
frequency, as well as throughput, and then tested on a Zync UltraScale+ MPSoc
Evaluation Kit for area size, latency, and throughput estimation. |
| author2 |
Chang Chip Hong |
| author_facet |
Chang Chip Hong Ding, Dao Xian |
| format |
Final Year Project |
| author |
Ding, Dao Xian |
| author_sort |
Ding, Dao Xian |
| title |
Hardware implementation for secure computation on encrypted data |
| title_short |
Hardware implementation for secure computation on encrypted data |
| title_full |
Hardware implementation for secure computation on encrypted data |
| title_fullStr |
Hardware implementation for secure computation on encrypted data |
| title_full_unstemmed |
Hardware implementation for secure computation on encrypted data |
| title_sort |
hardware implementation for secure computation on encrypted data |
| publisher |
Nanyang Technological University |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/177065 |
| _version_ |
1800916213245673472 |