Ray C. C. Cheung scite author profile

Abstract-This paper presents a method for producing hardware designs for elliptic curve cryptography (ECC) systems over the finite field GF(2 ), using the optimal normal basis for the representation of numbers. Our field multiplier design is based on a parallel architecture containing multiple -bit serial multipliers; by changing the number of such serial multipliers, designers can obtain implementations with different tradeoffs in speed, size and level of security. A design generator has been developed which can automatically produce a customised ECC hardware design that meets user-defined requirements. To facilitate performance characterization, we have developed a parametric model for estimating the number of cycles for our generic ECC architecture. The resulting hardware implementations are among the fastest reported: for a key size of 270 bits, a point multiplication in a Xilinx XC2V6000 FPGA at 35 MHz can run over 1000 times faster than a software implementation on a Xeon computer at 2.6 GHz.Index Terms-Field-programmable gate arrays (FPGAs), parallel architectures, public key cryptography, security.

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Faster Pairing Coprocessor Architecture

Yao

Fan

Cheung

et al. 2013

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In this paper, we present a high-speed pairing coprocessor using Residue Number System (RNS) which is intrinsically suitable for parallel computation. This work improves the design of Cheung et al. [11] using a carefully selected RNS base and an optimized pipeline design of the modular multiplier. As a result, the cycle count for a modular reduction has been halved. When combining with the lazy reduction, Karatsuba-like formulas and optimal pipeline scheduling, a 128-bit optimal ate pairing computation can be completed in less than 100,000 cycles. We prototype the design on a Xilinx Virtex-6 FPGA using 5237 slices and 64 DSPs; a 128-bit pairing is computed in 0.358 ms running at 230MHz. To the best of our knowledge, this implementation outperforms all reported hardware and software designs.

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Unsupervised and real-time spike sorting chip for neural signal processing in hippocampal prosthesis

Han

et al. 2019

Journal of Neuroscience Methods

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Ray C. C. Cheung

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Customizable elliptic curve cryptosystems

Faster Pairing Coprocessor Architecture

Unsupervised and real-time spike sorting chip for neural signal processing in hippocampal prosthesis

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