High-Speed and Unified ECC Processor for Generic Weierstrass Curves over GF(p) on FPGA

Awaludin, Asep Muhamad; Larasati, Harashta Tatimma; Kim, Howon

doi:10.20944/preprints202101.0250.v1

2021

DOI: 10.20944/preprints202101.0250.v1

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High-Speed and Unified ECC Processor for Generic Weierstrass Curves over GF(p) on FPGA

Asep Muhamad Awaludin¹,

Harashta Tatimma Larasati²,

Howon Kim³

Abstract: In this paper, we present a high-speed, unified elliptic curve cryptography (ECC) processor for arbitrary Weierstrass curves over GF(p), which to the best of our knowledge, outperforms other similar works in terms of execution time. Our approach employs the combination of the schoolbook long and Karatsuba multiplication algorithm for the elliptic curve point multiplication (ECPM) to achieve better parallelization while retaining low complexity. In the hardware implementation, the substantial gain in speed is a… Show more

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Cited by 10 publications

References 12 publications

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An Optimized Flexible Accelerator for Elliptic Curve Point Multiplication over NIST Binary Fields

Aljaedi,

Rashid,

Jamal

et al. 2023

Applied Sciences

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This article proposes a flexible hardware accelerator optimized from a throughput and area point of view for the computationally intensive part of elliptic curve cryptography. The target binary fields, defined by the National Institute of Standards and Technology, are GF(2163), GF(2233), GF(2283), GF(2409), and GF(2571). For the optimization of throughput, the proposed accelerator employs a digit-parallel multiplier. The size of the digit is 41 bits. The proposed accelerator has reused the multiplication and squaring circuit for area optimization to compute modular inversions. Flexibility is included using three additional buffers on top of the proposed accelerator architecture to load different input parameters. Finally, a dedicated controller is used to optimize control signal handling. The architecture is modeled using Verilog and implemented up to the post-place-and-route level on a Xilinx Virtex-7 field-programmable gate array. The area utilization of our accelerator in slices is 1479, 1998, 2573, 3271, and 4469 for m=163 to 571. The time needed to perform one-point multiplication is 7.15, 10.60, 13.26, 20.96, and 30.42 μs. Similarly, the throughput over area figures for the same key lengths are 94.56, 47.21, 29.30, 14.58, and 7.35. Consequently, achieved results and a comprehensive performance comparison show the suitability of the proposed design for constrained environments that demand throughput/area-efficient implementations.

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An Optimized Flexible Accelerator for Elliptic Curve Point Multiplication over NIST Binary Fields

Aljaedi,

Rashid,

Jamal

et al. 2023

Applied Sciences

View full text Add to dashboard Cite

show abstract

A Low-Complexity Edward-Curve Point Multiplication Architecture

et al. 2021

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The Binary Edwards Curves (BEC) are becoming more and more important, as compared to other forms of elliptic curves, thanks to their faster operations and resistance against side channel attacks. This work provides a low-complexity architecture for point multiplication computations using BEC over GF(2233). There are three major contributions in this article. The first contribution is the reduction of instruction-level complexity for unified point addition and point doubling laws by eliminating multiple operations in a single instruction format. The second contribution is the optimization of hardware resources by minimizing the number of required storage elements. Finally, the third contribution is to reduce the number of required clock cycles by incorporating a 32-bit finite field digit-parallel multiplier in the datapath. As a result, the achieved throughput over area ratio over GF(2233) on Virtex-4, Virtex-5, Virtex-6 and Virtex-7 Xilinx FPGA (Field Programmable Gate Array) devices are 2.29, 19.49, 21.5 and 20.82, respectively. Furthermore, on the Virtex-7 device, the required computation time for one point multiplication operation is 18 µs, while the power consumption is 266 mW. This reveals that the proposed architecture is best suited for those applications where the optimization of both area and throughput parameters are required at the same time.

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A Novel Low-Area Point Multiplication Architecture for Elliptic-Curve Cryptography

et al. 2021

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This paper presents a Point Multiplication (PM) architecture of Elliptic-Curve Cryptography (ECC) over GF(2163) with a focus on the optimization of hardware resources and latency at the same time. The hardware resources are reduced with the use of a bit-serial (traditional schoolbook) multiplication method. Similarly, the latency is optimized with the reduction in a critical path using pipeline registers. To cope with the pipelining, we propose to reschedule point addition and double instructions, required for the computation of a PM operation in ECC. Subsequently, the proposed architecture over GF(2163) is modeled in Verilog Hardware Description Language (HDL) using Vivado Design Suite. To provide a fair performance evaluation, we synthesize our design on various FPGA (field-programmable gate array) devices. These FPGA devices are Virtex-4, Virtex-5, Virtex-6, Virtex-7, Spartan-7, Artix-7, and Kintex-7. The lowest area (433 FPGA slices) is achieved on Spartan-7. The highest speed is realized on Virtex-7, where our design achieves 391 MHz clock frequency and requires 416 μs for one PM computation (latency). For power, the lowest values are achieved on the Artix-7 (56 μW) and Kintex-7 (61 μW) devices. A ratio of throughput over area value of 4.89 is reached for Virtex-7. Our design outperforms most recent state-of-the-art solutions (in terms of area) with an overhead of latency.

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High-Speed and Unified ECC Processor for Generic Weierstrass Curves over GF(p) on FPGA

Cited by 10 publications

References 12 publications

An Optimized Flexible Accelerator for Elliptic Curve Point Multiplication over NIST Binary Fields

An Optimized Flexible Accelerator for Elliptic Curve Point Multiplication over NIST Binary Fields

A Low-Complexity Edward-Curve Point Multiplication Architecture

A Novel Low-Area Point Multiplication Architecture for Elliptic-Curve Cryptography

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