• Title/Summary/Keyword: right-shift binary inversion

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Efficient Design and Performance Analysis of a Hardware Right-shift Binary Modular Inversion Algorithm in GF(p)

  • Choi, Piljoo;Lee, Mun-Kyu;Kong, Jeong-Taek;Kim, Dong Kyue
    • JSTS:Journal of Semiconductor Technology and Science
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    • v.17 no.3
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    • pp.425-437
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    • 2017
  • For efficient hardware (HW) implementation of elliptic curve cryptography (ECC), various sub-modules for the underlying finite field operations should be implemented efficiently. Among these sub-modules, modular inversion (MI) requires the most computation; therefore, its performance might be a dominant factor of the overall performance of an ECC module. To determine the most efficient MI algorithm for an HW ECC module, we implement various classes of MI algorithms and analyze their performance. In contrast to the common belief in previous research, our results show that the right-shift binary inversion (RS) algorithm performs well when implemented in hardware. In addition, we present optimization methods to reduce the area overhead and improve the speed of the RS algorithm. By applying these methods, we propose a new RS-variant that is both fast and compact. The proposed MI module is more than twice as fast as the other two classes of MI: shifting Euclidean (SE) and left-shift binary inversion (LS) algorithms. It consumes only 15% more area and even 5% less area than SE and LS, respectively. Finally, we show that how our new method can be applied to optimize an HW ECC module.

Efficient Hardware Montgomery Modular Inverse Module for Elliptic Curve Cryptosystem in GF(p) (GF(p)의 타원곡선 암호 시스템을 위한 효율적인 하드웨어 몽고메리 모듈러 역원기)

  • Choi, Piljoo;Kim, Dong Kyue
    • Journal of Korea Multimedia Society
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    • v.20 no.2
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    • pp.289-297
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    • 2017
  • When implementing a hardware elliptic curve cryptosystem (ECC) module, the efficient design of Modular Inverse (MI) algorithm is especially important since it requires much more computation than other finite field operations in ECC. Among the MI algorithms, binary Right-Shift modular inverse (RS) algorithm has good performance when implemented in hardware, but Montgomery Modular Inverse (MMI) algorithm is not considered in [1, 2]. Since MMI has a similar structure to that of RS, we show that the area-improvement idea that is applied to RS is applicable to MMI, and that we can improve the speed of MMI. We designed area- and speed-improved MMI variants as hardware modules and analyzed their performance.