Elliptic Curve Cryptography (ECC) has the highest safety strength of private key per bit in the Public-Key Cryptography recently.
椭圆曲线密码体制是目前公钥体制中每比特密钥安全强度最高的一种密码体制。
The finite field arithmetic, elliptic curve cryptography (ECC) and the finite field multiplier are investigated in this thesis.
本论文研究的主要内容是有限域算术、椭圆曲线加密算法和有限域乘法器。
To accelerate point multiplication operation of elliptic curve cryptography(ECC), a fast reduction algorithm for modular operation was introduced.
为了提高椭圆曲线密码(ECC)的点乘运算速度,提出了一种快速约简求模算法。
This work presents a dual-core two-field elliptic curve cryptosystem supporting several elliptic curve cryptography(ECC) protocols to accelerate signature generation and verification.
为了加快签名和验证的速度,给出了一种支持多种椭圆曲线密码(ECC)协议的双核双域ECC处理器结构。
Elliptical curve cryptography (ECC) is a public key encryption technique based on elliptic curve theory that can be used to create faster, smaller, and more efficient cryptographic keys.
椭圆曲线密码(ECC)是一个基于椭圆曲线理论的公钥加密技术,可以用来创造更快、更小、更高效的加密密钥。
Elliptic Curve Cryptography (ECC) is a rather complicated algorithm. It is difficult to design an application specific integrated circuit (ASIC) to fully implement ECC.
椭圆曲线密码(ECC)是一种非常复杂的数学算法,设计出能够完整实现ECC算法的专用集成电路芯片(ASIC)非常困难。
Based on the public key encryption, the elliptic curve cryptography (ECC) is the highest security encryption based on each bit and it is considered as the next multipurpose public cryptography.
基于公钥密码系统的椭圆曲线密码系统(ECC)是迄今为止每比特具有最高安全强度的密码系统,被认为是下一代通用的公钥密码系统。
The implementation speed of elliptic curve Cryptography (ECC) depends on the implementation speed of elliptic curve point multiplication.
椭圆曲线点乘的实现速度决定了椭圆曲线密码算法(ECC)的实现速度。
Analysis of finite field modular multiplication requirement of Elliptic Curve Cryptography (ECC), the application specific instruction for modular multiplication computation is designed in this paper.
针对椭圆曲线密码算法中有限域模乘运算的需求,提出其专用模乘指令。
Compared to RSA, with keys of the same length, Elliptic Curve Cryptography (ECC) offers more security strength, thus ECC-based digital signature scheme attracts the most attention.
与RSA密码体制相比,在密钥长度相同的情况下,椭圆曲线密码体制安全强度更高,因此基于椭圆曲线密码体制的数字签名方案得到了广泛的关注。
Compared to RSA, with keys of the same length, Elliptic Curve Cryptography (ECC) offers more security strength, thus ECC-based digital signature scheme attracts the most attention.
与RSA密码体制相比,在密钥长度相同的情况下,椭圆曲线密码体制安全强度更高,因此基于椭圆曲线密码体制的数字签名方案得到了广泛的关注。
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