Architectural Optimization for a 1.82Gbits/sec VLSI Implementation of the AES Rijndael Algorithm

机译：AES Rijndael算法的1.82Gbits / sec VLSI实现的体系结构优化

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This paper discusses the architectural optimizations for a special purpose ASIC processor that implements the AES Rijndael Algorithm. In October 2000 the NIST chose Rijndael as the new Advanced Encryption Standard (AES). The algorithm has variable key length and block length between 128, 192, or 256 bits. VLSI architectural optimizations such as parallelism and distributed memory are discussed, and several hardware design techniques are employed to increase performance and reduce area consumption. The hardware architecture is described using Verilog XL and synthesized by Synopsys with a 0.18μm standard cell library. Results show that with a design of 173,000 gates, data encryption can be done at a rate of 1.82 Gbits/sec.

机译：本文讨论了实现AES Rijndael算法的专用ASIC处理器的体系结构优化。 NIST在2000年10月选择Rijndael作为新的高级加密标准（AES）。该算法的密钥长度可变，块长度在128、192或256位之间。讨论了诸如并行性和分布式内存之类的VLSI体系结构优化，并采用了几种硬件设计技术来提高性能并减少面积消耗。使用Verilog XL描述了硬件架构，并由Synopsys使用0.18μm标准单元库进行了合成。结果表明，采用173,000个门的设计，可以以1.82 Gbits / sec的速率完成数据加密。

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来源
《Third International Workshop on Cryptographic Hardware and Embedded Systems - CHES 2001, May 14-16, 2001, Paris, France》|2001年|p.51-64|共14页
会议地点 Paris(FR);Paris(FR)
作者
Henry Kuo; Ingrid Verbauwhede;
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Electrical Engineering Department, University of California Los Angeles.;

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原文格式 PDF
正文语种 eng
中图分类自动化技术、计算机技术;
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1. Architectures and VLSI implementations of the AES-Proposal Rijndael [J] . Sklavos N., Koufopavlou O. IEEE Transactions on Computers . 2002,第12期

机译：AES提案Rijndael的体系结构和VLSI实现
2. An Implementation of Catmap-Rijndael (AES) Algorithm For Image Security (Case Study on A Software For Making Students Card At Universitas Jenderal Soedirman) [J] . Bangun Wijayanto, Retantyo Wardoyo Indonesian Journal of Computing and Cybernetics Systems . 2011,第1期

机译：用于图像安全的Catmap-Rijndael（AES）算法的实现（以Universitas Jenderal Soedirman的学生证制作软件为例）
3. Power efficient and high performance VLSI architecture for AES algorithm [J] . K. Kalaiselvi, H. Mangalam Journal of Electrical Systems and Information Technology . 2015,第2期

机译：高效节能的AES算法VLSI架构
4. Architectural Optimization for a 1.82Gbits/sec VLSI Implementation of the AES Rijndael Algorithm [C] . Henry Kuo, Ingrid Verbauwhede International workshop on cryptographic hardware and embedded systems . 2001

机译：AES Rijndael算法的1.82gbits / sec VLSI实现的建筑优化
5. An Ultra Low Power VLSI Implementation of the 128-Bit AES Algorithm Using a Novel Approach to the ShiftRow Transformation [D] . Muthineni, Alekhya. 2017

机译：使用新颖的方法到Shiftrow变换的128位AES算法的超低功率VLSI实现
6. An Efficient VLSI Architecture for Multi-Channel Spike Sorting Using a Generalized Hebbian Algorithm [O] . Ying-Lun Chen, Wen-Jyi Hwang, Chi-En Ke 2015

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7. Architectural Optimization for a 1.82Gbits/sec VLSI Implementation of the AES Rijndael Algorithm [O] . Henry Kuo, Ingrid Verbauwhede 2001

机译：AES Rijndael算法的1.82Gbit / sec VLSI实现的体系结构优化
8. Parallel optimization algorithms and their implementation in VLSI design [R] . Lee, G., Feeley, J. J. 1991

机译：并行优化算法及其在VLsI设计中的实现

Architectural Optimization for a 1.82Gbits/sec VLSI Implementation of the AES Rijndael Algorithm

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