FPGA Implementation of Enhanced Throughput Design of AES Architecture using Nikhilam Sutra

International Journal of Electrical Engineering and Computer Science Pub Date : 2022-10-31 DOI:10.37394/232027.2022.4.8

B. Pasuluri, V. K. Sonti

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Abstract

The exponential growth of the internet and contemporary communications users have established safety as a fundamental design feature for encrypted transmission. The Enhanced Cryptography Standard is perhaps the most widely used cryptography information security algorithm standard that has been authorized by NIST. This paper proposes a high-throughput design for the AES Algorithm with huge key sizes. AES would be a block cipher that ensures data security by using key lengths of 128,192 and 256-bits. The design concept focuses on a 256-bit key size classification algorithm since a big key size is required to ensure excellent security. Additionally, simultaneous key expansion & encryption/decryption processes would be pipelined to maximize speed. Parallelization of a key expansion module's sub-processes would be used to reduce the critical chain latency. The S-box comprising sub-byte & inverse sub-byte operations has been developed with compound field arithmetic operations to reduce time and area further. The work Increased throughput by 50%, area reduced by 34.32 %, and latency by 20% compared to the old approach with modified nikhilam sutra. Additionally, integrated AES encryption/decryption is planned and implemented on the FPGA Zed board utilizing Verilog HDL in Xilinx Vivado.

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基于Nikhilam Sutra的AES架构增强吞吐量设计的FPGA实现

互联网和当代通信用户的指数级增长已经将安全作为加密传输的基本设计特征。增强型密码学标准可能是NIST授权的使用最广泛的密码学信息安全算法标准。本文提出了一种针对大密钥大小的AES算法的高吞吐量设计。AES是一种分组密码，通过使用128、192和256位的密钥长度来确保数据安全。设计理念是采用256位密钥大小的分类算法，因为需要较大的密钥大小来保证良好的安全性。此外，同步密钥扩展和加密/解密过程将被流水线化，以最大限度地提高速度。关键扩展模块子进程的并行化将用于减少关键链延迟。采用复合域算术运算开发了包含子字节和逆子字节运算的s盒，进一步减少了时间和面积。与修改nikhilam经的旧方法相比，该工作增加了50%的吞吐量，减少了34.32%的面积，延迟减少了20%。此外，利用Xilinx Vivado中的Verilog HDL，在FPGA Zed板上规划和实现了集成的AES加密/解密。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Journal of Electrical Engineering and Computer Science

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