Pulse latch based FSRs for low-overhead hardware implementation of cryptographic algorithms

机译：基于脉冲锁存器的C加密算法的低开销硬件实现的FSR

获取原文

页面导航

摘要
著录项
相似文献
相关主题

摘要

In this paper, we address the problem of low-overhead implementation of Feedback Shift Registers (FSRs). We present a dynamic pulse latch which is based on transistors with two different channel lengths. The channel lengths are selected to make the latch suitable for replacing flip-flops in FSRs. The presented latch is 1.92 times smaller and 3.94 times less power consuming compared to the smallest standard flip-flop in the same technology. By re-implementing FSRs of Grain-80 stream cipher with the presented latch, we achieve 32.24% reduction in area, 36.77% reduction in total power, and 10.81% increase in the maximum clock frequency compared to the original, flip-flop based version of Grain-80. If, in addition, the static time borrowing technique is applied, we achieve an additional 25.5% increase in the maximum clock frequency at the expense of 4.68% smaller gain in area and 2.67% smaller gain in total power.

机译：在本文中，我们解决了反馈换档寄存器（FSR）的低开销实施问题。我们介绍了一种动态脉冲锁存器，基于具有两个不同通道长度的晶体管。选择通道长度以使闩锁适于在FSR中更换触发器。与相同技术中最小的标准触发器相比，所呈现的闩锁比相比最小的标准触发器更小的1.92倍，功率少3.94倍。通过使用所提出的闩锁重新实现谷物-80流密码的FSR，我们的面积减少32.24％，总功率降低36.77％，最大时钟频率增加了10.81％，而最大的时钟频率增加了与原始的，触发器的版本相比谷物80。如果另外，如果应用静态时间借用技术，我们的最大时钟频率额外增加25.5％，以牺牲区的最大增长为4.68％，总功率增益2.67％。

著录项

来源
《IEEE International Conference on Computer Design》|2010年||共7页
会议地点
作者
Sharif Mansouri Shohreh; Dubrova Elena;
展开▼
作者单位

展开▼
会议组织
原文格式 PDF
正文语种
中图分类 TP3-53;
关键词

相似文献

外文文献
中文文献
专利

1. Hardware implementation of pulsed neuron with GHA learning rule based on △∑ modulation, Pulsed neuron, Hardware implementation [J] . Yoshimitsu Murahashi, Yuya Oota, Shinji Doki, 電子情報通信学会技術研究報告. ニュ-ロコンピュ-ティング. Neurocomputing . 2000,第688期

机译：基于△∑调制的具有GHA学习规则的脉冲神经元的硬件实现，脉冲神经元，硬件实现
2. Hardware implementation of pulsed neuron with GHA learning rule based on △∑ modulation, Pulsed neuron, Hardware implementation [J] . Yoshimitsu Murahashi, Yuya Oota, Shinji Doki, 電子情報通信学会技術研究報告. ニュ-ロコンピュ-ティング. Neurocomputing . 2000,第688期

机译：基于△Σ调制，脉冲神经元，硬件实现，具有GHA学习规则的脉冲神经元的硬件实现
3. Hardware implementation of pulsed neural networks based on delta-sigma modulation with back propagation learning algorithm [J] . Tadayoshi Okuda, Shinji Doki, Muneaki Ishida 電子情報通信学会技術研究報告. ニュ-ロコンピュ-ティング. Neurocomputing . 2002,第729期

机译：反向传播学习算法基于delta-sigma调制的脉冲神经网络的硬件实现
4. Pulse latch based FSRs for low-overhead hardware implementation of cryptographic algorithms [C] . Sharif Mansouri Shohreh, Dubrova Elena 2010 IEEE International Conference on Computer Design . 2010

机译：基于脉冲锁存的FSR用于加密算法的低开销硬件实现
5. FPGA-Based Hardware Implementation of Image Processing Algorithms for Real-Time Vehicle Detection Applications. [D] . Li, Peng. 2012

机译：用于实时车辆检测应用的图像处理算法的基于FPGA的硬件实现。
6. A soft decoding algorithm and hardware implementation for the visual prosthesis based on high order soft demodulation [O] . Yuan Yang, Nannan Quan, Jingjing Bu, 2016

机译：基于高阶软解调的视觉假体软解码算法及硬件实现
7. Compact FPGA Hardware Platform for Power Analysis Attacks on Cryptographic Algorithms Implementations [O] . Martin PETRVALSKY, Milos DRUTAROVSKY, Michal VARCHOLA 2016

机译：紧凑型FPGA硬件平台，用于加密算法的电力分析攻击
8. Public-Key Cryptography: A Hardware Implementation and Novel Neural Network-Based Approach. [R] . Nguyen, P. 1992

机译：公钥密码学：硬件实现和新颖的基于神经网络的方法。

Pulse latch based FSRs for low-overhead hardware implementation of cryptographic algorithms

摘要

著录项

相似文献

相关主题

期刊订阅