Differential Edge-Triggered Flip-Flops Using Neuron-MOS Transistors

2013 Ninth International Conference on Computational Intelligence and Security Pub Date : 2013-12-14 DOI:10.1109/CIS.2013.73
G. Hang, Xiaohui Hu, Hongli Zhu, X. You
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引用次数: 2

Abstract

Novel differential flip-flops using neuron-MOS transistors are presented, including single edge-triggered flipflop and double edge-triggered flip-flop. In the new differential flip-flops, a pair of n-channel multiple-input neuron-MOS pull down logic networks is used to replace the nMOS logic tree in the conventional differential flip-flops. The construction of the circuits has been simplified by employing the multiple-input neuron-MOS transistors. HSPICE simulations using TSMC 0.35μm 2-ploy 4-metal CMOS technology have verified the effectiveness of the proposed design scheme. The simulated results of propagation delay and power dissipation are also given.
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基于神经元- mos晶体管的差分边触发触发器
提出了基于神经元- mos晶体管的新型差分触发器,包括单沿触发触发器和双沿触发触发器。在新型差分触发器中,采用一对n通道多输入神经元- mos下拉逻辑网络来取代传统差分触发器中的nMOS逻辑树。采用多输入神经元- mos晶体管简化了电路的结构。采用台积电0.35μm 2-ploy 4金属CMOS技术进行HSPICE仿真,验证了该设计方案的有效性。给出了传输延迟和功耗的仿真结果。
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2013 Ninth International Conference on Computational Intelligence and Security
2013 Ninth International Conference on Computational Intelligence and Security
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