低压高能效BiDPL逻辑设计与应用

Conference Proceedings. IEEE Canadian Conference on Electrical and Computer Engineering (Cat. No.98TH8341) Pub Date : 1998-05-24 DOI:10.1109/CCECE.1998.682733

M. Margala, N. G. Durdle, N.L. Rodnunsky

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引用次数: 0

摘要

本文提出了一种新的逻辑设计，双极双通晶体管逻辑(BiDPL)，并在全加法器中实现。在1.2 V和0.1至0.7 pF的输出负载下，新逻辑风格的功率效率比以前报道的低压BiCMOS风格高2.9倍，使用的开关功率减少16%至32%。在最优条件下(V /子dd / = 1.6 V),新设计18%功率效率高于传统CMOS逻辑pF 0.55比1的负载,117%更好的电源效率相比BiCMOS风格输出负荷的0.1到0.68 pF。当用于实现一个完整的加法器,它更低功耗非常低电源电压(1.1 - 2 V)比传统CMOS加法器的设计和最好的低压低功耗加法器在文献中报道。所提出的BiDPL加法器在1.5 V电压下的功率效率分别比两种设计高出61%和535%。

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Low-voltage power-efficient BiDPL logic design and applications

This paper presents a new logic design, bipolar double pass-transistor logic (BiDPL), and its implementation into a full-adder. At 1.2 V and output loads of 0.1 to 0.7 pF the new logic style has up to 2.9 times better power efficiency than previously reported low-voltage BiCMOS styles and uses between 16 to 32 % less switching power. Under optimal conditions (V/sub dd/=1.6 V), the new design has up to 18% higher power efficiency than conventional CMOS logic for loads of 0.55 to 1 pF and up to 117 % better power efficiency compared to BiCMOS styles for output loads of 0.1 to 0.68 pF. When used to implement a full adder, it is more power-efficient at very low power supply voltages (1.1 to 2 V) than a conventional CMOS adder design and the best low-voltage low-power adder reported in the literature. The proposed BiDPL adder outperforms in power efficiency both designs at 1.5 V by as much as 61 % and 535 % respectively.

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Conference Proceedings. IEEE Canadian Conference on Electrical and Computer Engineering (Cat. No.98TH8341)

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