A Thermally Stable Quasi-CMOS Bipolar Logic

Kuźmicz, Wiesław

doi:10.20944/preprints202111.0473.v1

2021

DOI: 10.20944/preprints202111.0473.v1

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A Thermally Stable Quasi-CMOS Bipolar Logic

Wiesław Kuźmicz¹

Abstract: Logic gates made of pairs of NPN and PNP bipolar transistors, similar to CMOS logic gates, have been proposed and patented long ago but did not find any practical application until now. Other bipolar technologies (TTL, TTL-S, ECL), once the technologies of choice for digital systems, were abandoned and superseded by CMOS. In this paper it is shown that now, when truly com-plementary pairs of bipolar transistors can be made, properly biased bipolar gates similar to CMOS gates are feasible, can be thermally stab… Show more

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VES-BJT: A Lateral Bipolar Transistor on SOI with Polysilicon Emitter and Collector

Mierzwinski

Kuźmicz

2023

Electronics

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This paper summarizes the results of investigations of bipolar transistors made in VESTIC (Vertical Slit Transistor-based Integrated Circuits) technology. This technology was proposed by W. Maly as an alternative to classical bulk CMOS technology. However, the basic VESTIC cell can be used not only to make field effect transistors but also to make bipolar transistors. Their structures differ in many ways from existing structures of bipolar transistors. The investigations reported here aim to answer the question: can VESTIC-based lateral bipolar transistors be useful as active devices, and can they be made technologically compatible with field effect VESTIC devices? The theoretical studies were followed by the fabrication and measurements of VESTIC-based p-n-p and n-p-n bipolar devices. Although the manufacturing technology available was far from optimal, working bipolar devices were obtained. The results show that VESTIC-based bipolar devices may achieve acceptable parameters if made with state-of-the-art manufacturing technology. The main outcome of the research reported in the paper is that p-n-p and n-p-n bipolar transistors with acceptable parameters may be fabricated, together with field effect devices, in VESTIC-based integrated circuits. As a result, the VESTIC technology could become the new original BiCMOS technology.

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VES-BJT: A Lateral Bipolar Transistor on SOI with Polysilicon Emitter and Collector

Mierzwinski

Kuźmicz

2023

Electronics

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show abstract

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A Thermally Stable Quasi-CMOS Bipolar Logic

Cited by 1 publication

References 10 publications

VES-BJT: A Lateral Bipolar Transistor on SOI with Polysilicon Emitter and Collector

VES-BJT: A Lateral Bipolar Transistor on SOI with Polysilicon Emitter and Collector

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