Neuron MOS Voltage-Mode Circuit Technology for Multiple-Valued Logic
Summary :
We have developed a new functional MOS transistor called Neuron MOSFET (abbreviated as neuMOS or νMOS) which simulates the function of biological neurons. The new transistor is capable of executing a weighted sum calculation of multiple input signals and threshold operation based on the result of weighted summation, all in the voltage mode at a single transistor level. By utilizing its neuron-like very powerful functional capability, various circuits essential for multiple-valued logic operation have been designed using quite simple circuit configurations. The circuit designs for data conversion between the multivalued and binary logic systems and for generating universal literal functions are described and their experimental verifications are presented. One of the most important features of νMOS multivalued lagic circuit is that the circuit operates basically in the voltage mode, thus greatly reducing the power dissipation as compared to the conventional current mode circuitry. This is indeed most essential in implementing multivalued logic systems in ultra large scale integration. Another important feature of νMOS design is in its flexibility of implementing logic functions. The functional form of a universal literal function, for instance, can be arbitrarily altered by external signals without any modifications in its hardware configuration. A circuit representing multiple-valued multithreshold functions is also proposed.
- Publication
- IEICE TRANSACTIONS on Electronics Vol.E76-C No.3 pp.347-356
- Publication Date
- 1993/03/25
- Publicized
- Online ISSN
- DOI
- Type of Manuscript
- Special Section INVITED PAPER (Special Issue on Multiple-Valued Integrated Circuits)
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Tadashi SHIBATA, Tadahiro OHMI, "Neuron MOS Voltage-Mode Circuit Technology for Multiple-Valued Logic" in IEICE TRANSACTIONS on Electronics,
vol. E76-C, no. 3, pp. 347-356, March 1993, doi: .
Abstract: We have developed a new functional MOS transistor called Neuron MOSFET (abbreviated as neuMOS or νMOS) which simulates the function of biological neurons. The new transistor is capable of executing a weighted sum calculation of multiple input signals and threshold operation based on the result of weighted summation, all in the voltage mode at a single transistor level. By utilizing its neuron-like very powerful functional capability, various circuits essential for multiple-valued logic operation have been designed using quite simple circuit configurations. The circuit designs for data conversion between the multivalued and binary logic systems and for generating universal literal functions are described and their experimental verifications are presented. One of the most important features of νMOS multivalued lagic circuit is that the circuit operates basically in the voltage mode, thus greatly reducing the power dissipation as compared to the conventional current mode circuitry. This is indeed most essential in implementing multivalued logic systems in ultra large scale integration. Another important feature of νMOS design is in its flexibility of implementing logic functions. The functional form of a universal literal function, for instance, can be arbitrarily altered by external signals without any modifications in its hardware configuration. A circuit representing multiple-valued multithreshold functions is also proposed.
URL: https://globals.ieice.org/en_transactions/electronics/10.1587/e76-c_3_347/_p
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@ARTICLE{e76-c_3_347,
author={Tadashi SHIBATA, Tadahiro OHMI, },
journal={IEICE TRANSACTIONS on Electronics},
title={Neuron MOS Voltage-Mode Circuit Technology for Multiple-Valued Logic},
year={1993},
volume={E76-C},
number={3},
pages={347-356},
abstract={We have developed a new functional MOS transistor called Neuron MOSFET (abbreviated as neuMOS or νMOS) which simulates the function of biological neurons. The new transistor is capable of executing a weighted sum calculation of multiple input signals and threshold operation based on the result of weighted summation, all in the voltage mode at a single transistor level. By utilizing its neuron-like very powerful functional capability, various circuits essential for multiple-valued logic operation have been designed using quite simple circuit configurations. The circuit designs for data conversion between the multivalued and binary logic systems and for generating universal literal functions are described and their experimental verifications are presented. One of the most important features of νMOS multivalued lagic circuit is that the circuit operates basically in the voltage mode, thus greatly reducing the power dissipation as compared to the conventional current mode circuitry. This is indeed most essential in implementing multivalued logic systems in ultra large scale integration. Another important feature of νMOS design is in its flexibility of implementing logic functions. The functional form of a universal literal function, for instance, can be arbitrarily altered by external signals without any modifications in its hardware configuration. A circuit representing multiple-valued multithreshold functions is also proposed.},
keywords={},
doi={},
ISSN={},
month={March},}
Copy
TY - JOUR
TI - Neuron MOS Voltage-Mode Circuit Technology for Multiple-Valued Logic
T2 - IEICE TRANSACTIONS on Electronics
SP - 347
EP - 356
AU - Tadashi SHIBATA
AU - Tadahiro OHMI
PY - 1993
DO -
JO - IEICE TRANSACTIONS on Electronics
SN -
VL - E76-C
IS - 3
JA - IEICE TRANSACTIONS on Electronics
Y1 - March 1993
AB - We have developed a new functional MOS transistor called Neuron MOSFET (abbreviated as neuMOS or νMOS) which simulates the function of biological neurons. The new transistor is capable of executing a weighted sum calculation of multiple input signals and threshold operation based on the result of weighted summation, all in the voltage mode at a single transistor level. By utilizing its neuron-like very powerful functional capability, various circuits essential for multiple-valued logic operation have been designed using quite simple circuit configurations. The circuit designs for data conversion between the multivalued and binary logic systems and for generating universal literal functions are described and their experimental verifications are presented. One of the most important features of νMOS multivalued lagic circuit is that the circuit operates basically in the voltage mode, thus greatly reducing the power dissipation as compared to the conventional current mode circuitry. This is indeed most essential in implementing multivalued logic systems in ultra large scale integration. Another important feature of νMOS design is in its flexibility of implementing logic functions. The functional form of a universal literal function, for instance, can be arbitrarily altered by external signals without any modifications in its hardware configuration. A circuit representing multiple-valued multithreshold functions is also proposed.
ER -
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