1.
Popescu, Mihai; Ravariu, Cristian; Hascsi, Zoltan
First and Second Order Digital Circuits with Neuronal Models under Pulses Train Stimulus Journal Article
In: ROMANIAN JOURNAL OF INFORMATION SCIENCE AND TECHNOLOGY, vol. 28, no. 2, pp. 223-232, 2025, ISSN: 1453-8245.
Abstract | Links | BibTeX | Tags: Circuits; flip-flop; logic block; neurons; pulses train
@article{WOS:001538680900010,
title = {First and Second Order Digital Circuits with Neuronal Models under
Pulses Train Stimulus},
author = {Mihai Popescu and Cristian Ravariu and Zoltan Hascsi},
doi = {10.59277/ROMJIST.2025.2.09},
issn = {1453-8245},
year = {2025},
date = {2025-01-01},
journal = {ROMANIAN JOURNAL OF INFORMATION SCIENCE AND TECHNOLOGY},
volume = {28},
number = {2},
pages = {223-232},
publisher = {EDITURA ACAD ROMANE},
address = {CALEA 13 SEPTEMBRIE NR 13, SECTOR 5, BUCURESTI 050711, ROMANIA},
abstract = {One or more neurons can be perceived as an analog circuit in terms of
their voltage-time characteristics, but at the block level, they can
rather fulfill a logic function. This later approach is imposed by the
neuron membrane behavior that always works between two voltage levels -
the resting potential and the acting potential, easily associated to two
binary states. These levels change when an appropriate combination of
pulses trains appears on the neuron's exciting and inhibiting input
synapses. Being difficult to describe in all details the neuronal
processes inside the human brain, this paper proposes some digital
models able to mimic these biological processes. The first original
element of this paper is the extension of the neuronal models,
previously presented, from 0-order logic circuits to 1-order logic and
2-order logic circuits. The envelope signal shelters the pulses train
that stimulate any neuron, and this envelope signal signature as the
digital function represents an element of originality.},
keywords = {Circuits; flip-flop; logic block; neurons; pulses train},
pubstate = {published},
tppubtype = {article}
}
One or more neurons can be perceived as an analog circuit in terms of
their voltage-time characteristics, but at the block level, they can
rather fulfill a logic function. This later approach is imposed by the
neuron membrane behavior that always works between two voltage levels -
the resting potential and the acting potential, easily associated to two
binary states. These levels change when an appropriate combination of
pulses trains appears on the neuron's exciting and inhibiting input
synapses. Being difficult to describe in all details the neuronal
processes inside the human brain, this paper proposes some digital
models able to mimic these biological processes. The first original
element of this paper is the extension of the neuronal models,
previously presented, from 0-order logic circuits to 1-order logic and
2-order logic circuits. The envelope signal shelters the pulses train
that stimulate any neuron, and this envelope signal signature as the
digital function represents an element of originality.
their voltage-time characteristics, but at the block level, they can
rather fulfill a logic function. This later approach is imposed by the
neuron membrane behavior that always works between two voltage levels -
the resting potential and the acting potential, easily associated to two
binary states. These levels change when an appropriate combination of
pulses trains appears on the neuron's exciting and inhibiting input
synapses. Being difficult to describe in all details the neuronal
processes inside the human brain, this paper proposes some digital
models able to mimic these biological processes. The first original
element of this paper is the extension of the neuronal models,
previously presented, from 0-order logic circuits to 1-order logic and
2-order logic circuits. The envelope signal shelters the pulses train
that stimulate any neuron, and this envelope signal signature as the
digital function represents an element of originality.