All-optical reversible PNOR logic gate using semiconductor optical amplifiers at 100 Gb/s

Amer Kotb; Kyriakos E. Zoiros; Eng Hwa Yap

doi:10.1117/1.OE.62.10.108101

All-optical reversible PNOR logic gate using semiconductor optical amplifiers at 100 Gb/s

Amer Kotb^*
, Kyriakos E. Zoiros
, Eng Hwa Yap^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

The loss of one bit of information causes energy dissipation in traditional logic gates at ambient temperature, but when the number of bits is greater, as in high-speed networks, the heat released by them is so great that it impacts performance and shortens component lifetime. Using reversible logic gates, which ideally result in zero energy dissipation, these problems in ordinary Boolean functions can be solved. At 100 Gb/s, an all-optical three-input-output reversible PNOR logic gate is numerically simulated in this article using semiconductor optical amplifiers (SOAs)based switching units. The quality factor (Q-factor) and the bit error rate (BER) are the metrics against which the performance of reversible PNOR operation is assessed. The results indicate the feasibility of realizing all-optically the PNOR gate at 100 Gb/s since the SOA-based scheme, along with correct logic operation, manages to achieve more than acceptable Q-factor and BER.

Original language	English
Article number	108101
Journal	Optical Engineering
Volume	62
Issue number	10
DOIs	https://doi.org/10.1117/1.OE.62.10.108101
Publication status	Published - Oct 2023

Keywords

bit error rate
quality factor
reversible optical PNOR logic gate
semiconductor optical amplifier

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10.1117/1.OE.62.10.108101

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title = "All-optical reversible PNOR logic gate using semiconductor optical amplifiers at 100 Gb/s",

abstract = "The loss of one bit of information causes energy dissipation in traditional logic gates at ambient temperature, but when the number of bits is greater, as in high-speed networks, the heat released by them is so great that it impacts performance and shortens component lifetime. Using reversible logic gates, which ideally result in zero energy dissipation, these problems in ordinary Boolean functions can be solved. At 100 Gb/s, an all-optical three-input-output reversible PNOR logic gate is numerically simulated in this article using semiconductor optical amplifiers (SOAs)based switching units. The quality factor (Q-factor) and the bit error rate (BER) are the metrics against which the performance of reversible PNOR operation is assessed. The results indicate the feasibility of realizing all-optically the PNOR gate at 100 Gb/s since the SOA-based scheme, along with correct logic operation, manages to achieve more than acceptable Q-factor and BER.",

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author = "Amer Kotb and Zoiros, \{Kyriakos E.\} and Yap, \{Eng Hwa\}",

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doi = "10.1117/1.OE.62.10.108101",

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T1 - All-optical reversible PNOR logic gate using semiconductor optical amplifiers at 100 Gb/s

AU - Kotb, Amer

AU - Zoiros, Kyriakos E.

AU - Yap, Eng Hwa

PY - 2023/10

Y1 - 2023/10

N2 - The loss of one bit of information causes energy dissipation in traditional logic gates at ambient temperature, but when the number of bits is greater, as in high-speed networks, the heat released by them is so great that it impacts performance and shortens component lifetime. Using reversible logic gates, which ideally result in zero energy dissipation, these problems in ordinary Boolean functions can be solved. At 100 Gb/s, an all-optical three-input-output reversible PNOR logic gate is numerically simulated in this article using semiconductor optical amplifiers (SOAs)based switching units. The quality factor (Q-factor) and the bit error rate (BER) are the metrics against which the performance of reversible PNOR operation is assessed. The results indicate the feasibility of realizing all-optically the PNOR gate at 100 Gb/s since the SOA-based scheme, along with correct logic operation, manages to achieve more than acceptable Q-factor and BER.

AB - The loss of one bit of information causes energy dissipation in traditional logic gates at ambient temperature, but when the number of bits is greater, as in high-speed networks, the heat released by them is so great that it impacts performance and shortens component lifetime. Using reversible logic gates, which ideally result in zero energy dissipation, these problems in ordinary Boolean functions can be solved. At 100 Gb/s, an all-optical three-input-output reversible PNOR logic gate is numerically simulated in this article using semiconductor optical amplifiers (SOAs)based switching units. The quality factor (Q-factor) and the bit error rate (BER) are the metrics against which the performance of reversible PNOR operation is assessed. The results indicate the feasibility of realizing all-optically the PNOR gate at 100 Gb/s since the SOA-based scheme, along with correct logic operation, manages to achieve more than acceptable Q-factor and BER.

KW - bit error rate

KW - quality factor

KW - reversible optical PNOR logic gate

KW - semiconductor optical amplifier

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VL - 62

JO - Optical Engineering

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ER -

All-optical reversible PNOR logic gate using semiconductor optical amplifiers at 100 Gb/s

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