2 × 2 compact silicon waveguide-based optical logic functions at 1.55 μm

Amer Kotb; Kyriakos E. Zoiros

doi:10.3390/photonics10040403

2 × 2 compact silicon waveguide-based optical logic functions at 1.55 μm

Amer Kotb^*, Kyriakos E. Zoiros

^*Corresponding author for this work

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

3 Citations (Scopus)

Abstract

Compact waveguide crossing is a fundamental component of optoelectronic fusion chip solutions due to its orders-of-magnitude smaller footprint than that of conventional photonic integrated circuits. In this paper, we suggest 2 × 2 compact silicon-on-silica waveguides that can implement all of the fundamental Boolean logic functions, including XOR, AND, OR, NOT, NOR, XNOR, and NAND, operated at 1.55 μm. Three input waveguides, one output waveguide, and a design area compose the proposed waveguide. The execution of the specified logic gates relies on the constructive and destructive interferences produced by the phase variations between the input beams. The contrast ratio (CR) is employed as a performance metric to assess how well these logic functions operate. In comparison to other reported designs, the proposed waveguide achieves higher CRs at a high speed of 120 Gb/s.

Original language	English
Article number	403
Journal	MDPI Photonics
Volume	10
Issue number	4
DOIs	https://doi.org/10.3390/photonics10040403
Publication status	Published - Apr 2023
Externally published	Yes

Keywords

contrast ratio
logic functions
waveguide crossing

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10.3390/photonics10040403

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abstract = "Compact waveguide crossing is a fundamental component of optoelectronic fusion chip solutions due to its orders-of-magnitude smaller footprint than that of conventional photonic integrated circuits. In this paper, we suggest 2 × 2 compact silicon-on-silica waveguides that can implement all of the fundamental Boolean logic functions, including XOR, AND, OR, NOT, NOR, XNOR, and NAND, operated at 1.55 μm. Three input waveguides, one output waveguide, and a design area compose the proposed waveguide. The execution of the specified logic gates relies on the constructive and destructive interferences produced by the phase variations between the input beams. The contrast ratio (CR) is employed as a performance metric to assess how well these logic functions operate. In comparison to other reported designs, the proposed waveguide achieves higher CRs at a high speed of 120 Gb/s.",

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AU - Zoiros, Kyriakos E.

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N2 - Compact waveguide crossing is a fundamental component of optoelectronic fusion chip solutions due to its orders-of-magnitude smaller footprint than that of conventional photonic integrated circuits. In this paper, we suggest 2 × 2 compact silicon-on-silica waveguides that can implement all of the fundamental Boolean logic functions, including XOR, AND, OR, NOT, NOR, XNOR, and NAND, operated at 1.55 μm. Three input waveguides, one output waveguide, and a design area compose the proposed waveguide. The execution of the specified logic gates relies on the constructive and destructive interferences produced by the phase variations between the input beams. The contrast ratio (CR) is employed as a performance metric to assess how well these logic functions operate. In comparison to other reported designs, the proposed waveguide achieves higher CRs at a high speed of 120 Gb/s.

AB - Compact waveguide crossing is a fundamental component of optoelectronic fusion chip solutions due to its orders-of-magnitude smaller footprint than that of conventional photonic integrated circuits. In this paper, we suggest 2 × 2 compact silicon-on-silica waveguides that can implement all of the fundamental Boolean logic functions, including XOR, AND, OR, NOT, NOR, XNOR, and NAND, operated at 1.55 μm. Three input waveguides, one output waveguide, and a design area compose the proposed waveguide. The execution of the specified logic gates relies on the constructive and destructive interferences produced by the phase variations between the input beams. The contrast ratio (CR) is employed as a performance metric to assess how well these logic functions operate. In comparison to other reported designs, the proposed waveguide achieves higher CRs at a high speed of 120 Gb/s.

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2 × 2 compact silicon waveguide-based optical logic functions at 1.55 μm

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Keywords

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