Ultra-compact all-optical half-adder realized by a modular-inverse-design method

•An all-optical half-adder smaller than 10 × 5 μm2 is designed by a new proposed Modular-inverse-design method.•Five modules with different functions are realized in a same area of 2 μm × 2 μm.•Remarkable contrast ratio is around 7 dB and 15 dB for SUM and CARRY.•The half-adder could reach a high re...

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Bibliographic Details
Published inPhotonics and nanostructures Vol. 42; p. 100860
Main Authors Lu, Qichao, Yan, Xin, Zhang, Yangan, Zhang, Xia, Ren, Xiaomin
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 01.12.2020
Elsevier Science Ltd
Subjects
All-optical half-adder
Beam splitters
Design techniques
Finite difference time domain method
Gates (circuits)
Modular design
Modular-inverse-design
Multiple objective analysis
Optical computing
Photonicintegrated circuits
Time domain analysis
Photonicintegrated circuits
Modular-inverse-design
All-optical half-adder
Optical computing
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Summary:•An all-optical half-adder smaller than 10 × 5 μm2 is designed by a new proposed Modular-inverse-design method.•Five modules with different functions are realized in a same area of 2 μm × 2 μm.•Remarkable contrast ratio is around 7 dB and 15 dB for SUM and CARRY.•The half-adder could reach a high respond speed beyond 1.4 THz. An ultra-compact all-optical half-adder operating at 1550 nm on silicon-on-insulator is realized by a modular-inverse-design method which deconstruct the design of optical units with complicated functions to several devices with basic functions. The half adder is composed of five modules: two beam splitters, one hub, one XOR gate and one AND gate, all of which are designed by the same multi-objective particle swarm optimized method and have the equal area of 2 μm × 2 μm. The system is studied numerically by the Finite Difference Time Domain method. Remarkable contrast ratios of 12.0 dB and 8.45 dB are obtained for AND gate and XOR gate, respectively. The whole half-adder possesses an ultra-small area smaller than 10 μm × 5 μm, which results in a short respond time less than 0.7 ps and high respond speed beyond 1.4 THz. The contrast ratio between two output logic states “1” and “0” is around 7 dB and 15 dB for SUM and CARRY, respectively. The half-adder designed by modular-inverse-design method possess advantages such as tiny size, fast respond and high diversity, which indicates that our method has great potential as a universal method for the design of complicated integrated devices.
ISSN:1569-4410
1569-4429
DOI:10.1016/j.photonics.2020.100860