An Optical Half Adder Using Nonlinear Ring Resonator Based on Photonic Crystal
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Mohsen Ebrahimi
Abstract
Nonlinear photonic crystal ring resonators are suitable mechanisms that can be used for designing optical logic gates and digital structures. In this paper, we designed two nonlinear resonant rings by adding doped glass rods inside the photonic crystal ring resonator. An optical half adder was designed using these nonlinear photonic crystal ring resonators. We used plane wave expansion and finite difference time domain methods to simulate our optical half adder. The simulations show that when one of the input ports is ON, the normalized optical power at the S is about 90 %. The time delay in this case is 7 ps. Also when both the input ports are ON, the normalized optical power at the C is about 155 %. The time delay in this case is 8 ps.
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© 2019 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- Amplifiers
- Unified Formalism for Erbium-Doped Fiber Amplifiers and Lasers
- Nonlinear Effects with Semiconductor Optical Amplifiers
- Average Power Model of Optical Raman Amplifiers Based on Frequency Spacing and Amplifier Section Stage Optimization
- Devices
- An Optical Half Adder Using Nonlinear Ring Resonator Based on Photonic Crystal
- Implementation of Polarization-Encoded Quantum Fredkin Gate Using Kerr Effect
- Lasers
- Spatial Continuous Wave Laser and Spatiotemporal VCSEL for High-Speed Long Haul Optical Wireless Communication Channels
- Measurements
- Graphene Oxide Effect on Improvement of Silver Surface Plasmon Resonance D-Shaped Optical Fiber Sensor
- Networks
- High-Speed Light Sources in High-Speed Optical Passive Local Area Communication Networks
- RSVP-TE Bilateral-Recursive Region Re-Routing Crankback Mechanism for Large-Scale Optical Networks
- An Intelligent Vehicle Control System for Enhancing Road Safety Using Optimal Visible Light Communication Network
- Systems
- Design and Parameter Analysis of Underwater Wireless Optical Communication with Different Water Samples
- Free Space Optical Communication System under Different Weather Conditions
- Windowing Techniques for Reducing PAPR of OFDM in Li-Fi Systems
- Effects of Order Super Gaussian Pulses on the Performance of High Data Rate Optical Fiber Channel in the Presence of Self Phase Modulation
- Evaluation of Proposed Coherent Optical OFDM Link Using X-QAM with Polarization Division Multiplexing
- Theory
- Mathematical Model Analysis of Dispersion and Loss in Photonic Crystal Fibers
- Simulation of Optical ISL with 48 Transponders and Performance Analysis Using Ber and Q-Factor
Artikel in diesem Heft
- Frontmatter
- Amplifiers
- Unified Formalism for Erbium-Doped Fiber Amplifiers and Lasers
- Nonlinear Effects with Semiconductor Optical Amplifiers
- Average Power Model of Optical Raman Amplifiers Based on Frequency Spacing and Amplifier Section Stage Optimization
- Devices
- An Optical Half Adder Using Nonlinear Ring Resonator Based on Photonic Crystal
- Implementation of Polarization-Encoded Quantum Fredkin Gate Using Kerr Effect
- Lasers
- Spatial Continuous Wave Laser and Spatiotemporal VCSEL for High-Speed Long Haul Optical Wireless Communication Channels
- Measurements
- Graphene Oxide Effect on Improvement of Silver Surface Plasmon Resonance D-Shaped Optical Fiber Sensor
- Networks
- High-Speed Light Sources in High-Speed Optical Passive Local Area Communication Networks
- RSVP-TE Bilateral-Recursive Region Re-Routing Crankback Mechanism for Large-Scale Optical Networks
- An Intelligent Vehicle Control System for Enhancing Road Safety Using Optimal Visible Light Communication Network
- Systems
- Design and Parameter Analysis of Underwater Wireless Optical Communication with Different Water Samples
- Free Space Optical Communication System under Different Weather Conditions
- Windowing Techniques for Reducing PAPR of OFDM in Li-Fi Systems
- Effects of Order Super Gaussian Pulses on the Performance of High Data Rate Optical Fiber Channel in the Presence of Self Phase Modulation
- Evaluation of Proposed Coherent Optical OFDM Link Using X-QAM with Polarization Division Multiplexing
- Theory
- Mathematical Model Analysis of Dispersion and Loss in Photonic Crystal Fibers
- Simulation of Optical ISL with 48 Transponders and Performance Analysis Using Ber and Q-Factor
