Performance Analysis of Laser Phase Noise Compensated COOFDM System
-
Divya Dhawan
and
Neena Gupta
Abstract
Orthogonal Frequency Division Multiplexing along with the coherent detection and spectrally efficient modulation formats is a promising solution for long haul and high speed communication systems. Although they offer significant advantages which make them suitable for high speed and long haul communication systems they all are susceptible to phase noise. In this paper a combination of RF-pilot-based approach followed by pilot-based equalization approach is used for laser phase noise compensation. The various parameters such as drive voltage, bias voltage and extinction ratio are optimized to get the optimum performance from the proposed scheme. The designed system is then analyzed in terms of Symbol Error Rate (SER), constellation diagrams and error vector magnitude using various types of Quadrature Amplitude Modulation (QAM) formats.
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Articles in the same Issue
- Frontmatter
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- Combined Effect of ASE Noise and SRS Induced Crosstalk on the BER Performance of a Single Span WDM System with Raman Amplifier Using Heterodyne Coherent Detection
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- Design of a High-Quality Optical Filter Based on 2D Photonic Crystal Ring Resonator for WDM Systems
- Reflective Detection Method of Partial Discharge Using Optical Fiber Sensor
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- Effect of Soft Glass Rod Infiltration in the Core of Photonic Crystal Fiber
- Prediction of First Higher Order Modal Field for Graded Index Fiber in Presence of Kerr Nonlinearity
- Extremely Low Loss of Photonic Crystal Fiber for Terahertz Wave Propagation in Optical Communication Applications
- Networks
- Evaluation of Network Blocking Probability and Network Utilization Efficiency on Proposed Elastic Optical Network using RSA Algorithms
- Performance Analysis of a Novel 2-D Code in the Network Access Segment
- Systems
- To Decrease Maintenance Issues using FWM in Ultradense WDM Systems and Enhancing Optimum Placement of Optical Phase Conjugation
- Simulation-Based Optical Threshold Component Design for Mitigating Four-Wave Mixing Effects in WDM Radio Over Fiber Systems
- PAPR Reduction in OFDM Signal by Incorporating Mu-Law Companding Approach into Enhanced PTS Scheme
- Performance Analysis of Laser Phase Noise Compensated COOFDM System
- Performance Analysis of a Multiple Subcarrier Modulated FSO Communication System using Direct Detection Optical Receiver under the Effect of Weak Atmospheric Turbulence
- Analysis of Free Space Optics Link Performance Considering the Effect of Different Weather Conditions and Modulation Formats for Terrestrial Communication
Articles in the same Issue
- Frontmatter
- Amplifiers
- Performance Analysis of Homodyne-Based FSO System Using Various Optical Amplifiers
- Combined Effect of ASE Noise and SRS Induced Crosstalk on the BER Performance of a Single Span WDM System with Raman Amplifier Using Heterodyne Coherent Detection
- Devices
- Design of a High-Quality Optical Filter Based on 2D Photonic Crystal Ring Resonator for WDM Systems
- Reflective Detection Method of Partial Discharge Using Optical Fiber Sensor
- Fibers
- Effect of Soft Glass Rod Infiltration in the Core of Photonic Crystal Fiber
- Prediction of First Higher Order Modal Field for Graded Index Fiber in Presence of Kerr Nonlinearity
- Extremely Low Loss of Photonic Crystal Fiber for Terahertz Wave Propagation in Optical Communication Applications
- Networks
- Evaluation of Network Blocking Probability and Network Utilization Efficiency on Proposed Elastic Optical Network using RSA Algorithms
- Performance Analysis of a Novel 2-D Code in the Network Access Segment
- Systems
- To Decrease Maintenance Issues using FWM in Ultradense WDM Systems and Enhancing Optimum Placement of Optical Phase Conjugation
- Simulation-Based Optical Threshold Component Design for Mitigating Four-Wave Mixing Effects in WDM Radio Over Fiber Systems
- PAPR Reduction in OFDM Signal by Incorporating Mu-Law Companding Approach into Enhanced PTS Scheme
- Performance Analysis of Laser Phase Noise Compensated COOFDM System
- Performance Analysis of a Multiple Subcarrier Modulated FSO Communication System using Direct Detection Optical Receiver under the Effect of Weak Atmospheric Turbulence
- Analysis of Free Space Optics Link Performance Considering the Effect of Different Weather Conditions and Modulation Formats for Terrestrial Communication
