Performance analysis of polymer optical fibre based Fabry-Perot sensor formed by two uniform Bragg gratings

Keyphrases

• Bragg Gratings 100%
• Fiber-based 100%
• Polymer Optical Fiber 100%
• Performance Analysis 100%
• Fabry-Perot Sensor 100%
• Grating 57%
• Interferometer 42%
• Stress Sensitivity 42%
• Cavity Length 28%
• Attenuation 28%
• Fiber Loss 28%
• Silica 28%
• Finite Dimension 28%
• Numerical Model 14%
• Reflectivity 14%
• Finesse 14%
• Optical Fiber Sensor 14%
• Operating Wavelength 14%
• Physical Properties 14%
• Optical Path 14%
• Biocompatibility 14%
• High-performance Fibers 14%
• Material Properties 14%
• Optical Properties 14%
• Refractive Index Modulation 14%
• Effective Length 14%
• Polymer Materials 14%
• Failure Strain 14%
• Fabry-Perot Interferometer 14%
• Low Young's Modulus 14%
• Silica-based 14%
• Highly Elastic 14%
• Force Detection 14%
• Acoustic Waves 14%
• Optical Fiber Technology 14%

Engineering

• Bragg Cell 100%
• Fabry-Perot Sensor 100%
• Performance Analysis 100%
• Plastic Optical Fibers 100%
• Silicon Dioxide 42%
• Cavity Length 28%
• Fiber Loss 28%
• Optical Path 14%
• Reflectance 14%
• Numerical Model 14%
• Fabry Perot 14%
• Grating Length 14%
• Operating Wavelength 14%
• Main Advantage 14%
• Young's Modulus 14%
• Refractive Index Modulation 14%
• Effective Length 14%
• Perot Interferometer 14%
• Polymer Material 14%
• Failure Strain 14%
• Optical Fibre Technology 14%

Material Science

• Glass Fiber 100%
• Interferometer 57%
• Silicon Dioxide 42%
• Refractive Index 14%
• Reflectivity 14%
• Physical Property 14%
• Young's Modulus 14%
• Poly Methyl Methacrylate 14%
• Biocompatibility 14%
• Optical Property 14%
• Materials Property 14%