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010 a| 2018302587;

020 a| 9780128031315q| (paperback);

020 a| 012803131Xq| (paperback);

020 z| 9780128031469q| (eBook);

035 a| (WaSeSS)ssj0002063141;

042 a| lccopycat;

049 a| EREEa| NEHH;

050 00 a| TA1815b| .O78 2018;

082 04 a| 681.252| 23;

245 00 a| Opto-mechanical fiber optic sensorsh| [electronic resource] :b| research, technology, and applications in mechanical sensing /c| edited by Hamid Alemohammad.;

260 a| Oxford, United Kingdom :b| Butterworth-Heinemann,c| [2018];

300 a| xvi, 342 pages :b| illustrations ;c| 24 cm;

505 00 a| Machine generated contents note:g| ch. 1t| Opto-Mechanical Modeling of Fiber Bragg Grating Sensors /r| Hamid Alemohammad --g| 1.1.t| Fiber Bragg Gratings --g| 1.2.t| Opto-Mechanical Properties of Optical Fibers --g| 1.3.t| Fiber Bragg Gratings With Structurally and Thermally Induced Index Changes --g| 1.4.t| Light Propagation in Optical Fibers With Induced Optical Anisotropy --g| 1.5.t| Coupled-Mode Theory --g| 1.6.t| Derivation of Coupled-Mode Theory for Fiber Bragg Gratings With Uniform Grating --g| 1.7.t| Coupled-Mode Theory for Superstructure Fiber Bragg Gratings --t| Appendices --t| References --g| ch. 2t| Superstructure Fiber Bragg Grating Sensors for Multiparameter Sensing /r| Hamid Alemohammad --g| 2.1.t| Superstructure Fiber Bragg Gratings With Periodic On-Fiber Films --g| 2.2.t| Opto-Mechanical Modeling --g| 2.3.t| Simulation Results --g| 2.4.t| Geometrical Features of Fabricated Superstructure Fiber Bragg Gratings With On-Fiber Films --g| 2.5.t| Measurement Test Rig --g| 2.6.t| Optical Response Analysis --t| References --g| ch. 3t| Flat-Cladding Fiber Bragg Grating Sensors for Large Strain Amplitude Fatigue Tests /r| Xija Gu --g| 3.1.t| Introduction --g| 3.2.t| Experiments --g| 3.3.t| Sensor Validation Results --g| 3.4.t| Application in the Fatigue Test of a Friction Stir-Welded Aluminum Alloy --g| 3.5.t| Application in Asymmetric Fatigue Deformation of a Magnesium Alloy --g| 3.6.t| Conclusions --t| References --g| ch. 4t| Fiber Bragg Grating Strain Sensor for Microstructure in Situ Strain Measurement and Real-Time Failure Detection /r| Xija Gu --g| 4.1.t| Introduction --g| 4.2.t| Fiber Bragg Grating Basics and Sensor Fabrication --g| 4.3.t| Comparison of Cantilever Strain Measured by a Fiber Bragg Grating Sensor and a Strain Gauge --g| 4.4.t| Printed Circuit Board Assembly Test Sample Preparation for Bend Testing --g| 4.5.t| Strain Gauge A and Fiber Bragg Grating Sensor Installation on Assembly Packages --g| 4.6.t| Comparison of Ball Grid Array Substrate Strain Results by Fiber Bragg Grating Sensor Array and Finite Element Analysis Modeling --g| 4.7.t| Four-Point Bending System and Test Setup --g| 4.8.t| Dye-and-Pry Failure Visual Inspection --g| 4.9.t| Test Results and Discussion --g| 4.10.t| Conclusions --t| References --g| ch. 5t| Distributed Brillouin Sensing Using Polymer Optical Fibers /r| Kentaro Nakamura --g| 5.1.t| Introduction --g| 5.2.t| Characterization of Brillouin Scattering in Polymer Optical Fibers --g| 5.3.t| Distributed Measurement --g| 5.4.t| Polymer Optical Fiber Fuse --g| 5.5.t| Conclusion --t| References --g| ch. 6t| Femtosecond Laser-Inscribed Fiber Bragg Gratings for Sensing Applications /r| Stephen J. Mihailov --g| 6.1.t| Introduction --g| 6.2.t| The Fiber Bragg Grating --g| 6.3.t| The Fiber Bragg Grating Sensor --g| 6.4.t| Femtosecond Laser-Induced Bragg Gratings --g| 6.5.t| Applications of Femtosecond Laser-Induced Fiber Bragg Gratings for Sensing --g| 6.6.t| Conclusions --t| References --g| ch. 7t| Innovative Fiber Bragg Grating Sensors for Highly Demanding Applications: Considerations, Concepts, and Designs /r| Peter Martijn Toet --g| 7.1.t| Introduction --g| 7.2.t| Fiber Bragg Grating Sensor System --g| 7.3.t| High-Demand Fiber Bragg Grating Sensor System Performance --g| 7.4.t| Fiber Bragg Grating -- Based Sensors for Dedicated Operational Conditions --g| 7.5.t| Fiber Bragg Grating -- Based Sensors for Special Physical Parameters --t| Acknowledgments --t| References --g| ch. 8t| Fiber Optic Sensors in the Oil and Gas Industry: Current and Future Applications /r| Christopher Baldwin --g| 8.1.t| Introduction --g| 8.2.t| Breakdown of the Oil and Gas Industry --g| 8.3.t| Thermal Monitoring --g| 8.4.t| Pressure Monitoring in the Downhole Environment --g| 8.5.t| Flow Monitoring --g| 8.6.t| Seismic Monitoring --g| 8.7.t| Acoustic Monitoring --g| 8.8.t| Future Directions --t| References --t| Further Reading --g| ch. 9t| Aerospace Applications of Optical Fiber Mechanical Sensors /r| Craig Lopatin --g| 9.1.t| Introduction and Background --g| 9.2.t| Measurements for Flight Control --g| 9.3.t| Overview --g| 9.4.t| Concluding Remarks --t| References --t| Further Reading --g| ch. 10t| Fiber Optical Sensors in Biomechanics /r| Paulo Roriz --g| 10.1.t| Introduction --g| 10.2.t| Why Fiber Optical Sensors in Biomechanics? --g| 10.3.t| Applications in Biomechanics of Rigid Bodies --g| 10.4.t| Applications in Biomechanics of Deformable Bodies --g| 10.5.t| Applications in Biomechanics of Fluids --g| 10.6.t| Final Remarks --t| References --g| ch. 11t| Fiber Optic Sensors for Biomedical Applications /r| Emiliano Schena --g| 11.1.t| Introduction --g| 11.2.t| Biomedical Fiber Optic Sensor Systems --g| 11.3.t| Optical Fiber Sensors for Diagnostics --g| 11.4.t| Optical Fiber Sensors for Robotic Microsurgery --g| 11.5.t| Smart Textiles and Wearable Sensors --t| References.;

506 a| Available only to authorized users.;

538 a| Mode of access: World Wide Web;

650 0 a| Optical fiber detectors.=| ^A347337;

650 0 a| Senses and sensationx| Technological innovations.=| ^A3791;

650 7 a| Optical fiber detectors.2| fast0| (OCoLC)fst01046693;

655 0 a| Electronic books.=| ^A491897;

700 1 a| Alemohammad, Hamid.?| UNAUTHORIZED;

856 40 z| Full text available from eBook - Engineering 2018u| https://go.openathens.net/redirector/ecu.edu?url=https%3A%2F%2Fwww.sciencedirect.com%2Fscience%2Fbook%2F9780128031315;

947 a| (OCoLC)ocn979561966;

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949 a| CLICK ON WEB ADDRESSw| ASISh| JMUSIC60;

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999 a| CLICK ON WEB ADDRESSw| ASISc| 1i| 5868080-2001l| HSLELECm| HSLr| Ys| Yt| HEBKu| 7/18/2022x| EBOOKz| HERESOURCE;

999 a| CLICK ON WEB ADDRESSw| ASISc| 1i| 5868080-3001l| MNETm| JMUSICr| Ys| Yt| MNESSBKu| 7/18/2022x| EBOOKz| JERESOURCE;

Opto-mechanical fiber optic sensors research, technology, and applications in mechanical sensing / edited by Hamid Alemohammad.

Other author	Alemohammad, Hamid.
Format	Electronic
Publication Info	Oxford, United Kingdom : Butterworth-Heinemann, [2018]
Description	xvi, 342 pages : illustrations ; 24 cm
Supplemental Content	Full text available from eBook - Engineering 2018
Subjects	Optical fiber detectors. Senses and sensation--Technological innovations.

Contents	Machine generated contents note: ch. 1 Opto-Mechanical Modeling of Fiber Bragg Grating Sensors / Hamid Alemohammad -- 1.1. Fiber Bragg Gratings -- 1.2. Opto-Mechanical Properties of Optical Fibers -- 1.3. Fiber Bragg Gratings With Structurally and Thermally Induced Index Changes -- 1.4. Light Propagation in Optical Fibers With Induced Optical Anisotropy -- 1.5. Coupled-Mode Theory -- 1.6. Derivation of Coupled-Mode Theory for Fiber Bragg Gratings With Uniform Grating -- 1.7. Coupled-Mode Theory for Superstructure Fiber Bragg Gratings -- Appendices -- References -- ch. 2 Superstructure Fiber Bragg Grating Sensors for Multiparameter Sensing / Hamid Alemohammad -- 2.1. Superstructure Fiber Bragg Gratings With Periodic On-Fiber Films -- 2.2. Opto-Mechanical Modeling -- 2.3. Simulation Results -- 2.4. Geometrical Features of Fabricated Superstructure Fiber Bragg Gratings With On-Fiber Films -- 2.5. Measurement Test Rig -- 2.6. Optical Response Analysis -- References -- ch. 3 Flat-Cladding Fiber Bragg Grating Sensors for Large Strain Amplitude Fatigue Tests / Xija Gu -- 3.1. Introduction -- 3.2. Experiments -- 3.3. Sensor Validation Results -- 3.4. Application in the Fatigue Test of a Friction Stir-Welded Aluminum Alloy -- 3.5. Application in Asymmetric Fatigue Deformation of a Magnesium Alloy -- 3.6. Conclusions -- References -- ch. 4 Fiber Bragg Grating Strain Sensor for Microstructure in Situ Strain Measurement and Real-Time Failure Detection / Xija Gu -- 4.1. Introduction -- 4.2. Fiber Bragg Grating Basics and Sensor Fabrication -- 4.3. Comparison of Cantilever Strain Measured by a Fiber Bragg Grating Sensor and a Strain Gauge -- 4.4. Printed Circuit Board Assembly Test Sample Preparation for Bend Testing -- 4.5. Strain Gauge A and Fiber Bragg Grating Sensor Installation on Assembly Packages -- 4.6. Comparison of Ball Grid Array Substrate Strain Results by Fiber Bragg Grating Sensor Array and Finite Element Analysis Modeling -- 4.7. Four-Point Bending System and Test Setup -- 4.8. Dye-and-Pry Failure Visual Inspection -- 4.9. Test Results and Discussion -- 4.10. Conclusions -- References -- ch. 5 Distributed Brillouin Sensing Using Polymer Optical Fibers / Kentaro Nakamura -- 5.1. Introduction -- 5.2. Characterization of Brillouin Scattering in Polymer Optical Fibers -- 5.3. Distributed Measurement -- 5.4. Polymer Optical Fiber Fuse -- 5.5. Conclusion -- References -- ch. 6 Femtosecond Laser-Inscribed Fiber Bragg Gratings for Sensing Applications / Stephen J. Mihailov -- 6.1. Introduction -- 6.2. The Fiber Bragg Grating -- 6.3. The Fiber Bragg Grating Sensor -- 6.4. Femtosecond Laser-Induced Bragg Gratings -- 6.5. Applications of Femtosecond Laser-Induced Fiber Bragg Gratings for Sensing -- 6.6. Conclusions -- References -- ch. 7 Innovative Fiber Bragg Grating Sensors for Highly Demanding Applications: Considerations, Concepts, and Designs / Peter Martijn Toet -- 7.1. Introduction -- 7.2. Fiber Bragg Grating Sensor System -- 7.3. High-Demand Fiber Bragg Grating Sensor System Performance -- 7.4. Fiber Bragg Grating -- Based Sensors for Dedicated Operational Conditions -- 7.5. Fiber Bragg Grating -- Based Sensors for Special Physical Parameters -- Acknowledgments -- References -- ch. 8 Fiber Optic Sensors in the Oil and Gas Industry: Current and Future Applications / Christopher Baldwin -- 8.1. Introduction -- 8.2. Breakdown of the Oil and Gas Industry -- 8.3. Thermal Monitoring -- 8.4. Pressure Monitoring in the Downhole Environment -- 8.5. Flow Monitoring -- 8.6. Seismic Monitoring -- 8.7. Acoustic Monitoring -- 8.8. Future Directions -- References -- Further Reading -- ch. 9 Aerospace Applications of Optical Fiber Mechanical Sensors / Craig Lopatin -- 9.1. Introduction and Background -- 9.2. Measurements for Flight Control -- 9.3. Overview -- 9.4. Concluding Remarks -- References -- Further Reading -- ch. 10 Fiber Optical Sensors in Biomechanics / Paulo Roriz -- 10.1. Introduction -- 10.2. Why Fiber Optical Sensors in Biomechanics? -- 10.3. Applications in Biomechanics of Rigid Bodies -- 10.4. Applications in Biomechanics of Deformable Bodies -- 10.5. Applications in Biomechanics of Fluids -- 10.6. Final Remarks -- References -- ch. 11 Fiber Optic Sensors for Biomedical Applications / Emiliano Schena -- 11.1. Introduction -- 11.2. Biomedical Fiber Optic Sensor Systems -- 11.3. Optical Fiber Sensors for Diagnostics -- 11.4. Optical Fiber Sensors for Robotic Microsurgery -- 11.5. Smart Textiles and Wearable Sensors -- References.
Access restriction	Available only to authorized users.
Technical details	Mode of access: World Wide Web
Genre/form	Electronic books.
LCCN	2018302587
ISBN	9780128031315 (paperback)
ISBN	012803131X (paperback)
ISBN	(eBook)

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