Tools

LEADER 10164nam 2200601 i 4500

001 ssj0001997241;

003 WaSeSS;

005 20201013092529.0;

006 m d ;

007 cr n ;

008 180227t20182018maua sb 001 0 eng d;

010 a| 2017297308;

016 7 a| 1017236802| DNLM;

020 a| 9781630811525q| (hardcover);

020 a| 1630811521q| (hardcover);

035 a| (WaSeSS)ssj0001997241;

042 a| pcc;

049 a| EREEa| NEHH;

050 00 a| R857.B54b| T67 2018;

060 00 a| 2018 B-903;

060 10 a| QT 36.4;

082 00 a| 610.282| 23;

100 1 a| Tosi, Daniele.?| UNAUTHORIZED;

245 10 a| Fiber-optic sensors for biomedical applicationsh| [electronic resource] /c| Daniele Tosi, Guido Perrone.;

260 a| Boston :b| Artech House,c| [2018];

300 a| xviii, 291 pages :b| illustrations ;c| 27 cm.;

490 1 a| Artech House applied photonics series;

504 a| Includes bibliographical references and index.;

505 00 a| Machine generated contents note:g| ch. 1t| Fundamentals of Wave Optics and Optical Fibers --g| 1.1.t| Introduction --g| 1.2.t| Electromagnetic Waves --g| 1.3.t| Reflection and Refraction of Plane Waves --g| 1.4.t| Dielectric Waveguides --g| 1.5.t| Optical Fibers --g| 1.6.t| Practical Aspects in Using Optical Fibers --t| Selected Bibliography --g| ch. 2t| Devices for Fiber-Optic Sensing Applications --g| 2.1.t| Introduction --g| 2.2.t| Light Sources --g| 2.2.1.t| Light-Emitting Diodes --g| 2.2.2.t| Laser Diodes --g| 2.3.t| Photodiodes --g| 2.4.t| Isolators and Circulators --g| 2.5.t| Couplers --g| 2.5.1.t| Wavelength-Insensitive Couplers --g| 2.5.2.t| Wavelength-Sensitive Couplers --g| 2.6.t| Polarization Optics --g| 2.7.t| Optical Spectrum Analyzers and Spectrometers --t| References --g| ch. 3t| Principles of Fiber-Optic Sensing --g| 3.1.t| Definitions --g| 3.2.t| Classification --g| 3.3.t| Working Principles --g| 3.4.t| Sensor Performance Analysis --g| 3.5.t| Application-Integrated Design --t| References --g| ch. 4t| Intensity-Based Sensors --g| 4.1.t| Introduction --g| 4.2.t| Sensors Exploiting the Modulation of Losses --g| 4.3.t| Sensors Based on Coupling Loss --t| References --g| ch. 5t| Fiber Bragg Gratings --g| 5.1.t| Description --g| 5.2.t| Uniform FBGs --g| 5.3.t| FBG Thermal and Mechanical Response --g| 5.4.t| FBG Arrays --g| 5.5.t| Chirped and Apodized FBG --g| 5.6.t| Tilted FBG --g| 5.7.t| Fabrication of FBGs --g| 5.7.1.t| Photosensitivity --g| 5.7.2.t| Phase Mask Inscription --g| 5.7.3.t| Interfering Beams --g| 5.7.4.t| Draw-Tower Method --g| 5.7.5.t| Point-by-Point --g| 5.8.t| FBG Package --g| 5.9.t| Recent Advances --t| References --g| ch. 6t| Distributed Sensors --g| 6.1.t| Introduction --g| 6.2.t| OFDR Theory --g| 6.2.1.t| Demonstration --g| 6.2.2.t| Detection --g| 6.3.t| Microwave Photonics --g| 6.4.t| Sensing Elements --g| 6.5.t| Practical Considerations --g| 6.6.t| Perspectives --t| References --g| ch. 7t| Fabry-Perot Interferometers --g| 7.1.t| Fabry-Perot Interferometer Principle --g| 7.2.t| FPI-Based Sensors --g| 7.3.t| FPI/FBG Dual Sensors --g| 7.4.t| Fabrication of FPI Sensors --g| 7.5.t| Self-Mixing Interferometry --g| 7.6.t| Other Interferometers --t| References --g| ch. 8t| Fiber-Optic Biosensor Principles --g| 8.1.t| Introduction --g| 8.2.t| Sensors Exploiting the Evanescent Field Absorption --g| 8.3.t| Sensors Exploiting Surface Plasmon Resonance --g| 8.3.1.t| SPR Sensors in Bulk Optics --g| 8.3.2.t| SPR Sensors in Optical Fibers --g| 8.3.3.t| SPR Sensors in Photonic Crystal Fibers --t| References --g| ch. 9t| Optical Fiber Spectroscopy --t| References --g| ch. 10t| Fiber-Optic Sensor Networks --g| 10.1.t| Introduction --g| 10.2.t| Amplitude Detection Methods --g| 10.2.1.t| FBG and Fabry-Perot Interferometers --g| 10.2.2.t| Plastic Fiber-Based Systems --g| 10.3.t| White Light-Based Setup --g| 10.3.1.t| Setup and Instrumentation --g| 10.3.2.t| Time/Wavelength Division Multiplexing --g| 10.3.3.t| Cepstrum Division Multiplexing --g| 10.4.t| Scanning-Source Interrogators --g| 10.5.t| Multiparametric Sensors --g| 10.6.t| Distributed Sensing Units --g| 10.7.t| Commercial Devices --g| 10.8.t| Conclusions --t| References --g| ch. 11t| Interrogation Software --g| 11.1.t| FBG Tracking Direct Methods --g| 11.1.1.t| Centroid --g| 11.1.2.t| Bandwidth Tracking --g| 11.1.3.t| Polynomial Fitting --g| 11.2.t| EFPI Direct Tracking --g| 11.2.1.t| Short-Cavity EFPI --g| 11.2.2.t| Long-Cavity EFPI --g| 11.3.t| Direct Karhunen-Loeve Transform --g| 11.4.t| Multi-EFPI Systems --g| 11.5.t| Tilted and Chirped FBG --g| 11.5.1.t| TFBG --g| 11.5.2.t| CFBG --g| 11.6.t| LabVIEW Implementation --g| 11.7.t| Conclusions --t| References --g| ch. 12t| Standards for Medical Sensors --g| 12.1.t| Main Standards --g| 12.2.t| ISO 10993 --g| 12.3.t| ISO 13485 --g| 12.4.t| IEC 60601 --g| 12.5.t| Other Standards --g| 12.6.t| CEMark --t| References --g| ch. 13t| Protocols and Tools for Validation --g| 13.1.t| Moral Norms --g| 13.2.t| Relevant Definitions --g| 13.2.1.t| In Vivo --g| 13.2.2.t| Ex Vivo --g| 13.2.3.t| In Vitro --g| 13.2.4.t| Phantom --g| 13.2.5.t| Principle of 3Rs --g| 13.2.6.t| Ethical Issues --g| 13.3.t| Research and Test Methodologies --g| 13.4.t| Investigational Device Exemption --g| 13.5.t| Useful Tools --t| References --g| ch. 14t| Sensor Catheterization --g| 14.1.t| Characteristics of Medical Catheters --g| 14.1.1.t| Invasiveness and Size --g| 14.1.2.t| Form Factor and Rigidity --g| 14.1.3.t| Insertion --g| 14.1.4.t| Positioning --g| 14.1.5.t| FOS Protection and Functionality --g| 14.1.6.t| Metrologic Issues --g| 14.1.7.t| Disposable Format and Sterilization --g| 14.2.t| FOS Catheterizations --g| 14.2.1.t| Urologic Pressure and Multipressure Catheter --g| 14.2.2.t| Fiber-Optic Manometer --g| 14.2.3.t| Force-Sensing Device for Epidural Anesthesia --g| 14.2.4.t| Cranial Intraventricular Catheter --g| 14.2.5.t| Needle Thermotherapy Probe --g| 14.2.6.t| Fiber-Optic Guidewire --g| 14.2.7.t| Biosensor Catheterization --g| 14.3.t| Perspectives --t| References --g| ch. 15t| Cardiovascular Sensors --g| 15.1.t| Pressure Measurement --g| 15.2.t| Blood Pressure Measurement --g| 15.3.t| Fractional Flow Reserve --g| 15.4.t| Heart-Assistive Devices --g| 15.5.t| Blood Temperature Sensor --g| 15.6.t| Conclusions --t| References --g| ch. 16t| Diagnostics in Gastroscopy, Urology, and Neurology --g| 16.1.t| Gastroscopy --g| 16.1.1.t| Sensing Element --g| 16.1.2.t| Esophageal Detection --g| 16.1.3.t| Colonic Analysis --g| 16.1.4.t| Dual Sensing --g| 16.1.5.t| Present and Future Perspectives --g| 16.2.t| Urology --g| 16.2.1.t| Urodynamics --g| 16.2.2.t| Traditional Diagnostic --g| 16.2.3.t| Differential Diagnostic --g| 16.2.4.t| Current Outlook and Future Prospects --g| 16.3.t| Neurology --g| 16.4.t| Epidural --g| 16.5.t| Conclusions --t| References --g| ch. 17t| Sensing in Thermal Ablation --g| 17.1.t| Thermal Ablation: Procedures and Rationale --g| 17.1.1.t| Radio Frequency Ablation --g| 17.1.2.t| Microwave Ablation --g| 17.1.3.t| Laser Ablation --g| 17.1.4.t| High-Intensity Focused Ultrasound --g| 17.1.5.t| Other Techniques --g| 17.2.t| Sensing in Thermal Ablation --g| 17.3.t| FBG Arrays --g| 17.4.t| High-Density Temperature Sensing --g| 17.4.1.t| Chirped FBG --g| 17.4.2.t| Distributed Sensing --g| 17.5.t| Pressure Sensing --g| 17.6.t| Concluding Remarks and Future Perspectives --t| References --g| ch. 18t| Application and Detection of SPR Sensors --g| 18.1.t| Genesis and Present Status --g| 18.2.t| Lung Cancer Biomarker Detection --g| 18.3.t| Thrombin Detection --g| 18.4.t| DNA Detection --g| 18.5.t| Celiac Disease Diagnostic --g| 18.6.t| Perspectives --t| References --g| ch. 19t| Minimally Invasive Robotic Surgery --g| 19.1.t| Robotic Microsurgery and Its Feedback --g| 19.2.t| Vitreoretinal Surgery: Case Study --g| 19.2.1.t| Tool-Tip FBG Force Detection --g| 19.2.2.t| Multi-FPI Force Detection --g| 19.2.3.t| Tool-Shaft and Transverse Force Detection --g| 19.3.t| Intensity-Based Sensors --g| 19.4.t| Distributed Sensing: An Industrial Prospect --g| 19.5.t| Future Evolution --t| References --g| ch. 20t| Smart Textiles and Wearable Sensors --g| 20.1.t| Introduction --g| 20.2.t| Smart Medical Textiles --g| 20.3.t| Wearable Sensors --g| 20.4.t| Future Prospects --t| References --g| ch. 21t| Fiber-Optic Spectrometric Sensors --g| 21.1.t| Detection of Liver Tumors --g| 21.2.t| Detection of Lung Tumors --g| 21.3.t| Portable Tissue Scanner --g| 21.4.t| Application Perspective --t| References --g| ch. 22t| Conclusions and Future Perspectives --g| Appendix At| FBG and EFPI Generators --t| FBG Generator: FBGgeneration.m --t| EFPI Generator (2-Mirror Extrinsic Structure): EFPIgeneration.m --t| FBG Array Analyzer: FBGarray.m --t| LCFBG Analyzer: LCFBG.m --t| Dual FBG/EFPI Sensor Analyzer: FBGandEFPI.m --g| Appendix Bt| FBG and EFPI Interrogation --t| FBG Wavelength Shift Tracking: FBGtracking.m --t| Short-Cavity EFPI Tracking: EFPIshort.m --t| Long-Cavity EFPI Tracking: EFPIlong.m --t| KLT for FBG and EFPI Tracking: KLT.m --t| Capon Estimator: CaponPSD.m.;

506 a| Available only to authorized users.;

538 a| Mode of access: World Wide Web;

650 0 a| Biosensors.=| ^A149319;

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

650 0 a| Biomedical engineering.=| ^A912;

650 12 a| Biosensing Techniques.=| ^A932665;

650 22 a| Fiber Optic Technology.=| ^A918279;

650 7 a| Biomedical engineering.2| fast0| (OCoLC)fst00832568;

650 7 a| Biosensors.2| fast0| (OCoLC)fst00832703;

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

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

700 1 a| Perrone, Guidoc| (Professor of Electronics and Telecommunications)?| UNAUTHORIZED;

830 0 a| Artech House applied photonics series.?| UNAUTHORIZED;

856 40 z| Full text available from Ebook Central - Academic Completeu| https://ebookcentral.proquest.com/lib/eastcarolina/detail.action?docID=5430726;

947 a| (OCoLC)on1021071095;

949 a| CLICK ON WEB ADDRESSw| ASISh| JOYNER188;

949 a| CLICK ON WEB ADDRESSw| ASISh| HSL77;

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

596 a| 1 3 4;

998 a| 5507199;

999 a| CLICK ON WEB ADDRESSw| ASISc| 1i| 5507199-1001l| JNETm| JOYNERr| Ys| Yt| JNESSBKu| 10/16/2020x| EBOOKz| JERESOURCE;

999 a| CLICK ON WEB ADDRESSw| ASISc| 1i| 5507199-2001l| HSLELECm| HSLr| Ys| Yt| HEBKu| 10/16/2020x| EBOOKz| HERESOURCE;

999 a| CLICK ON WEB ADDRESSw| ASISc| 1i| 5507199-3001l| MNETm| JMUSICr| Ys| Yt| MNESSBKu| 10/16/2020x| EBOOKz| JERESOURCE;

Fiber-optic sensors for biomedical applications / Daniele Tosi, Guido Perrone.

Author/creator	Tosi, Daniele
Other author	Perrone, Guido (Professor of Electronics and Telecommunications)
Format	Electronic
Publication Info	Boston : Artech House, [2018]
Description	xviii, 291 pages : illustrations ; 27 cm.
Supplemental Content	Full text available from Ebook Central - Academic Complete
Subjects	Biosensors. Optical fiber detectors. Biomedical engineering. Biosensing Techniques. Fiber Optic Technology.

Series	Artech House applied photonics series Artech House applied photonics series. UNAUTHORIZED
Contents	Machine generated contents note: ch. 1 Fundamentals of Wave Optics and Optical Fibers -- 1.1. Introduction -- 1.2. Electromagnetic Waves -- 1.3. Reflection and Refraction of Plane Waves -- 1.4. Dielectric Waveguides -- 1.5. Optical Fibers -- 1.6. Practical Aspects in Using Optical Fibers -- Selected Bibliography -- ch. 2 Devices for Fiber-Optic Sensing Applications -- 2.1. Introduction -- 2.2. Light Sources -- 2.2.1. Light-Emitting Diodes -- 2.2.2. Laser Diodes -- 2.3. Photodiodes -- 2.4. Isolators and Circulators -- 2.5. Couplers -- 2.5.1. Wavelength-Insensitive Couplers -- 2.5.2. Wavelength-Sensitive Couplers -- 2.6. Polarization Optics -- 2.7. Optical Spectrum Analyzers and Spectrometers -- References -- ch. 3 Principles of Fiber-Optic Sensing -- 3.1. Definitions -- 3.2. Classification -- 3.3. Working Principles -- 3.4. Sensor Performance Analysis -- 3.5. Application-Integrated Design -- References -- ch. 4 Intensity-Based Sensors -- 4.1. Introduction -- 4.2. Sensors Exploiting the Modulation of Losses -- 4.3. Sensors Based on Coupling Loss -- References -- ch. 5 Fiber Bragg Gratings -- 5.1. Description -- 5.2. Uniform FBGs -- 5.3. FBG Thermal and Mechanical Response -- 5.4. FBG Arrays -- 5.5. Chirped and Apodized FBG -- 5.6. Tilted FBG -- 5.7. Fabrication of FBGs -- 5.7.1. Photosensitivity -- 5.7.2. Phase Mask Inscription -- 5.7.3. Interfering Beams -- 5.7.4. Draw-Tower Method -- 5.7.5. Point-by-Point -- 5.8. FBG Package -- 5.9. Recent Advances -- References -- ch. 6 Distributed Sensors -- 6.1. Introduction -- 6.2. OFDR Theory -- 6.2.1. Demonstration -- 6.2.2. Detection -- 6.3. Microwave Photonics -- 6.4. Sensing Elements -- 6.5. Practical Considerations -- 6.6. Perspectives -- References -- ch. 7 Fabry-Perot Interferometers -- 7.1. Fabry-Perot Interferometer Principle -- 7.2. FPI-Based Sensors -- 7.3. FPI/FBG Dual Sensors -- 7.4. Fabrication of FPI Sensors -- 7.5. Self-Mixing Interferometry -- 7.6. Other Interferometers -- References -- ch. 8 Fiber-Optic Biosensor Principles -- 8.1. Introduction -- 8.2. Sensors Exploiting the Evanescent Field Absorption -- 8.3. Sensors Exploiting Surface Plasmon Resonance -- 8.3.1. SPR Sensors in Bulk Optics -- 8.3.2. SPR Sensors in Optical Fibers -- 8.3.3. SPR Sensors in Photonic Crystal Fibers -- References -- ch. 9 Optical Fiber Spectroscopy -- References -- ch. 10 Fiber-Optic Sensor Networks -- 10.1. Introduction -- 10.2. Amplitude Detection Methods -- 10.2.1. FBG and Fabry-Perot Interferometers -- 10.2.2. Plastic Fiber-Based Systems -- 10.3. White Light-Based Setup -- 10.3.1. Setup and Instrumentation -- 10.3.2. Time/Wavelength Division Multiplexing -- 10.3.3. Cepstrum Division Multiplexing -- 10.4. Scanning-Source Interrogators -- 10.5. Multiparametric Sensors -- 10.6. Distributed Sensing Units -- 10.7. Commercial Devices -- 10.8. Conclusions -- References -- ch. 11 Interrogation Software -- 11.1. FBG Tracking Direct Methods -- 11.1.1. Centroid -- 11.1.2. Bandwidth Tracking -- 11.1.3. Polynomial Fitting -- 11.2. EFPI Direct Tracking -- 11.2.1. Short-Cavity EFPI -- 11.2.2. Long-Cavity EFPI -- 11.3. Direct Karhunen-Loeve Transform -- 11.4. Multi-EFPI Systems -- 11.5. Tilted and Chirped FBG -- 11.5.1. TFBG -- 11.5.2. CFBG -- 11.6. LabVIEW Implementation -- 11.7. Conclusions -- References -- ch. 12 Standards for Medical Sensors -- 12.1. Main Standards -- 12.2. ISO 10993 -- 12.3. ISO 13485 -- 12.4. IEC 60601 -- 12.5. Other Standards -- 12.6. CEMark -- References -- ch. 13 Protocols and Tools for Validation -- 13.1. Moral Norms -- 13.2. Relevant Definitions -- 13.2.1. In Vivo -- 13.2.2. Ex Vivo -- 13.2.3. In Vitro -- 13.2.4. Phantom -- 13.2.5. Principle of 3Rs -- 13.2.6. Ethical Issues -- 13.3. Research and Test Methodologies -- 13.4. Investigational Device Exemption -- 13.5. Useful Tools -- References -- ch. 14 Sensor Catheterization -- 14.1. Characteristics of Medical Catheters -- 14.1.1. Invasiveness and Size -- 14.1.2. Form Factor and Rigidity -- 14.1.3. Insertion -- 14.1.4. Positioning -- 14.1.5. FOS Protection and Functionality -- 14.1.6. Metrologic Issues -- 14.1.7. Disposable Format and Sterilization -- 14.2. FOS Catheterizations -- 14.2.1. Urologic Pressure and Multipressure Catheter -- 14.2.2. Fiber-Optic Manometer -- 14.2.3. Force-Sensing Device for Epidural Anesthesia -- 14.2.4. Cranial Intraventricular Catheter -- 14.2.5. Needle Thermotherapy Probe -- 14.2.6. Fiber-Optic Guidewire -- 14.2.7. Biosensor Catheterization -- 14.3. Perspectives -- References -- ch. 15 Cardiovascular Sensors -- 15.1. Pressure Measurement -- 15.2. Blood Pressure Measurement -- 15.3. Fractional Flow Reserve -- 15.4. Heart-Assistive Devices -- 15.5. Blood Temperature Sensor -- 15.6. Conclusions -- References -- ch. 16 Diagnostics in Gastroscopy, Urology, and Neurology -- 16.1. Gastroscopy -- 16.1.1. Sensing Element -- 16.1.2. Esophageal Detection -- 16.1.3. Colonic Analysis -- 16.1.4. Dual Sensing -- 16.1.5. Present and Future Perspectives -- 16.2. Urology -- 16.2.1. Urodynamics -- 16.2.2. Traditional Diagnostic -- 16.2.3. Differential Diagnostic -- 16.2.4. Current Outlook and Future Prospects -- 16.3. Neurology -- 16.4. Epidural -- 16.5. Conclusions -- References -- ch. 17 Sensing in Thermal Ablation -- 17.1. Thermal Ablation: Procedures and Rationale -- 17.1.1. Radio Frequency Ablation -- 17.1.2. Microwave Ablation -- 17.1.3. Laser Ablation -- 17.1.4. High-Intensity Focused Ultrasound -- 17.1.5. Other Techniques -- 17.2. Sensing in Thermal Ablation -- 17.3. FBG Arrays -- 17.4. High-Density Temperature Sensing -- 17.4.1. Chirped FBG -- 17.4.2. Distributed Sensing -- 17.5. Pressure Sensing -- 17.6. Concluding Remarks and Future Perspectives -- References -- ch. 18 Application and Detection of SPR Sensors -- 18.1. Genesis and Present Status -- 18.2. Lung Cancer Biomarker Detection -- 18.3. Thrombin Detection -- 18.4. DNA Detection -- 18.5. Celiac Disease Diagnostic -- 18.6. Perspectives -- References -- ch. 19 Minimally Invasive Robotic Surgery -- 19.1. Robotic Microsurgery and Its Feedback -- 19.2. Vitreoretinal Surgery: Case Study -- 19.2.1. Tool-Tip FBG Force Detection -- 19.2.2. Multi-FPI Force Detection -- 19.2.3. Tool-Shaft and Transverse Force Detection -- 19.3. Intensity-Based Sensors -- 19.4. Distributed Sensing: An Industrial Prospect -- 19.5. Future Evolution -- References -- ch. 20 Smart Textiles and Wearable Sensors -- 20.1. Introduction -- 20.2. Smart Medical Textiles -- 20.3. Wearable Sensors -- 20.4. Future Prospects -- References -- ch. 21 Fiber-Optic Spectrometric Sensors -- 21.1. Detection of Liver Tumors -- 21.2. Detection of Lung Tumors -- 21.3. Portable Tissue Scanner -- 21.4. Application Perspective -- References -- ch. 22 Conclusions and Future Perspectives -- Appendix A FBG and EFPI Generators -- FBG Generator: FBGgeneration.m -- EFPI Generator (2-Mirror Extrinsic Structure): EFPIgeneration.m -- FBG Array Analyzer: FBGarray.m -- LCFBG Analyzer: LCFBG.m -- Dual FBG/EFPI Sensor Analyzer: FBGandEFPI.m -- Appendix B FBG and EFPI Interrogation -- FBG Wavelength Shift Tracking: FBGtracking.m -- Short-Cavity EFPI Tracking: EFPIshort.m -- Long-Cavity EFPI Tracking: EFPIlong.m -- KLT for FBG and EFPI Tracking: KLT.m -- Capon Estimator: CaponPSD.m.
Bibliography note	Includes bibliographical references and index.
Access restriction	Available only to authorized users.
Technical details	Mode of access: World Wide Web
Genre/form	Electronic books.
LCCN	2017297308
ISBN	9781630811525 (hardcover)
ISBN	1630811521 (hardcover)

Fiber-optic sensors for biomedical applications / Daniele Tosi, Guido Perrone.

Click here for more information about this title