05172nam 2200613Ia 450 991100667210332120200520144314.01-281-02410-497866110241090-08-051804-4(CKB)1000000000363812(EBL)298450(OCoLC)505142525(SSID)ssj0000310554(PQKBManifestationID)12071897(PQKBTitleCode)TC0000310554(PQKBWorkID)10313224(PQKB)10152778(MiAaPQ)EBC298450(EXLCZ)99100000000036381220020829d2001 uy 0engur|n|---|||||txtccrStructural monitoring with fiber optic technology /Raymond M. MeasuresSan Diego, Calif. ;London Academicc20011 online resource (735 p.)Description based upon print version of record.0-12-487430-4 Includes bibliographical references and index.Cover; Copyright Page; Contents; Preface; Acknowledgments; Chapter 1. Introduction; 1.1Smart Structures; 1.2Brief Historical Overview of Smart Structures; Chapter 2. Need for Integrated Structural Monitoring; 2.1Introduction; 2.2Civil Engineering Problems; 2.3New Materials for the Construction Industry; 2.4Bridges of Advanced Design; 2.5Detection of Structural Weakness; 2.6Measurement Prospects for Fiber Optic Technology; 2.7Earthquakes and New Materials for Repair; 2.8Other Structural Monitoring Applications; 2.9Wind Power and Structural Monitoring; 2.10Magnetic Levitation Train Monitoring2.11Aerospace Engineering Problems2.12New Materials for the Aerospace Industry; 2.13Fiber Optic Monitoring of Aircraft; Chapter 3. Introduction to Lightwaves; 3.1 Background and Overview; 3.2Electromagnetic Radiation; 3.3Birefringence and Polarization; 3.4Superposition, Coherence, and Interference; 3.5Partial Coherence and Coherence Length; 3.6High-Coherence Interferometers; 3.7Multipass Fabry-Perot Interferometer; 3.8Low-Coherence Interferometry; 3.9Radiation Coupling Between Optical Fibers; 3.10Bragg Grating Reflection; Chapter 4. Light Sources and Detectors; 4.1Introduction4.2Light Generation and Gain Media4.3Fabry-Perot Cavity Lasers; 4.4Semiconductor Radiation Sources; 4.5Light-Emitting Diodes; 4.6Semiconductor Laser Diodes; 4.7 Narrowband (DBR and DFB) Laser Diodes; 4.8Junction Photodetectors; 4.9 PIN and Avalanche Photodiode Detectors; 4.10Charge-Coupled Detector Arrays; 4.11Photodetector Signal-to-Noise; Chapter 5. Fiber Optic Technology; 5.1Introduction; 5.2Optical Fibers; 5.3Optical Fiber Guided Wave Modes; 5.4Cutoff Wavelength and Single-Mode Fiber; 5.5Optical Fiber Transmission Properties; 5.6 Optical Fiber Strength and Fatigue Life5.7Fiber Optic Connectors, Splices, and Pigtails5.8 Optical Isolators, Couplers, Filters, and Spectral Analyzers; 5.9Fiber Bragg Gratings; 5.10Multiplexing and Demultiplexing; Chapter 6. Fiber Optic Structural Sensors and Their Merits; 6.1Merits of Fiber Optic Structural Sensors; 6.2Types of Fiber Optic Structural Sensor; 6.3Intensiometric Fiber Optic Sensors; 6.4Interferometric Fiber Optic Sensors; 6.5 Polarimetric and Modalmetric Fiber Optic Sensors; 6.6Spectrometric Fiber Optic Sensors; 6.7Selection of a Fiber Optic Structural SensorChapter 7. Fiber Optic Strain and Temperature Sensitivity7.1 Introduction; 7.2Optothermomechanical Equations; 7.3 Strain and Temperature Sensitivity and Gauge Factors; 7.4Transverse Strains and Their Measurement; 7.5Thermal Apparent Strain; 7.6 Temperature Compensation for Fiber Optic Sensors; 7.7Temperature-Independent Strain Sensors; 7.8Strain-Temperature Cross-Sensitivity; Chapter 8. Sensor Installation and Material Integration Issues; 8.1Introduction; 8.2Installation of Fiber Optic Structural Sensors; 8.3 Fiber Optic Sensor Integration Within FRP Materials8.4The Influence of Fiber Optic CoatingsThis book is the first to address the field of structurally integrated fiber optic sensors. Fiber optic sensors embedded within materials and systems are able to measure a variety of parameters (i.e. temperature, vibration, deformation, strain, etc.) that allows for real time non-destructive evaluation. Examples include the following: monitoring structural fatigue in aging aircraft or loads in bridge structures. In more advanced applications, fiber optic sensors control actuators that allow materials to adapt to their environment. This gives rise to the names, ""smart,"" ""intelligent,"" and/oOptical fiber detectorsStructural stabilityOptical fiber detectors.Structural stability.624.17624.171028624.171Measures Raymond M725997MiAaPQMiAaPQMiAaPQBOOK9911006672103321Structural monitoring with fiber optic technology1424388UNINA04414nam 22007695 450 991101585780332120250711141904.03-031-90387-010.1007/978-3-031-90387-8(MiAaPQ)EBC32206008(Au-PeEL)EBL32206008(CKB)39625697500041(DE-He213)978-3-031-90387-8(OCoLC)1528359214(EXLCZ)993962569750004120250711d2025 u| 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierEnvironmentally Friendly Smart Materials with Special Electrical and Magnetic Properties /by Ilya A. Verbenko, Ivan A. Parinov, Ekaterina V. Glazunova, Svetlana I. Dudkina, Konstantin P. Andryushin, Dmitry V. Volkov, Larisa A. Reznichenko1st ed. 2025.Cham :Springer Nature Switzerland :Imprint: Springer,2025.1 online resource (315 pages)Engineering Materials,1868-12123-031-90386-2 Current State of Research in the Field of Environmentally Friendly Smart Materials, Technologies and Devices -- Regularities of the Change of Physical Properties of Solid Solutions Based on Sodium Niobate During Their Modification -- Regularities of Changes in Physical Properties of Oxides with Perovskite-Type Structure During Modification -- Structure, Grain Structure and Electrophysical Properties of Polycrystalline Solid Solutions of (Na, Li) NbO3 System -- Regularities of Changes in the Structure and Physical Properties of Solid Solutions Based on Alkali and Alkaline Earth Metal Niobates upon Heterovalention Substitution -- Thermal Frequency Behavior of Multi-element Compositions Based on Alkali Metal Niobates.This book presents a comprehensive exploration of the research and development of modern lead-free ferroelectric piezoceramic materials (FPCMs). Authored by Russian scientists from the Rostov Scientific School on Ferro-piezoelectricity, the book looks at the theoretical and experimental challenges associated with these environmentally friendly materials. It highlights the transition from traditional lead-containing materials to innovative lead-free alternatives, emphasizing their significance in various advanced fields such as biomedicine, information technology, robotics, and precision engineering. The book provides a detailed analysis of the methodologies employed for the preparation of FPCMs, the impact of structural inhomogeneities on their properties, and the development of new active materials. It also covers the extensive experimental data on the modification of solid solutions, the influence of different modifiers, and the resulting electrical, dielectric, and mechanical characteristics. This book serves as an essential resource for researchers, engineers, and students interested in the cutting-edge advancements in environmentally friendly smart materials and their wide-ranging applications.Engineering Materials,1868-1212MetalsCeramic materialsMagnetic materialsMaterialsChemistryCondensed matterMetals and AlloysCeramicsMagnetic MaterialsMaterials ChemistryStructure of Condensed MatterMetals.Ceramic materials.Magnetic materials.Materials.Chemistry.Condensed matter.Metals and Alloys.Ceramics.Magnetic Materials.Materials Chemistry.Structure of Condensed Matter.620.16Verbenko Ilya A1834078Parinov Ivan A1650866Glazunova Ekaterina V1834079Dudkina Svetlana I1834080Andryushin Konstantin P1834081Volkov Dmitry V1834082Reznichenko Larisa A1834083MiAaPQMiAaPQMiAaPQBOOK9911015857803321Environmentally Friendly Smart Materials with Special Electrical and Magnetic Properties4409173UNINA