LEADER 05449nam 2200661 a 450 001 9910144726303321 005 20170815113944.0 010 $a1-282-34823-X 010 $a9786612348235 010 $a0-470-51781-6 010 $a0-470-51780-8 035 $a(CKB)1000000000377516 035 $a(EBL)470265 035 $a(OCoLC)609849007 035 $a(SSID)ssj0000296302 035 $a(PQKBManifestationID)11220132 035 $a(PQKBTitleCode)TC0000296302 035 $a(PQKBWorkID)10320254 035 $a(PQKB)10881774 035 $a(MiAaPQ)EBC470265 035 $a(EXLCZ)991000000000377516 100 $a20071015d2007 uy 0 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt 182 $cc 183 $acr 200 10$aFibre optic methods for structural health monitoring$b[electronic resource] /$fBranko Glis?ic?, Daniele Inaudi 210 $aChichester, West Sussex, England ;$aHoboken, NJ $cJohn Wiley & Sons$dc2007 215 $a1 online resource (280 p.) 300 $aDescription based upon print version of record. 311 $a0-470-06142-1 320 $aIncludes bibliographical references (p. [253]-256) and index. 327 $aFIBRE OPTIC METHODS FOR STRUCTURAL HEALTH MONITORING; Contents; Foreword; Preface; Acknowledgements; 1 Introduction to Structural Health Monitoring; 1.1 Basic Notions, Needs and Benefits; 1.1.1 Introduction; 1.1.2 Basic Notions; 1.1.3 Monitoring Needs and Benefits; 1.1.4 Whole Lifespan Monitoring; 1.2 The Structural Health Monitoring Process; 1.2.1 Core Activities; 1.2.2 Actors; 1.3 On-Site Example of Structural Health Monitoring Project; 2 Fibre-Optic Sensors; 2.1 Introduction to Fibre-Optic Technology; 2.2 Fibre-Optic Sensing Technologies; 2.2.1 SOFO Interferometric Sensors 327 $a2.2.2 Fabry-Perot Interferometric Sensors2.2.3 Fibre Bragg-Grating Sensors; 2.2.4 Distributed Brillouin- and Raman-Scattering Sensors; 2.3 Sensor Packaging; 2.4 Distributed Sensing Cables; 2.4.1 Introduction; 2.4.2 Temperature-Sensing Cable; 2.4.3 Strain-Sensing Tape: SMARTape; 2.4.4 Combined Strain- and Temperature-Sensing: SMARTprofile; 2.5 Software and System Integration; 2.6 Conclusions and Summary; 3 Fibre-Optic Deformation Sensors: Applicability and Interpretation of Measurements; 3.1 Strain Components and Strain Time Evolution; 3.1.1 Basic Notions 327 $a3.1.2 Elastic and Plastic Structural Strain3.1.3 Thermal Strain; 3.1.4 Creep; 3.1.5 Shrinkage; 3.1.6 Reference Time and Reference Measurement; 3.2 Sensor Gauge Length and Measurement; 3.2.1 Introduction; 3.2.2 Deformation Sensor Measurements; 3.2.3 Global Structural Monitoring: Basic Notions; 3.2.4 Sensor Measurement Dependence on Strain Distribution: Maximal Gauge Length; 3.2.5 Sensor Measurement in Inhomogeneous Materials: Minimal Gauge Length; 3.2.6 General Principle in the Determination of Sensor Gauge Length; 3.2.7 Distributed Strain Sensor Measurement 327 $a3.3 Interpretation of strain measurement3.3.1 Introduction; 3.3.2 Sources of Errors and Detection of Anomalous Structural Condition; 3.3.3 Determination of Strain Components and Stress from Total Strain Measurement; 3.3.4 Example of Strain Measurement Interpretation; 4 Sensor Topologies: Monitoring Global Parameters; 4.1 Finite Element Structural Health Monitoring Concept: Introduction; 4.2 Simple Topology and Applications; 4.2.1 Basic Notions on Simple Topology; 4.2.2 Enchained Simple Topology; 4.2.3 Example of an Enchained Simple Topology Application; 4.2.4 Scattered Simple Topology 327 $a4.2.5 Example of a Scattered Simple Topology Application4.3 Parallel Topology; 4.3.1 Basic Notions on Parallel Topology: Uniaxial Bending; 4.3.2 Basic Notions on Parallel Topology: Biaxial Bending; 4.3.3 Deformed Shape and Displacement Diagram; 4.3.4 Examples of Parallel Topology Application; 4.4 Crossed Topology; 4.4.1 Basic Notions on Crossed Topology: Planar Case; 4.4.2 Basic Notions on Crossed Topology: Spatial Case; 4.4.3 Example of a Crossed Topology Application; 4.5 Triangular Topology; 4.5.1 Basic Notions on Triangular Topology; 4.5.2 Scattered and Spread Triangular Topologies 327 $a4.5.3 Monitoring of Planar Relative Movements Between Two Blocks 330 $aThe use of fibre optic sensors in structural health monitoring has rapidly accelerated in recent years. By embedding fibre optic sensors in structures (e.g. buildings, bridges and pipelines) it is possible to obtain real time data on structural changes such as stress or strain. Engineers use monitoring data to detect deviations from a structure's original design performance in order to optimise the operation, repair and maintenance of a structure over time. Fibre Optic Methods for Structural Health Monitoring is organised as a step-by-step guide to implementing a monitoring system 606 $aStructural analysis (Engineering) 606 $aFiber optics 606 $aOptoelectronics 608 $aElectronic books. 615 0$aStructural analysis (Engineering) 615 0$aFiber optics. 615 0$aOptoelectronics. 676 $a624.1/71 676 $a624.171 700 $aGlis?ic?$b Branko$f1975-$0882833 701 $aInaudi$b Daniele$0882834 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910144726303321 996 $aFibre optic methods for structural health monitoring$91972220 997 $aUNINA