01622oam 2200421Ia 450 991069622280332120071128112807.0(CKB)5470000002376596(OCoLC)150863471(EXLCZ)99547000000237659620070703d2007 ua 0engurmn||||m||||txtrdacontentcrdamediacrrdacarrierDistribution of potential spawning habitat for sturgeon in the lower Missouri River, 2003-06[electronic resource] /by Mark S. Laustrup, Robert B. Jacobson, and Darin G. Simpkins ; in cooperation with the U.S. Army Corps of EngineersReston, Va. :U.S. Geological Survey,2007.1 electronic text (v, 26 pages) HTML, digital, PDF fileOpen-file report ;2007-1192Title from PDF title screen (viewed on July 2, 2007).Includes bibliographical references (pages 24-26).SturgeonsSpawningMissouri RiverSturgeonsHabitatMissouri RiverSturgeonsSpawningSturgeonsHabitatLaustrup Mark S1395945Jacobson Robert B1386632Simpkins Darin G1395946United States.Army.Corps of Engineers.Geological Survey (U.S.)GISGISGPOBOOK9910696222803321Distribution of potential spawning habitat for sturgeon in the lower Missouri River, 2003-063455229UNINA05533nam 2200673 a 450 991100662490332120200520144314.097866110999920-08-055679-5(CKB)1000000000401653(EBL)330089(OCoLC)437198368(SSID)ssj0000252594(PQKBManifestationID)11200394(PQKBTitleCode)TC0000252594(PQKBWorkID)10180510(PQKB)10572693(Au-PeEL)EBL330089(CaPaEBR)ebr10203616(CaONFJC)MIL107251(MiAaPQ)EBC330089(EXLCZ)99100000000040165320071019d2008 uy 0engur|n|---|||||txtccrStructural health monitoring with piezoelectric wafer active sensors /Victor Giurgiutiu1st ed.Amsterdam ;Boston Academic Pressc20081 online resource (759 p.)Description based upon print version of record.0-12-088760-6 Includes bibliographical references (p. 699-710) and index.Front Cover; Structural Health Monitoring; Copyright Page; Table of Contents; Chapter 1 Introduction; 1.1 Structural Health Monitoring Principles and Concepts; 1.2 Structural Fracture and Failure; 1.3 Improved Diagnosis and Prognosis Through Structural Health Monitoring; 1.4 About this Book; Chapter 2 Electroactive and Magnetoactive Materials; 2.1 Introduction; 2.2 Piezoelectricity; 2.3 Piezoelectric Phenomena; 2.4 Perovskite Ceramics; 2.5 Piezopolymers; 2.6 Magnetostrictive Materials; 2.7 Summary and Conclusions; 2.8 Problems and Exercises; Chapter 3 Vibration of Solids and Structures3.1 Introduction3.2 Single Degree of Freedom Vibration Analysis; 3.3 Vibration of Continuous Systems; 3.4 Summary and Conclusions; 3.5 Problems and Exercises; Chapter 4 Vibration of Plates; 4.1 Elasticity Equations for Plate Vibration; 4.2 Axial Vibration of Rectangular Plates; 4.3 Axial Vibration of Circular Plates; 4.4 Flexural Vibration of Rectangular Plates; 4.5 Flexural Vibration of Circular Plates; 4.6 Problems and Exercises; Chapter 5 Elastic Waves in Solids and Structures; 5.1 Introduction; 5.2 Axial Waves in Bars; 5.3 Flexural Waves in Beams; 5.4 Torsional Waves in Shafts5.5 Plate Waves5.6 3-D Waves; 5.7 Summary and Conclusions; 5.8 Problems and Exercises; Chapter 6 Guided Waves; 6.1 Introduction; 6.2 Rayleigh Waves; 6.3 SH Plate Waves; 6.4 Lamb Waves; 6.5 General Formulation of Guided Waves in Plates; 6.6 Guided Waves in Tubes and Shells; 6.7 Guided Waves in Composite Plates; 6.8 Summary and Conclusions; 6.9 Problems and Exercises; Chapter 7 Piezoelectric Wafer Active Sensors; 7.1 Introduction; 7.2 PWAS Resonators; 7.3 Circular PWAS Resonators; 7.4 Coupled-Field Analysis of PWAS Resonators; 7.5 Constrained PWAS; 7.6 PWAS Ultrasonic Transducers7.7 Durability and Survivability of Piezoelectric Wafer Active Sensors7.8 Summary and Conclusions; 7.9 Problems and Exercises; Chapter 8 Tuned Waves Generated with Piezoelectric Wafer Active Sensors; 8.1 Introduction; 8.2 State of the Art; 8.3 Tuned Axial Waves Excited by PWAS; 8.4 Tuned Flexural Waves Excited by PWAS; 8.5 Tuned Lamb Waves Excited by PWAS; 8.6 Experimental Validation of PWAS Lamb-Wave Tuning in Isotropic Plates; 8.7 Directivity of Rectangular PWAS; 8.8 PWAS-Guided Wave Tuning in Composite Plates; 8.9 Summary and Conclusions; 8.10 Problems and ExercisesChapter 9 High-Frequency Vibration SHM with PWAS Modal Sensors - the Electromechanical Impedance Method9.1 Introduction; 9.2 1-D PWAS Modal Sensors; 9.3 Circular PWAS Modal Sensors; 9.4 Damage Detection with PWAS Modal Sensors; 9.5 Coupled-Field FEM Analysis of PWAS Modal Sensors; 9.6 Summary and Conclusions; 9.7 Problems and Exercises; Chapter 10 Wave Propagation SHM with PWAS; 10.1 Introduction; 10.2 1-D Modeling and Experiments; 10.3 2-D PWAS Wave Propagation Experiments; 10.4 Pitch-Catch PWAS-Embedded NDE; 10.5 Pulse-Echo PWAS-Embedded NDE; 10.6 PWAS Time Reversal Method10.7 PWAS Passive Transducers of Acoustic Waves Structural Health Monitoring (SHM) is the interdisciplinary engineering field devoted to the monitoring and assessment of structural health and durability. SHM technology integrates remote sensing, smart materials, and computer based knowledge systems to allow engineers see how built up structures are performing over time. It is particularly useful for remotely monitoring large infrastructure systems, such as bridges and dams, and high profile mechanical systems such as aircraft, spacecraft, ships, offshore structures and pipelines where performance is critical but onsite monitoring is diffStructural analysis (Engineering)Piezoelectric devicesPiezoelectric transducersAutomatic data collection systemsStructural analysis (Engineering)Piezoelectric devices.Piezoelectric transducers.Automatic data collection systems.624.1/71Giurgiutiu Victor622142MiAaPQMiAaPQMiAaPQBOOK9911006624903321Structural health monitoring with piezoelectric wafer active sensors4389035UNINA