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100   $a20061030d2007      uy             0
101 0 $aeng
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181   $ctxt
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200 10$aSound and structural vibration$b[electronic resource] $eradiation, transmission and response /$fFrank Fahy, Paolo Gardonio
205   $a2nd ed.
210   $aAmsterdam ;$aLondon $cElsevier/Academic$d2007
215   $a1 online resource (665 p.)
225 1 $aScienceDirect
300   $aPrevious ed.: 1985.
311   $a0-12-506940-5 
311   $a0-12-373633-1 
320   $aIncludes bibliographical references and index.
327   $aFront cover; Sound and Structural Vibration; Copyright page; Table of contents; Preface to the First Edition; Preface to the Second Edition; Acknowledgements; List of Permissions; Introduction; Chapter 1. Waves in Fluids and Solid Structures; 1.1 Frequency and Wavenumber; 1.2 Sound Waves in Fluids; 1.3 Longitudinal Waves in Solids; 1.4 Quasi-Longitudinal Waves in Solids; 1.5 Transverse (Shear) Waves in Solids; 1.6 Bending Waves in Bars; 1.7 Bending Waves in Thin Plates; 1.8 Dispersion Curves; 1.9 Flexural Waves in Thin-Walled Circular Cylindrical Shells
327   $a1.10 Natural Frequencies and Modes of Vibration1.11 Forced Vibration and Resonance; 1.12 Modal Density and Modal Overlap; 1.13 The Roles of Modal Density in Vibroacoustics; Problems; Chapter 2. Structural Mobility, Impedance, Vibrational Energy and Power; 2.1 Mobility and Impedance Representations; 2.2 Concepts and General Forms of Mobility and Impedance of Lumped Mechanical Elements; 2.3 Mobility Functions of Uniform Beams in Bending; 2.4 Mobility and Impedance Functions of Thin Uniform Flat Plates; 2.5 Radial Driving-Point Mobility of Thin-Walled Circular Cylindrical Shells
327   $a2.6 Mobility and Impedance Matrix Models 2.7 Structural Power; 2.8 Energy Density and Energy Flux of Vibrational Waves; Problems; Chapter 3. Sound Radiation by Vibrating Structures; 3.1 The Importance and Mechanism of Sound Radiation by Vibrating Structures; 3.2 The Simple Volume Source; 3.3 Sound Radiation by a Pair of Elementary Surface Sources; 3.4 The Baffled Piston; 3.5 Sound Radiation by Flexural Modes of Plates; 3.6 Sound Radiation by Plates in Multi-Mode Flexural Vibration; 3.7 Independent Radiation Modes; 3.8 Sound Radiation by Flexural Waves in Plates
327   $a3.9 The Frequency-Average Radiation Efficiency of Plates 3.10 Sound Radiation due to Concentrated Forces and Displacements; 3.11 Sound Radiation by Non-Uniform Plate Structures; 3.12 Sound Radiation by Curved Shells; 3.13 Sound Radiation by Irregularly Shaped Vibrating Bodies; Problems; Chapter 4. Fluid Loading of Vibrating Structures; 4.1 Practical Aspects of Fluid Loading; 4.2 Pressure Fields on Vibrating Surfaces; 4.3 Wave Impedances of Structures and Fluids; 4.4 Fluid Loading of Vibrating Plates; 4.5 Natural Frequencies of Fluid-Loaded Plates
327   $a4.6 Effects of Fluid Loading on Sound Radiation from Point-Excited Plates 4.7 Natural Frequencies of Fluid-Loaded, Thin-Walled, Circular Cylindrical Shells; 4.8 Effects of Fluid Loading on Sound Radiation by Thin-Walled, Circular Cylindrical Shells; 4.9 Damping of Thin Plates by Porous Sheets; Problems; Chapter 5. Transmission of Sound through Partitions; 5.1 Practical Aspects of Sound Transmission through Partitions; 5.2 Transmission of Normally Incident Plane Waves through an Unbounded Partition; 5.3 Transmission of Obliquely Incident Plane Waves through an Unbounded Flexible Partition
327   $a5.4 Transmission of Diffuse Sound through a Bounded Partition in a Baffle
330   $aThe first edition of Sound and Structural Vibration was written in the early 1980's. Since then, two major developments have taken place in the field of vibroacoustics. Powerful computational methods and procedures for the numerical analysis of structural vibration, acoustical fields and acoustical interactions between fluids and structures have been developed and these are now universally employed by researchers, consultants and industrial organisations. Advances in signal processing systems and algorithms, in transducers, and in structural materials and forms of construction, have facilitated
410  0$aScienceDirect
606   $aSound
606   $aStructural dynamics
606   $aVibration
615  0$aSound.
615  0$aStructural dynamics.
615  0$aVibration.
676   $a620.2
700   $aFahy$b Frank$0509556
701   $aGardonio$b P$01502177
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910784658803321
996   $aSound and structural vibration$93729788
997   $aUNINA