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101 0 $aeng
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200 10$aPiezoelectric Electromechanical Transducers for Underwater Sound$hPart III$iCalculating transducers of different types$hPart IV$iSome aspects of transducers designing /$fBoris S. Aronov
205   $a1st ed.
210  1$aBoston, MA :$cAcademic Studies Press,$d[2022]
210  4$dİ2022
215   $a1 online resource (vii, 262 pages)
311 1 $a1-64469-823-4 
327   $tFrontmatter --$tPREFACE --$tTable Of Contents --$tPart III Calculating Transducers of Different Types --$tCHAPTER 7 Cylindrical Transducers --$tCHAPTER 8 Spherical Transducers --$tCHAPTER 9 Flexural Plate Transducers --$tCHAPTER 10 Length Expander Transducers and Their Modifications --$tPart IV Some Aspects of Transducers Designing --$tCHAPTER 11 Effects of Operational and Environmental Conditions --$tCHAPTER 12 Hydrostatic Pressure Equalization --$tCHAPTER 13 Projectors Designing Related Issues --$tCHAPTER 14 Sensors Designing Related Issues --$tCHAPTER 15 Combining Finite Element Analysis with Analytical Method --$tAfterword --$tLIST OF SYMBOLS --$tAPPENDIX A. Properties of Passive Materials --$tAPPENDIX B. Properties of Piezoelectric Ceramics --$tAPPENDIX C. Special Functions
330   $aThe book presents a broad-scope analysis of piezoelectric electromechanical transducers and the related aspects of practical transducer design for underwater applications. It uses an energy method for analyzing transducer problems that provides the physical insight important for the understanding of electromechanical devices. Application of the method is first illustrated with transducer examples that can be modeled as systems with a single degree of freedom, (such as spheres, short cylinders, bars and flexural disks and plates made of piezoelectric ceramics). Thereupon, transducers are modeled as devices with multiple degrees of freedom. In all these cases, results of modeling are presented in the form of equivalent electromechanical circuits convenient for the calculation of the transducers? operational characteristics. Special focus is made on the effects of coupled vibrations in mechanical systems on transducer performance. The book also provides extensive coverage of acoustic radiation including acoustic interaction between the transducers. The book is inherently multidisciplinary. It provides essential background regarding the vibration of elastic passive and piezoelectric bodies, piezoelectricity, acoustic radiation, and transducer characterization. Scientists and engineers working in the field of electroacoustics and those involved in education in the field will find this material useful not only for underwater acoustics, but also for electromechanics, energy conversion and medical ultrasonics.
606   $aPiezoelectric transducers
606   $aUnderwater acoustics
610   $aAcoustic Transduction.
610   $aelectroacoustics.
610   $aelectromechanical circuits.
610   $apiezoelectric transducers.
610   $aunderwater sound.
615  0$aPiezoelectric transducers.
615  0$aUnderwater acoustics.
676   $a681.2
700   $aAronov$b B. S$g(Boris Samuilovich)$4aut$4http://id.loc.gov/vocabulary/relators/aut$01436202
801  0$bDE-B1597
801  1$bDE-B1597
906   $aBOOK
912   $a996487161303316
996   $aPiezoelectric Electromechanical Transducers for Underwater Sound$93594539
997   $aUNISA