Analysis of piezoelectric devices:
Gespeichert in:
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| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Hackensack, NJ
World Scientific
c2006
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| Online-Zugang: | FAW01 FAW02 Volltext |
| Beschreibung: | Includes bibliographical references (p. 491-500) and index Ch. 1. Three-dimensional theories. 1.1. Nonlinear electroelasticity for strong fields. 1.2. Linear piezoelectricity for infinitesimal fields. 1.3. Linear theory for small fields superposed on a finite bias. 1.4. Cubic theory for weak nonlinearity -- ch. 2. Thickness-shear modes of plate resonators. 2.1. Static thickness-shear deformation. 2.2. Nonlinear thickness-shear deformation. 2.3. Effects of initial fields on thickness-shear deformation. 2.4. Linear thickness-shear vibration. 2.5. Effects of electrode inertia. 2.6. Inertial effects of imperfectly bounded electrodes. 2.7. Effects of electrode inertia and shear stiffness. 2.8. Nonlinear thickness-shear vibration. 2.9. Effects of initial fields on thickness-shear vibration -- - ch. 3. Slowly varying thickness-shear modes. 3.1. Exact waves in a plate. 3.2. An approximate equation for thickness-shear waves. 3.3. Thickness-shear vibration of finite plates. 3.4. Energy trapping in mesa resonators. 3.5. Contoured resonators. 3.6. Energy trapping due to material inhomogeneity. 3.7. Energy trapping by electrode mass. 3.8. Effects of non-uniform electrodes. 3.9. Effectsof electromechanical coupling on energy trapping. 3.10. Coupling to flexure. 3.11. Coupling to face-shear and flexure. 3.12. Effects of middle surface curvature -- - ch. 4. Mass sensors. 4.1. Inertial effect of a mass layer by perturbation. 4.2. Thickness-shear modes of a plate. 4.3. Anti-plane modes of a wedge. 4.4. Torsional modes of a conical shell. 4.5. Effects of inertia and stiffness of a mass layer by perturbation. 4.6. Effects of inertia and stiffness of a mass layer by variation. 4.7. Radial modes of a ring. 4.8. Effects of shear deformability ofa mass layer. 4.9. Thickness-shear modes ofa plate with thick mass layers. 4.10. An ill-posed problem in elasticity for mass sensors. 4.11. Thickness-shear modes of a circular cylinder. 4.12. Mass sensitivity of surface waves. 4.13. Thickness-twist waves in a ceramic plate. 4.14. Bechmann's number for thickness-twist waves. 4.15. Thickness-twist waves in a quartz plate -- - ch. 5. Fluid sensors. 5.1. An ill-posed problem in elasticity for fluid sensors. 5.2. Perturbation analysis. 5.3. Thickness-shear modes of a plate. 5.4. Torsional modes of a cylindrical shell. 5.5. Thickness-shear modes of a circular cylinder. 5.6. Surface wave fluid sensors. 5.7. Thickness-twist waves in a ceramic plate -- ch. 6. Gyroscopes -- frequency effect. 6.1. High frequency vibrations of a small rotating piezoelectric body. 6.2. Propagation of plane waves. 6.3. Thickness vibrations of plates. 6.4. Propagating waves in a rotating piezoelectric plate. 6.5. Surface waves over a rotating piezoelectric half-space -- ch. 7. Gyroscopes -- charge effect. 7.1. A rectangular beam. 7.2. A circular tube. 7.3. A beam bimorph. 7.4. An inhomogeneous shell. 7.5. A ceramic ring. 7.6. A concentrated mass and ceramic rods. 7.7. A ceramic plate by two-dimensional equations. 7.8. A ceramic plate by zero-dimensional equations -- - ch. 8. Acceleration sensitivity. 8.1. Deformation of a quartz plate under normal acceleration. 8.2. First-order acceleration sensitivity. 8.3. An estimate of second-order acceleration sensitivity and its reduction. 8.4. Second-order perturbation analysis. 8.5. Second-order normal acceleration sensitivity. 8.6. Effects of middle surface curvature. 8.7. Vibration sensitivity -- ch. 9. Pressure sensors. 9.1. A rectangular plate in a circular cylindrical shell. 9.2. A circular plate in a circular cylindrical shell. 9.3. A rectangular plate in a shallow shell. 9.4. A bimorph. 9.5. Surface wave pressure sensors based on extension. 9.6. Surface wave pressure sensors based on flexure -- ch. 10. Temperature sensors. 10.1. Thermoelectroelasticity. 10.2. Linear theory. 10.3. Small fields superposed on a thermal bias. 10.4. Thickness-shear modes of a free plate. 10.5. Thickness-shear modes of a constrained plate -- - ch. 11. Piezoelectric generators. 11.1. Thickness-stretch of a ceramic plate. 11.2. A circular shell. 11.3. A beam bimorph. 11.4. A spiral bimorph. 11.5. Nonlinear behavior near resonance -- ch. 12. Piezoelectric transformers. 12.1. A thickness-stretch mode plate transformer. 12.2. Rosen transformer. 12.3. A thickness-shear mode transformer -- free vibration. 12.4. A thickness-shear mode transformer -- forced vibration -- ch. 13. Power transmissiion through an elastic wall. 13.1. Formulation of the problem. 13.2. Theoretical analysis. 13.3. Numerical results -- ch. 14. Acoustic wave amplifiers. 14.1. Equations for piezoelectric semiconductors. 14.2. Equations for a thin film. 14.3. Surface waves. 14.4. Interface waves. 14.5. Waves in a plate. 14.6. Gap waves This is the most systematic, comprehensive and up-to-date book on the theoretical analysis of piezoelectric devices. It is a natural continuation of the author's two previous books: "An Introduction to the Theory of Piezoelectricity" (Springer, 2005) and "The Mechanics of Piezoelectric Structures" (World Scientific, 2006). Based on the linear, nonlinear, three-dimensional and lower-dimensional structural theories of electromechanical materials, theoretical results are presented for devices such as piezoelectric resonators, acoustic wave sensors, and piezoelectric transducers. The book reflects the contribution to the field from Mindlin's school of applied mechanics researchers since the 1950s |
| Beschreibung: | 1 Online-Ressource (xv, 520 p.) |
| ISBN: | 1281373079 9781281373076 9789812568618 9789812773180 9812568611 9812773185 |
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| 100 | 1 | |a Yang, Jiashi |e Verfasser |4 aut | |
| 245 | 1 | 0 | |a Analysis of piezoelectric devices |c Jiashi Yang |
| 264 | 1 | |a Hackensack, NJ |b World Scientific |c c2006 | |
| 300 | |a 1 Online-Ressource (xv, 520 p.) | ||
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| 500 | |a Includes bibliographical references (p. 491-500) and index | ||
| 500 | |a Ch. 1. Three-dimensional theories. 1.1. Nonlinear electroelasticity for strong fields. 1.2. Linear piezoelectricity for infinitesimal fields. 1.3. Linear theory for small fields superposed on a finite bias. 1.4. Cubic theory for weak nonlinearity -- ch. 2. Thickness-shear modes of plate resonators. 2.1. Static thickness-shear deformation. 2.2. Nonlinear thickness-shear deformation. 2.3. Effects of initial fields on thickness-shear deformation. 2.4. Linear thickness-shear vibration. 2.5. Effects of electrode inertia. 2.6. Inertial effects of imperfectly bounded electrodes. 2.7. Effects of electrode inertia and shear stiffness. 2.8. Nonlinear thickness-shear vibration. 2.9. Effects of initial fields on thickness-shear vibration -- | ||
| 500 | |a - ch. 3. Slowly varying thickness-shear modes. 3.1. Exact waves in a plate. 3.2. An approximate equation for thickness-shear waves. 3.3. Thickness-shear vibration of finite plates. 3.4. Energy trapping in mesa resonators. 3.5. Contoured resonators. 3.6. Energy trapping due to material inhomogeneity. 3.7. Energy trapping by electrode mass. 3.8. Effects of non-uniform electrodes. 3.9. Effectsof electromechanical coupling on energy trapping. 3.10. Coupling to flexure. 3.11. Coupling to face-shear and flexure. 3.12. Effects of middle surface curvature -- | ||
| 500 | |a - ch. 4. Mass sensors. 4.1. Inertial effect of a mass layer by perturbation. 4.2. Thickness-shear modes of a plate. 4.3. Anti-plane modes of a wedge. 4.4. Torsional modes of a conical shell. 4.5. Effects of inertia and stiffness of a mass layer by perturbation. 4.6. Effects of inertia and stiffness of a mass layer by variation. 4.7. Radial modes of a ring. 4.8. Effects of shear deformability ofa mass layer. 4.9. Thickness-shear modes ofa plate with thick mass layers. 4.10. An ill-posed problem in elasticity for mass sensors. 4.11. Thickness-shear modes of a circular cylinder. 4.12. Mass sensitivity of surface waves. 4.13. Thickness-twist waves in a ceramic plate. 4.14. Bechmann's number for thickness-twist waves. 4.15. Thickness-twist waves in a quartz plate -- | ||
| 500 | |a - ch. 5. Fluid sensors. 5.1. An ill-posed problem in elasticity for fluid sensors. 5.2. Perturbation analysis. 5.3. Thickness-shear modes of a plate. 5.4. Torsional modes of a cylindrical shell. 5.5. Thickness-shear modes of a circular cylinder. 5.6. Surface wave fluid sensors. 5.7. Thickness-twist waves in a ceramic plate -- ch. 6. Gyroscopes -- frequency effect. 6.1. High frequency vibrations of a small rotating piezoelectric body. 6.2. Propagation of plane waves. 6.3. Thickness vibrations of plates. 6.4. Propagating waves in a rotating piezoelectric plate. 6.5. Surface waves over a rotating piezoelectric half-space -- ch. 7. Gyroscopes -- charge effect. 7.1. A rectangular beam. 7.2. A circular tube. 7.3. A beam bimorph. 7.4. An inhomogeneous shell. 7.5. A ceramic ring. 7.6. A concentrated mass and ceramic rods. 7.7. A ceramic plate by two-dimensional equations. 7.8. A ceramic plate by zero-dimensional equations -- | ||
| 500 | |a - ch. 8. Acceleration sensitivity. 8.1. Deformation of a quartz plate under normal acceleration. 8.2. First-order acceleration sensitivity. 8.3. An estimate of second-order acceleration sensitivity and its reduction. 8.4. Second-order perturbation analysis. 8.5. Second-order normal acceleration sensitivity. 8.6. Effects of middle surface curvature. 8.7. Vibration sensitivity -- ch. 9. Pressure sensors. 9.1. A rectangular plate in a circular cylindrical shell. 9.2. A circular plate in a circular cylindrical shell. 9.3. A rectangular plate in a shallow shell. 9.4. A bimorph. 9.5. Surface wave pressure sensors based on extension. 9.6. Surface wave pressure sensors based on flexure -- ch. 10. Temperature sensors. 10.1. Thermoelectroelasticity. 10.2. Linear theory. 10.3. Small fields superposed on a thermal bias. 10.4. Thickness-shear modes of a free plate. 10.5. Thickness-shear modes of a constrained plate -- | ||
| 500 | |a - ch. 11. Piezoelectric generators. 11.1. Thickness-stretch of a ceramic plate. 11.2. A circular shell. 11.3. A beam bimorph. 11.4. A spiral bimorph. 11.5. Nonlinear behavior near resonance -- ch. 12. Piezoelectric transformers. 12.1. A thickness-stretch mode plate transformer. 12.2. Rosen transformer. 12.3. A thickness-shear mode transformer -- free vibration. 12.4. A thickness-shear mode transformer -- forced vibration -- ch. 13. Power transmissiion through an elastic wall. 13.1. Formulation of the problem. 13.2. Theoretical analysis. 13.3. Numerical results -- ch. 14. Acoustic wave amplifiers. 14.1. Equations for piezoelectric semiconductors. 14.2. Equations for a thin film. 14.3. Surface waves. 14.4. Interface waves. 14.5. Waves in a plate. 14.6. Gap waves | ||
| 500 | |a This is the most systematic, comprehensive and up-to-date book on the theoretical analysis of piezoelectric devices. It is a natural continuation of the author's two previous books: "An Introduction to the Theory of Piezoelectricity" (Springer, 2005) and "The Mechanics of Piezoelectric Structures" (World Scientific, 2006). Based on the linear, nonlinear, three-dimensional and lower-dimensional structural theories of electromechanical materials, theoretical results are presented for devices such as piezoelectric resonators, acoustic wave sensors, and piezoelectric transducers. The book reflects the contribution to the field from Mindlin's school of applied mechanics researchers since the 1950s | ||
| 650 | 7 | |a SCIENCE / Physics / Electromagnetism |2 bisacsh | |
| 650 | 7 | |a SCIENCE / Physics / Electricity |2 bisacsh | |
| 650 | 7 | |a Piezoelectric devices / Mathematical models |2 fast | |
| 650 | 4 | |a Mathematisches Modell | |
| 650 | 4 | |a Piezoelectric devices |x Mathematical models | |
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Datensatz im Suchindex
| _version_ | 1804175558222807040 |
|---|---|
| any_adam_object | |
| author | Yang, Jiashi |
| author_facet | Yang, Jiashi |
| author_role | aut |
| author_sort | Yang, Jiashi |
| author_variant | j y jy |
| building | Verbundindex |
| bvnumber | BV043125008 |
| collection | ZDB-4-EBA |
| ctrlnum | (OCoLC)226376829 (DE-599)BVBBV043125008 |
| dewey-full | 537/.2446 |
| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 537 - Electricity and electronics |
| dewey-raw | 537/.2446 |
| dewey-search | 537/.2446 |
| dewey-sort | 3537 42446 |
| dewey-tens | 530 - Physics |
| discipline | Physik |
| format | Electronic eBook |
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Three-dimensional theories. 1.1. Nonlinear electroelasticity for strong fields. 1.2. Linear piezoelectricity for infinitesimal fields. 1.3. Linear theory for small fields superposed on a finite bias. 1.4. Cubic theory for weak nonlinearity -- ch. 2. Thickness-shear modes of plate resonators. 2.1. Static thickness-shear deformation. 2.2. Nonlinear thickness-shear deformation. 2.3. Effects of initial fields on thickness-shear deformation. 2.4. Linear thickness-shear vibration. 2.5. Effects of electrode inertia. 2.6. Inertial effects of imperfectly bounded electrodes. 2.7. Effects of electrode inertia and shear stiffness. 2.8. Nonlinear thickness-shear vibration. 2.9. Effects of initial fields on thickness-shear vibration -- </subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a"> - ch. 3. Slowly varying thickness-shear modes. 3.1. Exact waves in a plate. 3.2. An approximate equation for thickness-shear waves. 3.3. Thickness-shear vibration of finite plates. 3.4. 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Thickness-shear modes of a circular cylinder. 4.12. Mass sensitivity of surface waves. 4.13. Thickness-twist waves in a ceramic plate. 4.14. Bechmann's number for thickness-twist waves. 4.15. Thickness-twist waves in a quartz plate -- </subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a"> - ch. 5. Fluid sensors. 5.1. An ill-posed problem in elasticity for fluid sensors. 5.2. Perturbation analysis. 5.3. Thickness-shear modes of a plate. 5.4. Torsional modes of a cylindrical shell. 5.5. Thickness-shear modes of a circular cylinder. 5.6. Surface wave fluid sensors. 5.7. Thickness-twist waves in a ceramic plate -- ch. 6. Gyroscopes -- frequency effect. 6.1. High frequency vibrations of a small rotating piezoelectric body. 6.2. Propagation of plane waves. 6.3. Thickness vibrations of plates. 6.4. Propagating waves in a rotating piezoelectric plate. 6.5. Surface waves over a rotating piezoelectric half-space -- ch. 7. Gyroscopes -- charge effect. 7.1. A rectangular beam. 7.2. A circular tube. 7.3. A beam bimorph. 7.4. An inhomogeneous shell. 7.5. A ceramic ring. 7.6. A concentrated mass and ceramic rods. 7.7. A ceramic plate by two-dimensional equations. 7.8. A ceramic plate by zero-dimensional equations -- </subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a"> - ch. 8. Acceleration sensitivity. 8.1. Deformation of a quartz plate under normal acceleration. 8.2. First-order acceleration sensitivity. 8.3. An estimate of second-order acceleration sensitivity and its reduction. 8.4. Second-order perturbation analysis. 8.5. Second-order normal acceleration sensitivity. 8.6. Effects of middle surface curvature. 8.7. Vibration sensitivity -- ch. 9. Pressure sensors. 9.1. A rectangular plate in a circular cylindrical shell. 9.2. A circular plate in a circular cylindrical shell. 9.3. A rectangular plate in a shallow shell. 9.4. A bimorph. 9.5. Surface wave pressure sensors based on extension. 9.6. Surface wave pressure sensors based on flexure -- ch. 10. Temperature sensors. 10.1. Thermoelectroelasticity. 10.2. Linear theory. 10.3. Small fields superposed on a thermal bias. 10.4. Thickness-shear modes of a free plate. 10.5. Thickness-shear modes of a constrained plate -- </subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a"> - ch. 11. Piezoelectric generators. 11.1. Thickness-stretch of a ceramic plate. 11.2. A circular shell. 11.3. A beam bimorph. 11.4. A spiral bimorph. 11.5. Nonlinear behavior near resonance -- ch. 12. Piezoelectric transformers. 12.1. A thickness-stretch mode plate transformer. 12.2. Rosen transformer. 12.3. A thickness-shear mode transformer -- free vibration. 12.4. A thickness-shear mode transformer -- forced vibration -- ch. 13. Power transmissiion through an elastic wall. 13.1. Formulation of the problem. 13.2. Theoretical analysis. 13.3. Numerical results -- ch. 14. Acoustic wave amplifiers. 14.1. 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| id | DE-604.BV043125008 |
| illustrated | Not Illustrated |
| indexdate | 2024-07-10T07:18:12Z |
| institution | BVB |
| isbn | 1281373079 9781281373076 9789812568618 9789812773180 9812568611 9812773185 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-028549199 |
| oclc_num | 226376829 |
| open_access_boolean | |
| owner | DE-1046 DE-1047 |
| owner_facet | DE-1046 DE-1047 |
| physical | 1 Online-Ressource (xv, 520 p.) |
| psigel | ZDB-4-EBA ZDB-4-EBA FAW_PDA_EBA |
| publishDate | 2006 |
| publishDateSearch | 2006 |
| publishDateSort | 2006 |
| publisher | World Scientific |
| record_format | marc |
| spelling | Yang, Jiashi Verfasser aut Analysis of piezoelectric devices Jiashi Yang Hackensack, NJ World Scientific c2006 1 Online-Ressource (xv, 520 p.) txt rdacontent c rdamedia cr rdacarrier Includes bibliographical references (p. 491-500) and index Ch. 1. Three-dimensional theories. 1.1. Nonlinear electroelasticity for strong fields. 1.2. Linear piezoelectricity for infinitesimal fields. 1.3. Linear theory for small fields superposed on a finite bias. 1.4. Cubic theory for weak nonlinearity -- ch. 2. Thickness-shear modes of plate resonators. 2.1. Static thickness-shear deformation. 2.2. Nonlinear thickness-shear deformation. 2.3. Effects of initial fields on thickness-shear deformation. 2.4. Linear thickness-shear vibration. 2.5. Effects of electrode inertia. 2.6. Inertial effects of imperfectly bounded electrodes. 2.7. Effects of electrode inertia and shear stiffness. 2.8. Nonlinear thickness-shear vibration. 2.9. Effects of initial fields on thickness-shear vibration -- - ch. 3. Slowly varying thickness-shear modes. 3.1. Exact waves in a plate. 3.2. An approximate equation for thickness-shear waves. 3.3. Thickness-shear vibration of finite plates. 3.4. Energy trapping in mesa resonators. 3.5. Contoured resonators. 3.6. Energy trapping due to material inhomogeneity. 3.7. Energy trapping by electrode mass. 3.8. Effects of non-uniform electrodes. 3.9. Effectsof electromechanical coupling on energy trapping. 3.10. Coupling to flexure. 3.11. Coupling to face-shear and flexure. 3.12. Effects of middle surface curvature -- - ch. 4. Mass sensors. 4.1. Inertial effect of a mass layer by perturbation. 4.2. Thickness-shear modes of a plate. 4.3. Anti-plane modes of a wedge. 4.4. Torsional modes of a conical shell. 4.5. Effects of inertia and stiffness of a mass layer by perturbation. 4.6. Effects of inertia and stiffness of a mass layer by variation. 4.7. Radial modes of a ring. 4.8. Effects of shear deformability ofa mass layer. 4.9. Thickness-shear modes ofa plate with thick mass layers. 4.10. An ill-posed problem in elasticity for mass sensors. 4.11. Thickness-shear modes of a circular cylinder. 4.12. Mass sensitivity of surface waves. 4.13. Thickness-twist waves in a ceramic plate. 4.14. Bechmann's number for thickness-twist waves. 4.15. Thickness-twist waves in a quartz plate -- - ch. 5. Fluid sensors. 5.1. An ill-posed problem in elasticity for fluid sensors. 5.2. Perturbation analysis. 5.3. Thickness-shear modes of a plate. 5.4. Torsional modes of a cylindrical shell. 5.5. Thickness-shear modes of a circular cylinder. 5.6. Surface wave fluid sensors. 5.7. Thickness-twist waves in a ceramic plate -- ch. 6. Gyroscopes -- frequency effect. 6.1. High frequency vibrations of a small rotating piezoelectric body. 6.2. Propagation of plane waves. 6.3. Thickness vibrations of plates. 6.4. Propagating waves in a rotating piezoelectric plate. 6.5. Surface waves over a rotating piezoelectric half-space -- ch. 7. Gyroscopes -- charge effect. 7.1. A rectangular beam. 7.2. A circular tube. 7.3. A beam bimorph. 7.4. An inhomogeneous shell. 7.5. A ceramic ring. 7.6. A concentrated mass and ceramic rods. 7.7. A ceramic plate by two-dimensional equations. 7.8. A ceramic plate by zero-dimensional equations -- - ch. 8. Acceleration sensitivity. 8.1. Deformation of a quartz plate under normal acceleration. 8.2. First-order acceleration sensitivity. 8.3. An estimate of second-order acceleration sensitivity and its reduction. 8.4. Second-order perturbation analysis. 8.5. Second-order normal acceleration sensitivity. 8.6. Effects of middle surface curvature. 8.7. Vibration sensitivity -- ch. 9. Pressure sensors. 9.1. A rectangular plate in a circular cylindrical shell. 9.2. A circular plate in a circular cylindrical shell. 9.3. A rectangular plate in a shallow shell. 9.4. A bimorph. 9.5. Surface wave pressure sensors based on extension. 9.6. Surface wave pressure sensors based on flexure -- ch. 10. Temperature sensors. 10.1. Thermoelectroelasticity. 10.2. Linear theory. 10.3. Small fields superposed on a thermal bias. 10.4. Thickness-shear modes of a free plate. 10.5. Thickness-shear modes of a constrained plate -- - ch. 11. Piezoelectric generators. 11.1. Thickness-stretch of a ceramic plate. 11.2. A circular shell. 11.3. A beam bimorph. 11.4. A spiral bimorph. 11.5. Nonlinear behavior near resonance -- ch. 12. Piezoelectric transformers. 12.1. A thickness-stretch mode plate transformer. 12.2. Rosen transformer. 12.3. A thickness-shear mode transformer -- free vibration. 12.4. A thickness-shear mode transformer -- forced vibration -- ch. 13. Power transmissiion through an elastic wall. 13.1. Formulation of the problem. 13.2. Theoretical analysis. 13.3. Numerical results -- ch. 14. Acoustic wave amplifiers. 14.1. Equations for piezoelectric semiconductors. 14.2. Equations for a thin film. 14.3. Surface waves. 14.4. Interface waves. 14.5. Waves in a plate. 14.6. Gap waves This is the most systematic, comprehensive and up-to-date book on the theoretical analysis of piezoelectric devices. It is a natural continuation of the author's two previous books: "An Introduction to the Theory of Piezoelectricity" (Springer, 2005) and "The Mechanics of Piezoelectric Structures" (World Scientific, 2006). Based on the linear, nonlinear, three-dimensional and lower-dimensional structural theories of electromechanical materials, theoretical results are presented for devices such as piezoelectric resonators, acoustic wave sensors, and piezoelectric transducers. The book reflects the contribution to the field from Mindlin's school of applied mechanics researchers since the 1950s SCIENCE / Physics / Electromagnetism bisacsh SCIENCE / Physics / Electricity bisacsh Piezoelectric devices / Mathematical models fast Mathematisches Modell Piezoelectric devices Mathematical models http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=210749 Aggregator Volltext |
| spellingShingle | Yang, Jiashi Analysis of piezoelectric devices SCIENCE / Physics / Electromagnetism bisacsh SCIENCE / Physics / Electricity bisacsh Piezoelectric devices / Mathematical models fast Mathematisches Modell Piezoelectric devices Mathematical models |
| title | Analysis of piezoelectric devices |
| title_auth | Analysis of piezoelectric devices |
| title_exact_search | Analysis of piezoelectric devices |
| title_full | Analysis of piezoelectric devices Jiashi Yang |
| title_fullStr | Analysis of piezoelectric devices Jiashi Yang |
| title_full_unstemmed | Analysis of piezoelectric devices Jiashi Yang |
| title_short | Analysis of piezoelectric devices |
| title_sort | analysis of piezoelectric devices |
| topic | SCIENCE / Physics / Electromagnetism bisacsh SCIENCE / Physics / Electricity bisacsh Piezoelectric devices / Mathematical models fast Mathematisches Modell Piezoelectric devices Mathematical models |
| topic_facet | SCIENCE / Physics / Electromagnetism SCIENCE / Physics / Electricity Piezoelectric devices / Mathematical models Mathematisches Modell Piezoelectric devices Mathematical models |
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| work_keys_str_mv | AT yangjiashi analysisofpiezoelectricdevices |