方岱宁、王骥、陈伟球编著的《压电结构与器件分析(英文版)》包括压电结构分析的各种新方法，涉及波动、高频振动、材料性能和结构优化等专题，以及压电材料表征和结构优化的新颖方法等新型压电器件微结构的设计和优化的核心理论和内容。作者包括基础理论和应用技术领域的专家，内容源自最新的前沿创新研究，对研究方向有深入探究和丰富讨论。

《压电结构与器件分析(英文版)》涵盖了现代结构和器件中广泛应用的梁、板、壳等形式的新型压电材料构件的分析理论和方法。这类构件通常是谐振器、传感器、驱动器、振荡器等智能结构系统中的核心频率控制和检测单元，通过计算机和信息产品在我们的日常生活中扮演着重要角色。收录的专题包含了压电结构分析中的主要现象如波传播和高频振动，以及压电材料表征和结构优化的新颖方法等新型压电器件微结构的设计和优化的核心理论和内容。《压电结构与器件分析(英文版)》由方岱宁、王骥、陈伟球编著。

Chapter 1 Jing Jiang， HongHao Yue， ZongQuan Deng， and HornSen Tzou

Non—uniform Actuations of Plates and Shells with Piezoelectricand Photostrietive Skew—quad Actuator Designs —— 1

 1.1 Introduction—— 2

 1.2 New SQ actuator system —— 3

1.2.1 The distribution profile of induced non—uniform forces and moments——4

1.2.2 Design of an SQ actuator system —— 7

 1.3 Plate control with a piezoelectric SQ actuator system —— 7

1.3.1 Non—uniform forces and moments induced by the SQ actuator system —— 8

1.3.2 Modal control —— 9

1.3.3 Case studies： control of plates —— 10

1.3.4 Closed—loop actuation with collocated sensors and actuators —— 16

1.3.5 Summary of non—uniform piezoelectric actuations of plates —— 20

 1.4 Cylindrical shell control with photostrictive SQ actuator systems —— 21

1.4.1 Uniform and non—uniform photostrictive actuation —— 22

1.4.2 Photostrictive SQ actuator —— 24

1.4.3 Modal control —— 26

1.4.4 Case studies： photostrictive actuation of shells —— 27

1.4.5 Closed—loop actuation with paired SQ actuator systems —— 34

1.4.6 Summary of non—uniform photostrictive actuations of shells —— 36

 1.5 Summary —— 37

 References —— 39

 Appendix —— 41

Chapter 2 ChunLi Zhang and WeiQiu Chen Structural Theories of Multiferroic Plates and Shells —— 43

 2.1 Introduction —— 44

 2.2 Basic formulations —— 45

 2.3 Laminated multiferroic shell equations in orthogonal curvilinearcoordinates —— 46

 2.4 Equations of first—order theory for laminated multiferroic shells —— 50

 2.5 Equations for flat plates and cylindrical/spherical shells —— 52

2.5.1 Flat plates —— 52

2.5.2 Cylindrical shells —— 53

2.5.3 Spherical shells —— 55

 2.6 Applications： evaluation of magnetoelectric effects —— 57

2.6.1 Magnetoelectric effect in multiferroic bilayers —— 58

2.6.2 Magnetoelectric effect of multiferroic spherical shell laminates —— 62

 2.7 Summary —— 66

 References —— 66

 Appendix —— 67

Chapter 3 YuanTai Hu， Huan Xue， and HongPing Hu

Piezoelectric Power/Energy Harvesters —— 71

 3.1 Introduction —— 72

 3.2 Basic structure of a piezoelectric power/energy harvester —— 74

 3.3 Piezoelectric power harvesters —— 75

3.3.1 The related researches on piezoelectric power harvesters —— 75

3.3.2 Coupling analysis of piezoelectric power harvesters —— 76

3.3.3 Numerical results —— 80

3.3.4 Investigation on frequency shift of piezoelectric power harvesters —— 83

3.3.5 Broadband design of piezoelectric power harvesters —— 88

 3.4 Piezoelectric energy harvesters —— 91

3.4.1 Component portions of piezoelectric energy harvesters —— 91

3.4.2 Integrated analysis of piezoelectric energy harvesters —— 94

3.4.3 Numerical results —— 101

 References —— 108

Chapter 4 Ji Wang， RongXing Wu， JinBo Lin， QiaoQiao Pan， and JianKe Du

A Two—dimensional Analysis of Surface Acoustic Waves

in Finite Piezoelectric Plates —— 113

 4.1 Introduction —— 114

 4.2 A two—dimensional analysis of surface acoustic waves in finite isotropic elastic plates —— 115

4.2.1 Surface acoustic waves in an infinite isotropic elastic plate —— 115

4.2.2 Two—dimensional equations for finite isotropic elastic plate —— 120

4.2.3 Conclusions—— 126

 4.3 A two—dimensional analysis of surface acoustic waves in finite anisotropic elastic plates —— 126

4.3.1 Surface acoustic waves in semi—infinite anisotropic solids —— 126

4.3.2 Two—dimensional equations for finite anisotropic elastic plates —— 129

4.3.3 Conclusions —— 132

 4.4 A two—dimensional analysis of surface acoustic waves in finite piezoelectric plates —— 133

4.4.1 Surface acoustic waves in semi—infinite piezoelectric solids —— 133

4.4.2 Two—dimensional equations for finite piezoelectric elastic plates —— 135

4.4.3 Conclusions —— 138

 4.5 Summary —— 138

 References —— 139

Chapter 5 JianGong Yu

Wave Characteristics in the Functionally Graded Piezoelectric

Waveguides： Legendre Polynomial Approach —— 143

 5.1 Introduction —— 144

 5.2 Wave propagation in the FGPM plate —— 146

5.2.1 Mathematics and formulation —— 146

5.2.2 Numericalresults —— 151

 5.3 Circumferential wave in the FGPM cylindrical curved plate —— 153

5.3.1 Mathematics and formulation —— 153

5.3.2 Numerical results and discussion —— 159

5.3.3 Brief summary —— 172

 5.4 Axial wave in the FGPM hollow cylinders —— 172

5.4.1 Mathematics and formulation —— 173

5.4.2 Numerical results and discussion —— 175

5.4.3 Brief summary —— 185

 5.5 Wave propagation in FGPM spherical curved plates —— 185

5.5.1 Mathematics and formulation —— 185

5.5.2 Numerical results and discussion —— 190

 5.6 Summary —— 196

 References —— 197

Chapter 6 HuiMing Wang

Radial Vibration Analysis of Layered Piezoelectric Cylindrical

and Spherical Structures as Sensors and Actuators —— 201

 6.1 Introduction —— 202

 6.2 Basic equations for piezoelectric media —— 203

6.2.1 Basic equations for three—dimensional problems —— 203

6.2.2 Basic equations for radial motion —— 204

 6.3 Layered model and solution —— 205

6.3.1 Layered model and governing equations —— 205

6.3.2 The method of superposition —— 208

6.3.3 The quasi—static part —— 209

6.3.4 The dynamic solution—— 211

 6.4 Numerical results and analysis —— 212

 6.5 Summary—— 219

 References —— 220

 Appendix— 223

Chapter 7 Zheng—Hua Qian and Feng Jin

One Type of Transverse Surface Waves in Piezoelectric Layered Solids for Electro—acoustic Devices —— 227

 7.1 Introduction —— 228

 7.2 Transverse surface waves in piezoelectric layered solids —— 230

7.2.1 Piezoelectric layer and metal/dielectric substrate —— 230

7.2.2 Piezoelectric layered solids with a hard metal interlayer —— 235

 7.3 Transverse surface waves in prestressed piezoelectric layered solids —— 240

 7.4 Transverse surface waves in graded piezoelectric layered solids —— 243

7.4.1 Functionally graded covering layer —— 243

7.4.2 Functionally graded substrate —— 248

 7.5 Summary—— 251

 References —— 252

Chapter 8 HaiFeng Zhang

Theoretical Investigation of Force—frequency and Eleetroelastic Effects of Thickness Mode Langasite Resonators —— 255

 8.1 Introduction —— 256

 8.2 Perturbation integral for resonator frequency shift calculations —— 257

 8.3 Force—frequency effect of thickness mode langasite resonators —— 259

8.3.1 Background —— 259

8.3.2 Perturbation theory —— 261

8.3.3 Unperturbed mode —— 261

8.3.4 Diametrical force —— 263

8.3.5 Results —— 265

8.3.6 Conclusions —— 274

 8.4 Electroelastic effect of thickness mode langasite resonators—— 274

8.4.1 Introduction —— 275

8.4.2 Unperturbed modes —— 276

8.4.3 Biasing electric field—— 276

8.4.4 Results —— 278

8.4.5 Conclusions —— 282

 References —— 283

Chapter 9 WeiQiu Chen

Wave Propagation in a Piezoelectric Plate with Surface Effect——285

 9.1 Introduction——286

 9.2 Isotropic elastic material surface——287

 9.3 Surface piezOelectricity一291

 9.4 Waves in a piezoelectric plate with surface effect——293

9.4.1 Decomposition——295

9.4.2 Two independent classes of motion——297

9.4.3 Love type or SH waves——299

9.4.4 Rayleigh—Lamb type waves——304

 9.5 Summary——309

 References——310