Smart TechnologiesThis book is a general introduction to intelligent or smart materials, systems and machines. Presented in understandable and non-mathematical terms, it is for anyone who is interested in future developments in these fields or who needs to be briefed on the current status of these interdisciplinary technologies. The intended audience comprises physicists, engineers, materials scientists and computer scientists of all levels, from undergraduates to post-doctoral practitioners. Contents: The Smart Approach OCo An Introduction to Smart Technologies; Sensing Systems for Smart Structures; Vibration Control Using Smart Structures; Data Fusion OCo The Role of Signal Processing for Smart Structures and Systems; Shape Memory Alloys OCo A Smart Technology?; Piezoelectric Materials; Magnetostriction; Smart Fluid Machines; Smart Biomaterials OCo OC Out-SmartingOCO the Body''s Defence Systems and Other Advances in Materials for Medicine; Natural Engineering OCo The Smart Synergy. Readership: Undergraduates and researchers in materials science and engineering, electrical & electronic engineering, systems engineering and aerospace engineering." |
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Page ix
... Effect 111 113 5.7 Why Not Use Bimetals ? 5.5 Pseudoelasticity or the Superelastic Effect 5.6 A Brief History of ... Piezoelectric Materials 141 6.1 Introduction to Piezoelectricity . . 141 6.1.1 Crystallography of Piezoelectricity 142 ...
... Effect 111 113 5.7 Why Not Use Bimetals ? 5.5 Pseudoelasticity or the Superelastic Effect 5.6 A Brief History of ... Piezoelectric Materials 141 6.1 Introduction to Piezoelectricity . . 141 6.1.1 Crystallography of Piezoelectricity 142 ...
Page x
... Piezoelectric Effect 144 145 147 6.3 Acoustic Transducers . . 149 6.4 Piezoelectric Actuators . 149 6.4.1 Bimorphs and Other Bending Piezo - Actuators 150 6.4.2 Monolithic Actuators 152 6.4.2.1 Moonies and Cymbals 153 6.4.3 Stack and ...
... Piezoelectric Effect 144 145 147 6.3 Acoustic Transducers . . 149 6.4 Piezoelectric Actuators . 149 6.4.1 Bimorphs and Other Bending Piezo - Actuators 150 6.4.2 Monolithic Actuators 152 6.4.2.1 Moonies and Cymbals 153 6.4.3 Stack and ...
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Contents
Preface | 1 |
Sensing Systems for Smart Structures | 7 |
Vibration Control Using Smart Structures | 37 |
Bibliography | 69 |
Shape Memory Alloys A Smart Technology? | 109 |
137 | |
169 | |
Appendix A The MultiLayer Perceptron | 191 |
7 | 203 |
Applications | 213 |
219 | |
2 | 226 |
6 | 244 |
Bibliography | 269 |
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Common terms and phrases
acoustic active actuator actuator applications antenna beam behaviour bimorph biological biomaterials bone cell ceramic chemical clamps closed loop composite compressive crystal damping Data Fusion deformation developed dipoles distribution dynamic elastic electric field electrodes end-caps example external fibre fluid function heat implant increase input integration Lamb wave layers linear load magnetic field magnetocrystalline anisotropy magnetoelastic magnetostrictive magnetostrictive materials martensitic transformation measurement mechanical medical devices memory effect microstructure mode shapes Moonie motor multi-layer NiTi alloys optical parameters parent phase piezo piezoceramic piezoelectric actuators piezoelectric effect piezoelectric material plate polymer position problem Proc produce properties resonant frequency response sensing sensors and actuators shape memory alloys shape memory effect shear signal slewing SMA actuators smart materials smart structures smart systems smart technologies strain stress superelastic surface temperature Terfenol-D thermal tion tissue engineering transducer valve vibration control voltage Young's modulus