Microsystem Dynamics: Principles and Applications introduces the basic principles of microsystem dynamics, presenting a unified theoretical framework with focus on some of the most important engineering applications (including computer hard disk drives). This framework has been designed to advance the analysis, design and control of dynamical microsystems.
This book presents cutting-edge methodologies of nonlinear science to address non-stationary, non-linear dynamics and control of the most critical dynamical microsystems in engineering and science. It introduces advanced tools including nonlinear signal processing, computational intelligence, and nonlinear chaos dynamics and control. Stability and durability aspects of the dynamical microsystems are considered in detail and recent advances in in microsystem dynamics are also presented.
Microsystem Dynamics: Principles and Applications is a comprehensive reference for engineers, academics and students who wish to have a systematic understanding of microsystem dynamics.
Preface vii 1 Introduction 1 1.1 Definition of Microsystem, Vibrations and Dynamics 1 1.2 Engineering and Scientific Significance of Microsystem Dynamics 2 1.3 Organization of the Book 4 2 Vibrations and Dynamics 7 2.1 Introduction 7 2.2 Vibration of Linear System Under Deterministic Excitations 7 2.2.1 Vibration of Linear Discrete and Continuous Systems 7 2.2.2 Vibration of Linear Discrete Systems: Single-degree-of-freedom System 8 2.2.3 Vibrations of Linear Discrete Systems: Multiple-degree-of-freedom System 12 2.2.3.1 Eigenvalues and Eigenvectors 13 2.2.3.2 Forced Vibration Solution of an MDOF System 15 2.2.4 Vibrations of Continuous Systems 16 2.2.4.1 Transverse Vibrations of String and Wave Equation 16 2.2.4.2 Longitudinal Vibration of Rods and Torsional Vibration of Shafts 20 2.2.4.3 Transverse Vibration of Beams 21 2.3 Random Vibrations Under Deterministic Excitations 24 2.3.1 Probability Density, Autocorrelation, and Power Spectral Density Function 25 2.3.2 Response of an SDOF System to an Arbitrary Function Input 27 2.3.3 Power Spectral Density Function 29 2.3.4 Joint Probability Density Function and Cross-correlation Function 30 2.3.5 Response of Linear Dynamic System to a Random Input 32 2.4 Nonlinear Vibrations 35 2.4.1 Perturbation Method, Duffing Equation 35 2.4.2 Amplitude Frequency-dependent and Jump Phenomenon 39 2.4.3 Van der Pol's equation 39 2.4.4 Method of Variation of Parameter 40 2.4.5 Phase Plot, Limit Cycles, Self-excited Oscillations, and Chaos 41 2.4.6 Stability of Equilibrium 43 2.4.7 Parametrically Excited System and Mathieu's Equation 46 2.4.8 Transient and Nonstationary Vibrations 48 2.4.9 Multi-degree-of-freedom Systems 48 2.5 Advanced Dynamics 49 2.5.1 Kinematics of Rigid Body 49 2.5.2 Linear and Angular Momentums of Rigid Body 58 2.5.3 Euler Equations of Rigid Body 59 2.5.4 Lagrange Equations 60 3 Surface Forces and Interface Interactions 65 3.1 Introduction 65 3.2 Contact Between Two Solid Surfaces 65 3.2.1 Description of Surfaces 65 3.2.2 Contact Mechanics of Two Solid Surfaces 67 3.3 Forces Between Two Solid Surfaces 72 3.3.1 Adhesion 72 3.3.1.1 Solid-Solid Adhesion 72 3.3.1.2 Liquid-mediated Adhesion 76 3.3.2 Friction 79 3.3.3 Nanoscale Contact and Friction 84 4 Nanoscale Dynamics of Air-bearing Slider in Computer Hard Disk Drives 99 4.1 Introduction 99 4.1.1 Modern Hard Disk Drive 99 4.1.2 Head-disk Interface 99 4.1.3 Microsystem-based Active Slider Technology 101 4.2 Dynamics of ABS in Sub-5-nm Clearance Regime 104 4.2.1 Nonlinear Dynamics of Slider in Sub-5-nm Clearance Regime 104 4.2.2 Multiple Interface Forces and System Modeling 106 4.2.2.1 Air-bearing Slider Contact Model 108 4.2.2.2 Intermolecular Force 110 4.2.2.3 Electrostatic Force 111 4.2.2.4 Meniscus Forces 114 4.2.3 Nonlinear Dynamics Due to Nonlinear Air-bearing Stiffness and Vibro-impact 115 4.3 Microsystem-based Active Slider Dynamics 119 4.3.1 Microsystem-based Active Thermal Flying-height Control Slider 119 4.3.2 Nanoscale Dynamics Sensing, Identification and Diagnosis 134 4.3.3 Active Control of Microsystem-based-slider Vibrations 147 4.3.4 Characterization of Dynamic Performance of Lubricant in Head-Disk Interface Using Molecular Dynamics 161 5 Microdynamics of Lithium-ion Batteries 177 5.1 Multiscale Systems in Lithium-ion Batteries 177 5.1.1 Modern Lithium-ion Batteries 177 5.1.2 Multiscale Characterizations of LIBs 177 5.2 Microstructure and Microstructural Dynamics of LIBs 180 5.2.1 Microstructure and Multiphysics System 180 5.2.2 Modeling of Dynamics of LIBs 186 5.2.2.1 Equivalent Circuit Models 187 5.2.2.2 Electrochemical Model 189 5.2.3 Microstructural Dynamics of Particles in LIBs 191 5.3 Acoustic Emission Diagnosis of Microscale Damages of LIBs 196 5.3.1 Detection of Damages in LIBs Using AE Testing 196 5.3.2 Evaluation of Microcracking in LIBs 197 5.3.3 Diagnosis and Identification of Microscale Damages of LIBs 202 6 Dynamics of Actuator in Microsystems 213 6.1 Introduction 213 6.2 MEMS Actuators 213 6.2.1 Structures of MEMS Actuators 213 6.2.2 Electrostatically and Thermally Actuated Devices 213 6.3 Modeling MEMS Structure and Solution 219 6.4 Effects of Surface Forces and Surface Roughness on MEMS Actuators 226 6.5 System Control of MEMS Actuators and Nonlinear Analysis 233 6.6 Research and Development of Emerging MEMS 242 References 253 Index 259
Gang S. Chen, Marshall University, USA Gang Sheng Chen is J. Robert Fletcher Associate Professor in the College of Information Technology and Engineering at Marshall University. His industry experience includes working in Gates Corp., IBM Corp., Sony Corp., and DSI (a Singapore National Lab). He is a Fellow of ASME and serves on the editorial boards of four international journals. His main area of interest is microsystem dynamics with applications in data storage systems. Jianfeng Xu, Huazhong University of Science and Technology, China Jianfeng Xu is a researcher in the School of Mechanical Engineering at Huazhong University of Science and Technology. Until recently he was a senior Mechanical Engineer for Applied Materials, Ltd. His main area of research focuses on microsystem technologies, including MEMS and related technologies.
