Micromechanics and MEMS: Classic and Seminal Papers to 1990William S. Trimmer Micromechanics is a rich, diverse field that draws on many different disciplines and has potential applications in medicine, electronic interfaces to physical phenomena, military, industrial controls, consumer products, airplanes, microsatellites, and much more. Until now, papers written during the earlier stages of this field have been difficult to retrieve. The papers included in this volume have been thoughtfully arranged by topic, and are accompanied by section introductions written by renowned expert William Trimmer. |
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Page 102
... constant current density , constant heat flow per unit surface area and constant temperature rise across the windings . It is assumed that the magnetic forces are generated by the interaction of two wires carrying current . ( The ...
... constant current density , constant heat flow per unit surface area and constant temperature rise across the windings . It is assumed that the magnetic forces are generated by the interaction of two wires carrying current . ( The ...
Page 114
... constant , and the loge term remains constant . ( This says that the distance to the heat sink , rt , must scale . ) Hence , ( A23 ) scales exactly the same way as ( A18 ) , and the scaling laws for this case are given by ( A19 ) . For ...
... constant , and the loge term remains constant . ( This says that the distance to the heat sink , rt , must scale . ) Hence , ( A23 ) scales exactly the same way as ( A18 ) , and the scaling laws for this case are given by ( A19 ) . For ...
Page 668
... constant C1 on 2 1.0 5 0.5 0.1 0.2 0.3 8 0.4 0.5 POISSON'S RATIO Dependence of the constant Co on Poisson's ratio and membrane shape . p = C1oth / a2 + C2Eth3 / a4 C1 = 4 ( 1 + n2 ) / 64 C2 6/32 ( 1 - v2 ) } { ( 9 + 2n2 + 9n4 ) / 256 ...
... constant C1 on 2 1.0 5 0.5 0.1 0.2 0.3 8 0.4 0.5 POISSON'S RATIO Dependence of the constant Co on Poisson's ratio and membrane shape . p = C1oth / a2 + C2Eth3 / a4 C1 = 4 ( 1 + n2 ) / 64 C2 6/32 ( 1 - v2 ) } { ( 9 + 2n2 + 9n4 ) / 256 ...
Contents
Early Papers in Micromechanics | 1 |
Valves and Pumps | 24 |
Side Drive Actuators | 145 |
Copyright | |
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alignment anisotropically etched applied bearing cantilever beam capacitance capacitor charge chip circuit comb components deflection density deposited detector diamagnetic diaphragm dielectric displacement doped drive elec electret electric field electrode electromechanical Electron Devices electrostatic actuators electrostatic force electrostatic motor etchant etching excitation fabrication fiber Figure friction geometry IEEE Micro IEEE Trans input insulation integrated layer levitation linear LPCVD magnetic mask material measured metal microactuators microdynamics micromechanical micromotor nitride operation optical optical fibers output oxide pattern phase plane plate pole faces polysilicon position potential radius ratio resistor rotation rotor scale Sensors and Actuators shape memory alloy shown in Fig side-drive motors silicon nitride silicon wafer SiO2 slider Solid-State Sensors stator stator poles structures substrate superconductor surface switch techniques temperature thermal thickness thin films tion torque Transducers valve voltage wire wobble motor Workshop Young's modulus