Opis: Modeling and Control for Micro/Nano Devices and Systems

Micro/nano-scale engineering-especially the design and implementation of ultra-fast and ultra-scale energy devices, sensors, and cellular and molecular systems-remains a daunting challenge. Modeling and control has played an essential role in many technological breakthroughs throughout the course of history. Therefore, the need for a practical guide to modeling and control for micro/nano-scale devices and systems has emerged. The first edited volume to address this rapidly growing field, Modeling and Control for Micro/Nano Devices and Systems gives control engineers, lab managers, high-tech researchers, and graduate students easy access to the expert contributors' cutting-edge knowledge of micro/nanotechnology, energy, and bio-systems. The editors offer an integrated view from theory to practice, covering diverse topics ranging from micro/nano-scale sensors to energy devices and control of biology systems in cellular and molecular levels. The book also features numerous case studies for modeling of micro/nano devices and systems, and explains how the models can be used for control and optimization purposes. Readers benefit from learning the latest modeling techniques for micro/nano-scale devices and systems, and then applying those techniques to their own research and development efforts. "The chapter authors are well-known researchers and the content is well organized and fits tightly together. In this emerging and fast-developing field, the fact that the book is an edited volume ... allows [it] to cover new topics that are still currently under research." - Frank L. Lewis, Automation and Robotics Research Institute, University of Texas at Arlington, USA "I am convinced there is a strong need for a book on modeling and control of nano-scale devices, as this is a new, emerging area, and one for which there are no good books." - Declan Bates, University of Leeds, UK "... micro/nano devices and systems [is] a field that is expected to continue its rapid expansion. This is an excellent review with top-notch authors [and] broad coverage, and [it is] timely ... there is no competition, since this book is one of a kind." - Hong Zhang, University of Alberta, Edmonton, CanadaOn the Principles of Quantum Control Theory Introduction Mechanism of Quantum Control Modeling and Analysis of Quantum Control Systems Control Design Methodologies Open-Loop Control Quantum Systems Closed-Loop Control Quantum Systems Perspectives Modeling and Simulation Study of Biosensors Introduction The Basics of SiNW-Based FET Biosensor Theoretical Approaches Simulation Results and Discussions Surface Potential on SiNW I-V Characteristics of the SiNW FET Biosensor Sensitivity Analysis Discussions Conclusions and Perspectives Modeling and Simulation of Organic Photovoltaic Cells Introduction Fundamentals of Organic Photovoltaic Cells Optical Modeling Electrical Modeling and Simulation by Drift-Diffusion Model Electrical Modeling and Simulation by Monte Carlo Model Discussion and Conclusion Optimization of Organic Photovoltaic Cells Introduction Optimizing Device Thickness via Optical Model and Electrical Simulation Optimizing Device via Multiscale Simulation Discussion and Conclusion Developing Dynamics Model for Epidermal Growth Factor (EGF) Induced Cellular Signaling Events Introduction AFM Energy Dissipation and Hysteresivity Measurements QCM-D Energy Dissipation Measurement Model Development AFM Viscoelastic Characterization QCM-D-Based Cell Membrane Peeling Model Results and Discussion Conclusion Modeling and Experimental Verifications of Cell Tensegrity Introduction Desmosome Disruption Leads to Decrease in Cell Stiffness Desmosome Disassembly Results in Stiffness Decrease AFM-Based Nanosurgery Resulting in the Decrease of Stiffness Quantitative Modeling Based on Six Struts Tensegrity Structure Without Intermediate Filaments With Intermediate Filaments Conclusion and Perspectives Modeling Swimming Micro/Nano-Systems in Low Reynolds Number Introduction Prokaryotic Cell Swimming Strategies Prokaryotic Flagella Twitching Motility Gliding Motility Eukaryotic Cell Swimming Strategies Eukaryotic Flagella Cilia Pseudopodia Dynamics Modeling and Analysis of a Swimming Microrobot for Controlled Drug Delivery Modeling and Analysis of the Cellular Mechanics Involved in the Pathophysiology of Disease/Injury Introduction Modeling, Analysis, and Control of Cellular Mechanics in Disease/Injury Applications in Cancer Applications in Cardiovascular Disease Advances in Experimental and Imaging Techniques (BioMEMS/NEMS) An Example: Cardiomyocyte Mechanics Experimental Setup/Design Model Development Discussion Conclusions Hybrid Control for Micro/Nano Devices and Systems Introduction Problem Formulation Control Framework, Control Design, and Analysis Control Framework Feed-Forward Control Design Design of the Time-Driven and Data-Driven Planners Planners Switching Control Mechanism Robustness Analysis Example Conclusions

Szczegóły: Modeling and Control for Micro/Nano Devices and Systems

Tytuł: Modeling and Control for Micro/Nano Devices and Systems
Producent: Taylor
ISBN: 9781466554054
Rok produkcji: 2013
Ilość stron: 175
Oprawa: Twarda
Waga: 0.45 kg

Recenzje: Modeling and Control for Micro/Nano Devices and Systems