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200 10$aSmart MEMS and sensor systems$b[electronic resource] /$fElena Gaura & Robert Newman, with contributions from Michael Kraft, Andrew Flewitt, Davies William de Lima Monteiro
210   $aLondon $cImperial College$d2006
215   $a1 online resource (539 p. ) $cill
300   $aBibliographic Level Mode of Issuance: Monograph
311   $a1-86094-493-0 
320   $aIncludes bibliographical references and index.
327   $aPreface -- ch. 1. Markets and applications. 1.1. Technology at crossroads. 1.2. The present - MEMS in the news. 1.3. The past - great expectations. 1.4. The Future - maturity and pervasive applications. 1.5. Drivers for progress. 1.6. Progress - device improvement. 1.7. Progress - device integration. 1.8. Smart MEMS - the research agenda. 1.9. Structure of the book -- ch. 2. Microfabrication technologies. 2.1. Introduction. 2.2. Passive components. 2.3. Sensing components. 2.4. Actuating components. 2.5. Materials and growth. 2.6. Fabrication techniques. 2.7. Conclusions -- ch. 3. Sensor electronics. 3.1. Introduction. 3.2. Functions of a sensor system. 3.3. Analogue and digital design options. 3.4. Digital signal processing. 3.5. Interface configurations for different transducer types. 3.6. Integration. 3.7. Design for power awareness. 3.8. Conclusion -- ch. 4. Sensor signal enhancement. 4.1. Errors in sensor systems and measurement quality (non-linearity, cross-sensitivity, offset, parameter drift). 4.2. Sensor calibration and compensation - techniques and examples. 4.3. System design choices for compensation - closed loop configurations and other designs. 4.4. Summing up on sensor calibration and compensation -- ch. 5. Case study: control systems for capacitive inertial sensors. 5.1. Introduction. 5.2. Open loop accelerometer. 5.3. Closed loop accelerometer. 5.4. Conclusions -- ch. 6. Case study: adaptive optics and smart VLSI/MEMS systems. 6.1. Introduction. 6.2. Adaptive optics and MEMS systems. 6.3. Operational principles. 6.4. Device implementation. 6.5. Closed-loop adaptive optical system. 6.6. Conclusions and future trends -- ch. 7. Artificial intelligence techniques for microsensors identification and compensation. 7.1. Artificial neural networks: what they are and how they are used for microsensor control and identification. 7.2. Open loop, neural transducer prototype for static/low frequency applications. 7.3. Closed-loop neural network controlled accelerometer. 7.4. The neural network non-linear gain controller. 7.5. Micromachined sensor identification using neural networks. 7.6. Concluding remarks -- ch. 8. Smart, intelligent and cogent MEMS based sensors. 8.1. Introduction. 8.2. Smart, intelligent and cogent sensors - what do the terms mean. 8.3. What and where is the added value brought by intelligence? 8.4. ANNs and MEMS. 8.5. AI for MEMS intelligence. 8.6. 'Cogent' sensors - fault detection case study. 8.7. Conclusion -- ch. 9. Sensor arrays and networks. 9.1. Potential of sensor arrays. 9.2. Node design. 9.3. An architectural history of sensor arrays and networks. 9.4. Systems design issues. 9.5. Network technology and topology. 9.6. Conclusion -- ch. 10. Wireless and Ad hoc sensor networks. 10.1. Sensor network applications. 10.2. System designers' role. 10.3. Design assumptions for Ad hoc networks. 10.4. Distributed system design philosophy. 10.5. Network design considerations. 10.6. Layered model. 10.7. Sensor network operating environments. 10.8. Application services. 10.9. Proposed sensor support system architecture. 10.10. Conclusions -- ch. 11. Realising the dream - a case study. 11.1. Introduction. 11.2. The mission. 11.3. Initial rough design. 11.4. Sensor technology. 11.5. Deployment. 11.6. Operation, control and communication. 11.7. Querying the array. 11.8. A cogent sensor. 11.9. A world of applications.
330   $aMEMS have revolutionized the semiconductor industry, with sensors being a particularly buoyant sector. This book presents readers with the means to understand, evaluate, appreciate and participate in the development of the field, from a systems perspective.
606   $aMicroelectromechanical systems
606   $aMicroelectromechanical systems
606   $aSmart structures
606   $aElectrical & Computer Engineering$2HILCC
606   $aEngineering & Applied Sciences$2HILCC
606   $aElectrical Engineering$2HILCC
608   $aElectronic books.$2lcsh
615  0$aMicroelectromechanical systems.
615  0$aMicroelectromechanical systems
615  0$aSmart structures
615  7$aElectrical & Computer Engineering
615  7$aEngineering & Applied Sciences
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701   $aNewman$b Robert$032189
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701   $aFlewitt$b Andrew$0917684
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200 10$aSurface vitrinite reflectance study of the Uinta and Piceance basins and adjacent areas, eastern Utah and western Colorado $eimplications for the development of Laramide basins and uplifts /$fby Ronald C. Johnson and Vito F. Nuccio
210  1$a[Reston, Va.] :$cU.S. Department of the Interior, U.S. Geological Survey,$d1993.
210  2$a[Washington, D.C.] :$cUnited States Government Printing Office.
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300   $aTitle from title screen (viewed Aug. 25, 2014).
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200 10$aFDTD Modeling of EM Field inside Microwave Cavities /$fby Shiv Narayan, K. M. Divya, V. Krushna Kanth
205   $a1st ed. 2017.
210  1$aSingapore :$cSpringer Singapore :$cImprint: Springer,$d2017.
215   $a1 online resource (XXV, 71 p. 99 illus., 95 illus. in color.) 
225 1 $aSpringerBriefs in Computational Electromagnetics,$x2365-6239
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320   $aIncludes bibliographical references and indexes.
327   $aIntroduction -- Finite Difference Time Domain Method -- Analysis of EM Field Distribution inside Microwave Oven -- Modeling of Curved Closed Cavity using FDTD -- Summary -- References -- Author Index -- Subject Index.
330   $aThis book deals with the EM analysis of closed microwave cavities based on a three-dimensional FDTD method. The EM analysis is carried out for (i) rectangular microwave ovens and (ii) hybrid-cylindrical microwave autoclaves at 2.45 GHz. The field distribution is first estimated inside domestic rectangular ovens in xy-, yz-, and zx-plane. Further, the RF leakage from the oven door is determined to study the effect of leakage radiation on wireless communication at 2.45 GHz. Furthermore, the EM analysis of the autoclave is carried out based on 3D FDTD using staircase approximation. In order to show the capability of autoclaves (excited with five source) for curing the aerospace components and materials, the field distribution inside autoclave cavity is studied in presence of aerospace samples. The FDTD based modelling of oven and autoclave are explained with the appropriate expressions and illustrations.
410  0$aSpringerBriefs in Computational Electromagnetics,$x2365-6239
606   $aMicrowaves
606   $aOptical engineering
606   $aElectrical engineering
606   $aLasers
606   $aPhotonics
606   $aMicrowaves, RF and Optical Engineering$3https://scigraph.springernature.com/ontologies/product-market-codes/T24019
606   $aCommunications Engineering, Networks$3https://scigraph.springernature.com/ontologies/product-market-codes/T24035
606   $aOptics, Lasers, Photonics, Optical Devices$3https://scigraph.springernature.com/ontologies/product-market-codes/P31030
615  0$aMicrowaves.
615  0$aOptical engineering.
615  0$aElectrical engineering.
615  0$aLasers.
615  0$aPhotonics.
615 14$aMicrowaves, RF and Optical Engineering.
615 24$aCommunications Engineering, Networks.
615 24$aOptics, Lasers, Photonics, Optical Devices.
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