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200 10$aConference Companion Publication of the 2019 on Computer Supported Cooperative Work and Social Computing /$fEric Gilbert
210  1$aNew York :$cAssociation for Computing Machinery,$d2019.
215   $a1 online resource (562 pages)
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330   $aWelcome to the 22nd ACM Conference on Computer-Supported Cooperative Work and Social Computing (CSCW). CSCW has always been an exciting, dynamic and welcoming research community, bridging between the social and the technological. If anything, it seems like the role of this community in society at large has become even more critical in recent years. We hope that our community is amongst the best-placed to understand the impact of technology on society, and design technologies that contribute in positive and meaningful ways. This year, we experimented with new ideas: such as adding Meta chairs, whose results you can hear Monday @ 2:30; and inviting the Diversity & Inclusion chairs into a consultancy role for the conference broadly. In addition, we made gender-neutral bathroom facilities a non-negotiable part of the hotel contract. As a result of your compelling and thought-provoking submissions, and the committee's dedicated efforts, the conference is full of exciting work: in addition to the high- quality papers, the conference features 7 novel demos, 6 panels, 16 workshops, a doctoral consortium and 63 engaging posters.
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200 10$aScaling issues and design of MEMS /$fSalvatore Baglio, Salvatore Castorina, Nicolo Savalli
210   $aChichester, West Sussex, England ;$aHoboken, NJ $cJohn Wiley & Sons$dc2007
215   $a1 online resource (245 p.)
300   $aDescription based upon print version of record.
311 08$a9780470016992 
311 08$a047001699X 
320   $aIncludes bibliographical references and index.
327   $aScaling Issues and Design of MEMS; Contents; Preface; Introduction; 1 Scaling of MEMS; 1.1 Introduction to Scaling Issues; 1.2 Examples of Dimensional Scaling Potentials; 1.2.1 Scaling effects on a cantilever beam; 1.2.2 Scaling of electrostatic actuators; 1.2.3 Scaling of thermal actuators; 1.3 Motivation, Fabrication and Scaling of MEMS; 1.4 Scaling as a Methodological Approach; References; 2 Scaling of Microactuators - an Overview; 2.1 Electrostatic Actuators; 2.1.1 Transverse combs modelling; 2.1.2 Lateral combs modelling; 2.2 Magnetic Transducers; 2.2.1 Magnetic actuators
327   $a2.2.2 Ferromagnetic transducers2.3 Thermal Actuators; 2.3.1 Thermomechanical actuators; Acknowledgements; References; 3 Scaling of Thermal Sensors; 3.1 Thermoelectric Sensors; 3.2 Application: Dew-Point Relative Humidity Sensors; 3.2.1 Device structures and operating principles; 3.2.2 Device modelling and simulations; 3.2.3 Device design; 3.3 Conclusions; Acknowledgements; References; 4 Inductive Sensors for Magnetic Fields; 4.1 Inductive Microsensors for Magnetic Particles; 4.1.1 Integrated inductive sensors; 4.1.2 Planar differential transformer; 4.1.3 Signal-conditioning circuits
327   $a4.1.4 Simulation of the planar differential transformer4.1.5 Experimental results; 4.2 Magnetic Immunoassay Systems; Acknowledgements; References; 5 Scaling of Mechanical Sensors; 5.1 Introduction; 5.2 Device Modelling and Fabrication Processes; 5.2.1 Fabrication processes; 5.2.2 Devices modelling; 5.2.3 Accelerometers; 5.2.4 Resonant mass sensors; 5.3 Experimental Device Prototypes; 5.3.1 CMOS devices; 5.3.2 SOI devices; 5.3.3 Finite element modelling; 5.4 Scaling Issues on Microaccelerometers and Mass Sensors; 5.5 Some Experimental Results; 5.6 Vibrating Microgyroscopes
327   $a5.6.1 Coupled vibratory gyroscopesAcknowledgements; References; 6 Scaling of Energy Sources; 6.1 Introduction; 6.2 Energy Supply Strategies for Autonomous Microsystems; 6.2.1 Use of microlenses in photothermomechanical actuation; 6.2.2 Technologies, materials and design of photothermomechanical actuators; 6.3 Photothermomechanical and Photothermoelectric Strategies for Highly Efficient Power Supply of Autonomous Microsystems; 6.3.1 Photothermoelectric power generation; 6.4 Efficiency of the Combined Energy Supply Strategy; References
327   $a7 Technologies and Architectures for Autonomous MEMS Microrobots7.1 Design Issues in Microrobots; 7.2 A Microrobot Architecture Based on Photothermal Strategy; 7.3 A Microrobot as a Paradigm for the Analysis of Scaling in Microsystems; References; 8 Moving towards the Nanoscale; 8.1 Semiconductor-Based Nano-Electromechanical Systems; 8.2 Nanofabrication Facilities; 8.3 Overview of Nanosensors; 8.3.1 Use of AFM for materials and nanodevices characterization; 8.3.2 Scanning thermal microscopy (SThM); 8.3.3 Scanning Hall probe microscopy
327   $a8.3.4 Mechanical resonant immunospecific biological detector
330   $aThis accessible volume delivers a complete design methodology for microelectromechanical systems (MEMS). Focusing on the scaling of an autonomous micro-system, it explains the real-world problems and theoretical concepts of several different aspects inherent to the miniaturization of sensors and actuators. It reports on the analysis of dimensional scaling, the modelling, design and experimental characterization of a wide range of specific devices and applications, including: temperature microsensors based on an integrated complementary metal-oxide-semiconductor (CMOS) t
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606   $aMicroelectromechanical systems$xDesign and construction
615  0$aMicroelectromechanical systems$xDesign and construction.
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