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Coatings. --- Gas pressure. --- Pressure sensors. --- Signal detectors. --- Sound waves. --- Surface acoustic wave devices. --- Transducers. --- Coatings. --- Pressure transducers. --- Sound-waves. --- Acoustic surface wave devices. --- Transducers.
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Surface acoustic wave (SAW) devices are recognized for their versatility and efficiency in controlling and processing electrical signals. This has resulted in a multitude of device concepts for a wide range of signal processing functions, such as delay lines, filters, resonators, pulse compressors, convolvers, and many more. As SAW technology has found its way into mass market products such as TV receivers, pagers, keyless entry systems and cellular phones, the production volume has risen to millions of devices produced every day. At the other end of the scale, there are specialized high performance signal processing SAW devices for satellite communication and military applications, such as radar and electronic warfare.This volume, together with Volume 2, presents an overview of recent advances in SAW technology, systems and applications by some of the foremost researchers in this exciting field.
Acoustic surface wave devices. --- Acoustic surface waves. --- Waves, Acoustic surface --- Waves, Elastic surface --- Elastic waves --- Sound-waves --- Surface waves (Oceanography) --- Surface acoustic wave devices --- Surface wave devices, Acoustic --- Acoustic surface waves --- Electro-acoustics --- Piezoelectric devices
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621.38 --- Electronic devices. Electron tubes. Photocells. Particle accelerators. X-ray tubes --- Acoustic surface wave devices. --- Transducers, Interdigital. --- 621.38 Electronic devices. Electron tubes. Photocells. Particle accelerators. X-ray tubes --- Acoustic surface wave devices --- Transducers, Interdigital --- Interdigital transducers --- Surface acoustic wave devices --- Surface wave devices, Acoustic --- Acoustic surface waves --- Electro-acoustics --- Piezoelectric devices
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This timely book presents a thorough overview of RF BAW filters, covering a vast range of technologies, optimal device design, filter topologies, packaging, fabrication processes, and high quality piezoelectric thin films. Moreover, the book discusses the integration of BAW filters in RF systems.
Acoustic surface wave devices. --- Telecommunication --- Surface acoustic wave devices --- Surface wave devices, Acoustic --- Acoustic surface waves --- Electro-acoustics --- Piezoelectric devices --- Equipment and supplies. --- Apparatus and supplies --- Acoustic bulk wave devices --- Telecommunications --- Electric communication --- Mass communication --- Telecom --- Telecommunication industry --- Communication --- Information theory --- Telecommuting --- Equipment and supplies --- Acoustic bulk wave devices.
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The field of solid-state chemical sensor design is a research field of increasing interest as a result of the demands for reliable, inexpensive, and portable systems for environmental monitoring, assessing indoor air quality, food quality control, military, and many other applications. Solid-state chemical sensors, because they can be microfabricated using modern technologies of mass production, may be able to realize those requirements in practice. Solid-state sensor technology has advanced remarkably during the past few decades and is rapidly becoming an essential technology. As a result, many solid-state chemical sensors are now commercially available, and researchers are working to develop next-generation solidstate sensors that have all the necessary requirements, including small size, low production costs, and low power consumption.
Chemical detectors. --- Solid state chemistry. --- Chemistry, Solid state --- Chemistry, Physical and theoretical --- Chemical sensors --- Chemical apparatus --- Detectors --- calorimetric sensors --- capacitance sensors --- chemical sensors --- conductometric sensors --- FET sensors --- gas sensors --- integrated chemical sensors --- metal oxide sensors --- microcantilevers --- pyroelectric sensors --- quartz crystal microbalance --- Schottky sensors --- solid-state sensors --- surface acoustic wave sensors --- thermoelectric sensors --- work-function sensors
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In the field of magnetic sensing, a wide variety of different magnetometer and gradiometer sensor types, as well as the corresponding read-out concepts, are available. Well-established sensor concepts such as Hall sensors and magnetoresistive sensors based on giant magnetoresistances (and many more) have been researched for decades. The development of these types of sensors has reached maturity in many aspects (e.g., performance metrics, reliability, and physical understanding), and these types of sensors are established in a large variety of industrial applications. Magnetic sensors based on the magnetoelectric effect are a relatively new type of magnetic sensor. The potential of magnetoelectric sensors has not yet been fully investigated. Especially in biomedical applications, magnetoelectric sensors show several advantages compared to other concepts for their ability, for example, to operate in magnetically unshielded environments and the absence of required cooling or heating systems. In recent years, research has focused on understanding the different aspects influencing the performance of magnetoelectric sensors. At Kiel University, Germany, the Collaborative Research Center 1261 “Magnetoelectric Sensors: From Composite Materials to Biomagnetic Diagnostics”, funded by the German Research Foundation, has dedicated its work to establishing a fundamental understanding of magnetoelectric sensors and their performance parameters, pushing the performance of magnetoelectric sensors to the limits and establishing full magnetoelectric sensor systems in biological and clinical practice.
delta-E effect --- magnetoelectric --- magnetoelastic --- resonator --- torsion mode --- bending mode --- magnetic modeling --- MEMS --- FEM --- magnetoelectric sensor --- SQUID --- MEG --- deep brain stimulation (DBS) --- directional DBS electrode --- magnetic field measurement --- electrode localization --- rotational orientation detection --- Barkhausen noise --- delay line sensor --- Flicker noise --- Kerr microscopy --- magnetic domain networks --- magnetic field sensor --- magnetic noise --- magnetoelastic delta-E effect --- phase noise --- surface acoustic wave --- localization --- magnetoelectric sensors --- real time --- pose estimation --- magnetoactive elastomer --- piezoelectric polymer --- laminated structure --- cantilever --- direct magnetoelectric effect --- public understanding/outreach --- ME sensors --- medical sensing --- biomagnetic sensing --- interdisciplinary/multidisciplinary --- magnetometer --- sensor array --- exchange bias --- motion tracking --- artificial fields --- surface acoustic waves --- surface acoustic wave sensor --- current sensor --- magnetostriction --- AlScN --- FeCoSiB --- thin film --- magnetron sputter deposition --- ERDA --- XRD --- film stress --- magnetic properties --- magnetic domains --- SAW --- magnetic nanoparticle --- imaging --- inverse problem --- blind deconvolution --- application specific signal evaluation --- quantitative sensor system characterization --- sensor system performance
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Written by an interdisciplinary group of experts from both industry and academia, Acoustic Wave Sensors provides an in-depth look at the current state of acoustic wave devices and the scope of their use in chemical, biochemical, and physical measurements, as well as in engineering applications. Because of the inherent interdisciplinary applications of these devices, this book will be useful for the chemist and biochemist interested in the use and development of these sensors for specific applications; the electrical engineer involved in the design and improvement of these devices; the ch
Biosensors --- Chemical detectors --- Detectors --- Biocapteurs --- Détecteurs de produits chimiques --- Détecteurs --- Acoustic surface wave devices. --- Detectors. --- Sensors --- Engineering instruments --- Physical instruments --- Chemical sensors --- Chemical apparatus --- Biodetectors --- Biological detectors --- Biological sensors --- Biomedical detectors --- Biomedical sensors --- Medical instruments and apparatus --- Physiological apparatus --- Surface acoustic wave devices --- Surface wave devices, Acoustic --- Acoustic surface waves --- Electro-acoustics --- Piezoelectric devices --- Détecteurs de produits chimiques --- Détecteurs --- ELSEVIER-B EPUB-LIV-FT --- Acoustic surface wave devices --- Engineering --- Electronics --- Chemical detectors. --- Biosensors.
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In the field of magnetic sensing, a wide variety of different magnetometer and gradiometer sensor types, as well as the corresponding read-out concepts, are available. Well-established sensor concepts such as Hall sensors and magnetoresistive sensors based on giant magnetoresistances (and many more) have been researched for decades. The development of these types of sensors has reached maturity in many aspects (e.g., performance metrics, reliability, and physical understanding), and these types of sensors are established in a large variety of industrial applications. Magnetic sensors based on the magnetoelectric effect are a relatively new type of magnetic sensor. The potential of magnetoelectric sensors has not yet been fully investigated. Especially in biomedical applications, magnetoelectric sensors show several advantages compared to other concepts for their ability, for example, to operate in magnetically unshielded environments and the absence of required cooling or heating systems. In recent years, research has focused on understanding the different aspects influencing the performance of magnetoelectric sensors. At Kiel University, Germany, the Collaborative Research Center 1261 “Magnetoelectric Sensors: From Composite Materials to Biomagnetic Diagnostics”, funded by the German Research Foundation, has dedicated its work to establishing a fundamental understanding of magnetoelectric sensors and their performance parameters, pushing the performance of magnetoelectric sensors to the limits and establishing full magnetoelectric sensor systems in biological and clinical practice.
Research & information: general --- Physics --- Electricity, electromagnetism & magnetism --- delta-E effect --- magnetoelectric --- magnetoelastic --- resonator --- torsion mode --- bending mode --- magnetic modeling --- MEMS --- FEM --- magnetoelectric sensor --- SQUID --- MEG --- deep brain stimulation (DBS) --- directional DBS electrode --- magnetic field measurement --- electrode localization --- rotational orientation detection --- Barkhausen noise --- delay line sensor --- Flicker noise --- Kerr microscopy --- magnetic domain networks --- magnetic field sensor --- magnetic noise --- magnetoelastic delta-E effect --- phase noise --- surface acoustic wave --- localization --- magnetoelectric sensors --- real time --- pose estimation --- magnetoactive elastomer --- piezoelectric polymer --- laminated structure --- cantilever --- direct magnetoelectric effect --- public understanding/outreach --- ME sensors --- medical sensing --- biomagnetic sensing --- interdisciplinary/multidisciplinary --- magnetometer --- sensor array --- exchange bias --- motion tracking --- artificial fields --- surface acoustic waves --- surface acoustic wave sensor --- current sensor --- magnetostriction --- AlScN --- FeCoSiB --- thin film --- magnetron sputter deposition --- ERDA --- XRD --- film stress --- magnetic properties --- magnetic domains --- SAW --- magnetic nanoparticle --- imaging --- inverse problem --- blind deconvolution --- application specific signal evaluation --- quantitative sensor system characterization --- sensor system performance --- delta-E effect --- magnetoelectric --- magnetoelastic --- resonator --- torsion mode --- bending mode --- magnetic modeling --- MEMS --- FEM --- magnetoelectric sensor --- SQUID --- MEG --- deep brain stimulation (DBS) --- directional DBS electrode --- magnetic field measurement --- electrode localization --- rotational orientation detection --- Barkhausen noise --- delay line sensor --- Flicker noise --- Kerr microscopy --- magnetic domain networks --- magnetic field sensor --- magnetic noise --- magnetoelastic delta-E effect --- phase noise --- surface acoustic wave --- localization --- magnetoelectric sensors --- real time --- pose estimation --- magnetoactive elastomer --- piezoelectric polymer --- laminated structure --- cantilever --- direct magnetoelectric effect --- public understanding/outreach --- ME sensors --- medical sensing --- biomagnetic sensing --- interdisciplinary/multidisciplinary --- magnetometer --- sensor array --- exchange bias --- motion tracking --- artificial fields --- surface acoustic waves --- surface acoustic wave sensor --- current sensor --- magnetostriction --- AlScN --- FeCoSiB --- thin film --- magnetron sputter deposition --- ERDA --- XRD --- film stress --- magnetic properties --- magnetic domains --- SAW --- magnetic nanoparticle --- imaging --- inverse problem --- blind deconvolution --- application specific signal evaluation --- quantitative sensor system characterization --- sensor system performance
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Bionanoparticles such as microorganisms and exosomes are recognized as important targets for clinical applications, food safety, and environmental monitoring. Other nanoscale biological particles, including liposomes, micelles, and functionalized polymeric particles are widely used in nanomedicines. The recent development of microfluidic and nanofluidic technologies has enabled the separation and analysis of these species in a lab-on-a-chip platform, while there are still many challenges to address before these analytical tools can be adopted in practice. For example, the complex matrices within which these species reside in create a high background for their detection. Their small dimension and often low concentration demand creative strategies to amplify the sensing signal and enhance the detection speed. This Special Issue aims to recruit recent discoveries and developments of micro- and nanofluidic strategies for the processing and analysis of biological nanoparticles. The collection of papers will hopefully bring out more innovative ideas and fundamental insights to overcome the hurdles faced in the separation and detection of bionanoparticles.
n/a --- magnetic field --- microfluidic device --- ballpoint pen printing --- paper-based microfluidic device --- online analysis --- nanoporous membrane --- dielectric film --- digital microfluidic chip --- HIV diagnostics --- precipitation --- optically induced dielectrophoresis (ODEP) --- digital microfluidic device --- fluorescence --- ferrofluids --- cancer metastasis --- flow focusing --- image processing --- electrowetting --- light diffraction --- lensfree --- nanoparticle characterization --- multi-step assay --- cell isolation --- biomarker detection --- microparticles --- conductive electrode --- single particle analysis --- plastic wrap --- second-hand smoke --- flow control --- surface acoustic wave --- droplet actuation --- circulating tumour cells (CTCs) --- lipid nanoparticles --- crop disease --- cross-flow filtration --- oxidized hollow mesoporous carbon nanosphere --- microfluidic systems --- 3-ethenylpyridine --- microfluidic --- microfluidics --- COMSOL --- plug flow mixer
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