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Electrical and electro-optical biosensing technologies are critical to the development of innovative POCT devices, which can be used by both professional and untrained personnel for the provision of necessary health information within a short time for medical decisions to be determined, being especially important in an era of global pandemics. This Special Issue includes a few pioneering works concerning biosensors utilizing electrochemical impedance, localized surface plasmon resonance, and the bioelectricity of sensing materials in which the amount of analyte is pertinent to the signal response. The presented results demonstrate the potential of these label-free biosensing approaches in the detection of disease-related small-molecule metabolites, proteins, and whole-cell entities.

printed circuit board --- sensor electrode --- electrochemical sensor --- printed biosensors --- printing technologies --- electrochemistry --- point-of-care --- ovarian cancer --- nanowire biosensor --- nanowire --- silicon-on-insulator --- CA 125 --- antibodies --- liquid crystal --- photopolymer --- UV exposure --- bovine serum albumin --- protein assay --- dielectric spectroscopy --- lyotropic chromonic liquid crystal --- label-free biosensor --- optical biosensor --- immunoassay --- transmission spectrometry --- spoof localized surface plasmon polariton --- sensor --- glucose solution --- millimeter wave --- metamaterial --- spin-coating --- single-substrate --- cancer biomarker CA125 --- dengue virus --- dengue serotype --- mosquito-borne viral disease --- virus detection --- electrochemical impedance spectroscopy --- cancer cells --- dielectrophoresis --- crossover frequency --- electrical impedance spectroscopy --- n/a

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The development of micro- and nanodevices for blood analysis continues to be a growing interdisciplinary subject that demands the careful integration of different research fields. Following the success of the book “Micro/Nano Devices for Blood Analysis”, we invited more authors from the scientific community to participate in and submit their research for a second volume. Researchers from different areas and backgrounds cooperated actively and submitted high-quality research, focusing on the latest advances and challenges in micro- and nanodevices for diagnostics and blood analysis; micro- and nanofluidics; technologies for flow visualization and diagnosis; biochips, organ-on-a-chip and lab-on-a-chip devices; and their applications to research and industry.

Information technology industries --- blood viscosity --- Erythrocyte sedimentation rate (ESR) --- T-shaped microfluidic channel --- air-compressed syringe (ACS) --- micro-particle image velocimetry --- viscoelasticity --- microfluidic device --- coflowing streams --- interface --- linear differential equation --- two approximate factors --- dielectrophoresis --- electrophysiological properties --- crossover frequency --- wake or recirculation formation --- dielectric spectra --- air compliance effect --- RBC aggregation --- blood viscoelasticity --- blood velocity fields --- interface in co-flowing streams --- blood flow --- particle tracking --- red blood cells --- manual methods --- automatic methods --- image analysis --- biomicrofluidics --- microfluidics --- blood plasma filtration --- chip extract --- blood molecules --- patient-derived organoids --- colorectal cancer --- 3D model --- drug screening --- diagnostics --- malaria --- optical filters --- reflectance --- spectrophotometry --- TFCalc --- small caliber blood vessel --- composite molding --- micro-nano structure --- tissue repair --- 3D printing --- blood cells --- fourier transform infrared (FTIR) spectroscopy --- functional group --- lab-on-a-chip --- blood viscosity --- Erythrocyte sedimentation rate (ESR) --- T-shaped microfluidic channel --- air-compressed syringe (ACS) --- micro-particle image velocimetry --- viscoelasticity --- microfluidic device --- coflowing streams --- interface --- linear differential equation --- two approximate factors --- dielectrophoresis --- electrophysiological properties --- crossover frequency --- wake or recirculation formation --- dielectric spectra --- air compliance effect --- RBC aggregation --- blood viscoelasticity --- blood velocity fields --- interface in co-flowing streams --- blood flow --- particle tracking --- red blood cells --- manual methods --- automatic methods --- image analysis --- biomicrofluidics --- microfluidics --- blood plasma filtration --- chip extract --- blood molecules --- patient-derived organoids --- colorectal cancer --- 3D model --- drug screening --- diagnostics --- malaria --- optical filters --- reflectance --- spectrophotometry --- TFCalc --- small caliber blood vessel --- composite molding --- micro-nano structure --- tissue repair --- 3D printing --- blood cells --- fourier transform infrared (FTIR) spectroscopy --- functional group --- lab-on-a-chip

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In this book, 20 papers focused on different fields of power electronics are gathered. Approximately half of the papers are focused on different control issues and techniques, ranging from the computer-aided design of digital compensators to more specific approaches such as fuzzy or sliding control techniques. The rest of the papers are focused on the design of novel topologies. The fields in which these controls and topologies are applied are varied: MMCs, photovoltaic systems, supercapacitors and traction systems, LEDs, wireless power transfer, etc.

Technology: general issues --- vehicle-grid coupling system --- low frequency oscillation --- traction line-side converter (LSC) --- model-based predictive current control (MBPCC) --- dSPACE semi-physical verification --- switching converters --- sliding-mode control --- current-mode control --- hysteresis control --- PV-connected inverter --- MPPT --- SPPT --- adaptive hysteresis current control --- hybrid storage systems --- power electronic converters --- half-bridge current-source converters --- supercapacitors --- cascaded H-bridge (CHB) --- dc-link voltage balance control --- multilevel converter --- power control --- single-phase system --- pulsating output current --- light emitting diode (LED) --- peak to average ratio (PTAR) --- power factor correction --- harmonic injection --- modelling --- feedback loop control --- three-port converter --- linear active disturbance rejection control --- virtual damping --- linear extended state observer --- power converters --- digital control --- design space --- frequency domain --- switched affine systems --- hybrid systems --- fuzzy identification --- fuzzy modeling --- two degrees of freedom --- fuzzy model predictive control --- PLC --- bus converter --- DC bus --- LED driver --- buck converter --- inversion formulae --- phase margin --- gain crossover frequency --- wireless power transfer --- inductive power transfer --- Pareto optimality --- coil design --- magnetics design --- GaN-based inverter and converter --- zeta inverter --- active clamp --- synchronous rectification --- power efficiency --- circulating current --- fuzzy --- proportional integral --- proportional resonant --- MMC --- DC–DC converter --- experimental verification --- Inductor–Diode --- Inductor–Capacitor–Diode --- nonisolated --- step-down --- two-stage buck converter --- voltage regulation --- power electronic converter --- AC/AC converter --- matrix converter --- reliability --- DPWM --- photovoltaic power system --- differential flatness --- nonlinear control --- networked power converters --- PFC converters --- reactive power resources --- supervisory controller --- HIL Testbed --- binary particle swarm optimization (BPSO) --- nonsingular terminal sliding mode control (NTSMC) --- global best solution --- total harmonic distortion (THD) --- DC–AC converter --- decoupling --- reduced order generalized integrator (ROGI) --- optimal gain --- distributed power generation system (DPGS) --- grid-connected voltage source converters (GC-VSCs) --- vehicle-grid coupling system --- low frequency oscillation --- traction line-side converter (LSC) --- model-based predictive current control (MBPCC) --- dSPACE semi-physical verification --- switching converters --- sliding-mode control --- current-mode control --- hysteresis control --- PV-connected inverter --- MPPT --- SPPT --- adaptive hysteresis current control --- hybrid storage systems --- power electronic converters --- half-bridge current-source converters --- supercapacitors --- cascaded H-bridge (CHB) --- dc-link voltage balance control --- multilevel converter --- power control --- single-phase system --- pulsating output current --- light emitting diode (LED) --- peak to average ratio (PTAR) --- power factor correction --- harmonic injection --- modelling --- feedback loop control --- three-port converter --- linear active disturbance rejection control --- virtual damping --- linear extended state observer --- power converters --- digital control --- design space --- frequency domain --- switched affine systems --- hybrid systems --- fuzzy identification --- fuzzy modeling --- two degrees of freedom --- fuzzy model predictive control --- PLC --- bus converter --- DC bus --- LED driver --- buck converter --- inversion formulae --- phase margin --- gain crossover frequency --- wireless power transfer --- inductive power transfer --- Pareto optimality --- coil design --- magnetics design --- GaN-based inverter and converter --- zeta inverter --- active clamp --- synchronous rectification --- power efficiency --- circulating current --- fuzzy --- proportional integral --- proportional resonant --- MMC --- DC–DC converter --- experimental verification --- Inductor–Diode --- Inductor–Capacitor–Diode --- nonisolated --- step-down --- two-stage buck converter --- voltage regulation --- power electronic converter --- AC/AC converter --- matrix converter --- reliability --- DPWM --- photovoltaic power system --- differential flatness --- nonlinear control --- networked power converters --- PFC converters --- reactive power resources --- supervisory controller --- HIL Testbed --- binary particle swarm optimization (BPSO) --- nonsingular terminal sliding mode control (NTSMC) --- global best solution --- total harmonic distortion (THD) --- DC–AC converter --- decoupling --- reduced order generalized integrator (ROGI) --- optimal gain --- distributed power generation system (DPGS) --- grid-connected voltage source converters (GC-VSCs)

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• Reference Manager
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In this book, 20 papers focused on different fields of power electronics are gathered. Approximately half of the papers are focused on different control issues and techniques, ranging from the computer-aided design of digital compensators to more specific approaches such as fuzzy or sliding control techniques. The rest of the papers are focused on the design of novel topologies. The fields in which these controls and topologies are applied are varied: MMCs, photovoltaic systems, supercapacitors and traction systems, LEDs, wireless power transfer, etc.

vehicle-grid coupling system --- low frequency oscillation --- traction line-side converter (LSC) --- model-based predictive current control (MBPCC) --- dSPACE semi-physical verification --- switching converters --- sliding-mode control --- current-mode control --- hysteresis control --- PV-connected inverter --- MPPT --- SPPT --- adaptive hysteresis current control --- hybrid storage systems --- power electronic converters --- half-bridge current-source converters --- supercapacitors --- cascaded H-bridge (CHB) --- dc-link voltage balance control --- multilevel converter --- power control --- single-phase system --- pulsating output current --- light emitting diode (LED) --- peak to average ratio (PTAR) --- power factor correction --- harmonic injection --- modelling --- feedback loop control --- three-port converter --- linear active disturbance rejection control --- virtual damping --- linear extended state observer --- power converters --- digital control --- design space --- frequency domain --- switched affine systems --- hybrid systems --- fuzzy identification --- fuzzy modeling --- two degrees of freedom --- fuzzy model predictive control --- PLC --- bus converter --- DC bus --- LED driver --- buck converter --- inversion formulae --- phase margin --- gain crossover frequency --- wireless power transfer --- inductive power transfer --- Pareto optimality --- coil design --- magnetics design --- GaN-based inverter and converter --- zeta inverter --- active clamp --- synchronous rectification --- power efficiency --- circulating current --- fuzzy --- proportional integral --- proportional resonant --- MMC --- DC–DC converter --- experimental verification --- Inductor–Diode --- Inductor–Capacitor–Diode --- nonisolated --- step-down --- two-stage buck converter --- voltage regulation --- power electronic converter --- AC/AC converter --- matrix converter --- reliability --- DPWM --- photovoltaic power system --- differential flatness --- nonlinear control --- networked power converters --- PFC converters --- reactive power resources --- supervisory controller --- HIL Testbed --- binary particle swarm optimization (BPSO) --- nonsingular terminal sliding mode control (NTSMC) --- global best solution --- total harmonic distortion (THD) --- DC–AC converter --- decoupling --- reduced order generalized integrator (ROGI) --- optimal gain --- distributed power generation system (DPGS) --- grid-connected voltage source converters (GC-VSCs)