passive uhf rfid antennas for sensing applications

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UHF passive radio-frequency identification technology is rapidly evolving from simple labeling .This paper presents a passive radio frequency identification sensor transponder (tag) antenna .

UHF passive radio-frequency identification technology is rapidly evolving from simple labeling of things to wireless pervasive sensing. A remarkable number of scientific papers demonstrate that objects in principle can have their physical properties .This paper presents a passive radio frequency identification sensor transponder (tag) antenna concept that is based on the detection of defined tag signal patterns at the RFID reader that can be made independent of the reader/tag distance. Expand.In order to enable such vision, passive UHF RFID technology can play a strategic role, thanks to its low-cost, wireless and “sensing-friendly” capabilities. The use of an antenna as part of a passive sensor is not new and occurred much before the appearance of RFID microchips. In this research article, a printed dual‐polarized metasurface (MTS) inspired printed monopole antenna using characteristics modes theory (CMT) is investigated for UHF RFID applications.

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Passive UHF RFID Antennas for Sensing Applications: Principles, Methods, and Classifi cations. C. Occhiuzzi, S. Caizzone, and G. Marrocco.The present work tries to systematize the different applications of UHF RFID antennas for passive sensors, to clarify the relationships and constraints for communication and sensing, and to introduce performance parameters for gen eral application.Therefore, this chapter aims to provide an overview of sensing parameters, techniques, state-of-the-art passive UHF RFID sensors design IoT-based solutions, their applications in daily life environments, commercial tag solutions, and use of machine learning algorithms to improve sensor data accuracy. The key background is a new paradigm of antenna design that merges together the conventional communication issues with more-specific requirements about sensitivity to time-varying boundary conditions. This paper presents a unified review of the state of the art of the tag-as-sensor problem.

The platform consists of a passive UHF RFID tag and a base station. The tag has an inductively-fed, meandered dipole antenna that is impedance matched to a CMOS IC that contains the remote powering, power management, and communication circuits to operate with sensor interfaces.applications. In this paper, we propose the design of a passive RFID yarn including the temperature sensing functionality. The proposed structure of the sensor tag uses a thermistor as sensitive element and exploits the impedance mismatching between the antenna and the chip to translate the temperature variation.

UHF passive radio-frequency identification technology is rapidly evolving from simple labeling of things to wireless pervasive sensing. A remarkable number of scientific papers demonstrate that objects in principle can have their physical properties .This paper presents a passive radio frequency identification sensor transponder (tag) antenna concept that is based on the detection of defined tag signal patterns at the RFID reader that can be made independent of the reader/tag distance. Expand.In order to enable such vision, passive UHF RFID technology can play a strategic role, thanks to its low-cost, wireless and “sensing-friendly” capabilities. The use of an antenna as part of a passive sensor is not new and occurred much before the appearance of RFID microchips. In this research article, a printed dual‐polarized metasurface (MTS) inspired printed monopole antenna using characteristics modes theory (CMT) is investigated for UHF RFID applications.

Passive UHF RFID Antennas for Sensing Applications: Principles, Methods, and Classifi cations. C. Occhiuzzi, S. Caizzone, and G. Marrocco.The present work tries to systematize the different applications of UHF RFID antennas for passive sensors, to clarify the relationships and constraints for communication and sensing, and to introduce performance parameters for gen eral application.

Therefore, this chapter aims to provide an overview of sensing parameters, techniques, state-of-the-art passive UHF RFID sensors design IoT-based solutions, their applications in daily life environments, commercial tag solutions, and use of machine learning algorithms to improve sensor data accuracy.

The key background is a new paradigm of antenna design that merges together the conventional communication issues with more-specific requirements about sensitivity to time-varying boundary conditions. This paper presents a unified review of the state of the art of the tag-as-sensor problem. The platform consists of a passive UHF RFID tag and a base station. The tag has an inductively-fed, meandered dipole antenna that is impedance matched to a CMOS IC that contains the remote powering, power management, and communication circuits to operate with sensor interfaces.

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Passive UHF RFID antennas for sensing applications: Principles,

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passive uhf rfid antennas for sensing applications|Passive UHF RFID antennas for sensing applications: Principles,

passive uhf rfid antennas for sensing applications|Passive UHF RFID antennas for sensing applications: Principles, .

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