passive rfid strain-sensor based on meander-line antennas It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are engineered to achieve the desired sensing resolution and dynamic range.
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0 · Passive RFID Strain
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It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section .It is here shown how to design a completely passive UHF RFID sensor for strain .This question is for testing whether you are a human visitor and to prevent .
This question is for testing whether you are a human visitor and to prevent .It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are . It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are engineered to achieve the desired sensing resolution and dynamic range.It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are engineered to achieve the desired sensing resolu-tion and dynamic range.
Key takeaway: 'This passive UHF RFID sensor, based on a flexible meander-line dipole, offers sub-millimeter resolution and low-cost potential for structural health monitoring in damaged structures and vehicles.'
Passive RFID Strain
This paper has presented an overview of the progress made in the applications of passive antenna sensors and systems based on RFID technology, particularly for defect detection in metals for SHM. The related issues have been summarized into four main categories: defect type, antenna sensor, measurement strategy, and feature extraction.It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are engineered to achieve the desired sensing resolution and dynamic range. In this investigation, we propose, model, analyze, and test an enhanced wireless and passive RFID strain sensor that offers improved sensitivity to strains and quantifiable measurements in orthogonal directions.This research investigates a passive wireless antenna sensor designed for strain and crack sensing. When the antenna experiences deformation, the antenna shape changes, causing a shift in the electromagnetic resonance frequency of the antenna. A radio frequency identification (RFID) chip is adopted for antenna signal
Article "Passive RFID Strain-Sensor Based on Meander-Line Antennas" Detailed information of the J-GLOBAL is an information service managed by the Japan Science and Technology Agency (hereinafter referred to as "JST").
In this paper, a demonstration of a passive RFID sensor system for bridging the gap between NDT&E and SHM is conducted. The recent development of RFID antenna based defect sensors are reviewed and major considerations in RFID sensor systems are pointed out. It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are.
It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are engineered to achieve the desired sensing resolution and dynamic range.
It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are engineered to achieve the desired sensing resolu-tion and dynamic range.Key takeaway: 'This passive UHF RFID sensor, based on a flexible meander-line dipole, offers sub-millimeter resolution and low-cost potential for structural health monitoring in damaged structures and vehicles.'
This paper has presented an overview of the progress made in the applications of passive antenna sensors and systems based on RFID technology, particularly for defect detection in metals for SHM. The related issues have been summarized into four main categories: defect type, antenna sensor, measurement strategy, and feature extraction.It is here shown how to design a completely passive UHF RFID sensor for strain monitoring starting from a flexible meander-line dipole whose shape factor and feed section are engineered to achieve the desired sensing resolution and dynamic range. In this investigation, we propose, model, analyze, and test an enhanced wireless and passive RFID strain sensor that offers improved sensitivity to strains and quantifiable measurements in orthogonal directions.
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This research investigates a passive wireless antenna sensor designed for strain and crack sensing. When the antenna experiences deformation, the antenna shape changes, causing a shift in the electromagnetic resonance frequency of the antenna. A radio frequency identification (RFID) chip is adopted for antenna signalArticle "Passive RFID Strain-Sensor Based on Meander-Line Antennas" Detailed information of the J-GLOBAL is an information service managed by the Japan Science and Technology Agency (hereinafter referred to as "JST").
In this paper, a demonstration of a passive RFID sensor system for bridging the gap between NDT&E and SHM is conducted. The recent development of RFID antenna based defect sensors are reviewed and major considerations in RFID sensor systems are pointed out.
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passive rfid strain-sensor based on meander-line antennas|Passive RFID Strain