Dielectric Wireless Passive Temperature Sensor

Dielectric Wireless Passive Temperature Sensor

Resonators are passive components that respond to an excitation signal by oscillating at their natural frequency with an exponentially decreasing amplitude. When combined with antennas, resonators enable purely passive chipless sensors that can be read wirelessly. In this contribution, we investigat...

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Bibliographic Details
Main Authors: Taimur Aftab, Shah Hussain, Leonhard M. Reindl, Stefan Johann Rupitsch
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Journal of Sensor and Actuator Networks
Subjects:
dielectric resonator
wireless
passive
chip-less transponder
high temperature
small
Online Access:https://www.mdpi.com/2224-2708/14/3/60
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Summary:Resonators are passive components that respond to an excitation signal by oscillating at their natural frequency with an exponentially decreasing amplitude. When combined with antennas, resonators enable purely passive chipless sensors that can be read wirelessly. In this contribution, we investigate the properties of dielectric resonators, which combine the following functionalities: They store the readout signal for a sufficiently long time and couple to free space electromagnetic waves to act as antennas. Their mode spectrum, along with their resonant frequencies, quality factor, and coupling to electromagnetic waves, is investigated using a commercial finite element program. The fundamental mode exhibits a too-low overall <i>Q</i> factor. However, some higher modes feature overall <i>Q</i> factors of several thousand, which allows them to act as transponders operating without integrated circuits, batteries, or antennas. To experimentally verify the simulations, isolated dielectric resonators exhibiting modes with similarly high radiation-induced and dissipative quality factors were placed on a low-loss, low permittivity ceramic holder, allowing their far-field radiation properties to be measured. The radiation patterns investigated in the laboratory and outdoors agree well with the simulations. The resulting radiation patterns show a directivity of approximately 7.5 dBi at 2.5 GHz. The sensor was then heated in a ceramic furnace with the readout antenna located outside at room temperature. Wireless temperature measurements up to 700 °C with a resolution of 0.5 °C from a distance of 1 m demonstrated the performance of dielectric resonators for practical applications.
ISSN:2224-2708

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