Reader Architectures for Wireless Surface Acoustic Wave Sensors

Reader Architectures for Wireless Surface Acoustic Wave Sensors

Wireless surface acoustic wave (SAW) sensors have some unique features that make them promising for industrial metrology. Their decisive advantage lies in their purely passive operation and the wireless readout capability allowing the installation also at particularly inaccessible locations. Further...

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Bibliographic Details
Main Authors: Fabian Lurz, Thomas Ostertag, Benedict Scheiner, Robert Weigel, Alexander Koelpin
Format: Article
Language:English
Published: MDPI AG 2018-05-01
Series:Sensors
Subjects:
surface acoustic waves
transceiver architecture
temperature sensor
pressure sensor
torque sensor
wireless sensor
frequency measurement
Online Access:http://www.mdpi.com/1424-8220/18/6/1734
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spelling doaj-ac2fbca6111c4930bc67742d225d44022020-11-24T23:44:14ZengMDPI AGSensors1424-82202018-05-01186173410.3390/s18061734s18061734Reader Architectures for Wireless Surface Acoustic Wave SensorsFabian Lurz0Thomas Ostertag1Benedict Scheiner2Robert Weigel3Alexander Koelpin4Institute for Electronics Engineering, Friedrich-Alexander University Erlangen-Nuremberg (FAU), 91058 Erlangen, GermanyRSSI GmbH, Bürgermeister-Graf-Ring 1, 82538 Geretsried, GermanyInstitute for Electronics Engineering, Friedrich-Alexander University Erlangen-Nuremberg (FAU), 91058 Erlangen, GermanyInstitute for Electronics Engineering, Friedrich-Alexander University Erlangen-Nuremberg (FAU), 91058 Erlangen, GermanyDepartment of General Electrical Engineering and Measurement Technology, Brandenburg University of Technology, 03046 Cottbus, GermanyWireless surface acoustic wave (SAW) sensors have some unique features that make them promising for industrial metrology. Their decisive advantage lies in their purely passive operation and the wireless readout capability allowing the installation also at particularly inaccessible locations. Furthermore, they are small, low-cost and rugged components on highly stable substrate materials and thus particularly suited for harsh environments. Nevertheless, a sensor itself does not carry out any measurement but always requires a suitable excitation and interrogation circuit: a reader. A variety of different architectures have been presented and investigated up to now. This review paper gives a comprehensive survey of the present state of reader architectures such as time domain sampling (TDS), frequency domain sampling (FDS) and hybrid concepts for both SAW resonators and reflective SAW delay line sensors. Furthermore, critical performance parameters such as measurement accuracy, dynamic range, update rate, and hardware costs of the state of the art in science and industry are presented, compared and discussed.http://www.mdpi.com/1424-8220/18/6/1734surface acoustic wavestransceiver architecturetemperature sensorpressure sensortorque sensorwireless sensorfrequency measurement
collection DOAJ
language English
format Article
sources DOAJ
author Fabian Lurz
Thomas Ostertag
Benedict Scheiner
Robert Weigel
Alexander Koelpin
spellingShingle Fabian Lurz
Thomas Ostertag
Benedict Scheiner
Robert Weigel
Alexander Koelpin
Reader Architectures for Wireless Surface Acoustic Wave Sensors
Sensors
surface acoustic waves
transceiver architecture
temperature sensor
pressure sensor
torque sensor
wireless sensor
frequency measurement
author_facet Fabian Lurz
Thomas Ostertag
Benedict Scheiner
Robert Weigel
Alexander Koelpin
author_sort Fabian Lurz
title Reader Architectures for Wireless Surface Acoustic Wave Sensors
title_short Reader Architectures for Wireless Surface Acoustic Wave Sensors
title_full Reader Architectures for Wireless Surface Acoustic Wave Sensors
title_fullStr Reader Architectures for Wireless Surface Acoustic Wave Sensors
title_full_unstemmed Reader Architectures for Wireless Surface Acoustic Wave Sensors
title_sort reader architectures for wireless surface acoustic wave sensors
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2018-05-01
description Wireless surface acoustic wave (SAW) sensors have some unique features that make them promising for industrial metrology. Their decisive advantage lies in their purely passive operation and the wireless readout capability allowing the installation also at particularly inaccessible locations. Furthermore, they are small, low-cost and rugged components on highly stable substrate materials and thus particularly suited for harsh environments. Nevertheless, a sensor itself does not carry out any measurement but always requires a suitable excitation and interrogation circuit: a reader. A variety of different architectures have been presented and investigated up to now. This review paper gives a comprehensive survey of the present state of reader architectures such as time domain sampling (TDS), frequency domain sampling (FDS) and hybrid concepts for both SAW resonators and reflective SAW delay line sensors. Furthermore, critical performance parameters such as measurement accuracy, dynamic range, update rate, and hardware costs of the state of the art in science and industry are presented, compared and discussed.
topic surface acoustic waves
transceiver architecture
temperature sensor
pressure sensor
torque sensor
wireless sensor
frequency measurement
url http://www.mdpi.com/1424-8220/18/6/1734
work_keys_str_mv AT fabianlurz readerarchitecturesforwirelesssurfaceacousticwavesensors
AT thomasostertag readerarchitecturesforwirelesssurfaceacousticwavesensors
AT benedictscheiner readerarchitecturesforwirelesssurfaceacousticwavesensors
AT robertweigel readerarchitecturesforwirelesssurfaceacousticwavesensors
AT alexanderkoelpin readerarchitecturesforwirelesssurfaceacousticwavesensors
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