Surface Acoustic Wave (SAW) Sensors for Cryogenic Temperature and Strain Sensing

Furniss, Jonathan; Carka, Dorinamaria; Voiculescu, Ioana; Lee, Kun-Lin; Xiang, Dan; Li, Fang

doi:10.1109/wisee.2018.8637326

Cited by 5 publications

(1 citation statement)

References 12 publications

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“…Moreover, applications in high-voltage powerline monitoring and fault detection systems were achieved using wireless SAW temperature sensing [301]. Besides the digitalization of classical industrial processes, Furniss et al [302] presented a wireless monitoring system using a SAW strain sensor to be operated under cryogenic conditions in aerospace and marine applications. Later, Hu et al [303] developed a wireless fault detection system for aerospace vehicles based on an L-band SAW resonator deposited by electron-beam lithography on a 128° Y-X LiNbO3 substrate.…”

Section: ) Temperature Sensorsmentioning

confidence: 99%

Strain Sensing Technology to Enable Next-Generation Industry and Smart Machines for the Factories of the Future: A Review

Hamed,

O’Donnell,

Lishchenko

et al. 2023

IEEE Sensors J.

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In the era of digitalization, there is a huge focus on capturing data from manufacturing processes and systems. Since the promotion of Industry 4.0, the industrial marketplace has been crowded with solution providers who excel in capturing and aggregating data on the cloud and presenting it on dashboards. From machine states to production targets, this type of data has become more readily available from tools, controllers, switches, and factory bus systems. As the industry pushes deeper into the machine for information and aspires to have smart machines that can feel and react to experiences during the manufacturing process, then more sophisticated technology is necessary. Strain sensor technology is a logical measurement principle to address this challenge for many industrial sectors. For researchers and industrialists to progress toward the smart machine agenda, there must be a firm grasp of the "technology-solution fit," i.e., what strain technology could provide the most appropriate solution. This paper presents a review of the state of the art in strain sensors that are foreseen as frontrunners to enable next-generation smart components and intelligent tools. The review focuses on industrial strain sensing technologies that are at a mature place on the technology readiness levels (TRLs) and present themselves as highly practical solutions for smart components and digitized machines, considering sensitivity, powered or passive, wired or wireless, and robustness. Through this review, researchers and industrialists will have a suite of solutions to move on with their innovative designs of smart machines based on embedded strain sensor technology.

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Section: ) Temperature Sensorsmentioning

confidence: 99%