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Reflective-Mode Phase-Variation Sensors Based on a Movable Step Impedance Resonator (SIR) and Application to Micrometer-Scale Motion Sensing | IEEE Journals & Magazine | IEEE Xplore
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Journals & Magazines >IEEE Transactions on Microwav... >Volume: 73 Issue: 1

Reflective-Mode Phase-Variation Sensors Based on a Movable Step Impedance Resonator (SIR) and Application to Micrometer-Scale Motion Sensing

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Amirhossein Karami-Horestani; Ferran Paredes; Pau Casacuberta; Amir Ebrahimi; Paris Vélez; Karl Adolphs Saura
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Abstract:

This article proposes a novel reflective-mode phase-variation sensor based on a movable step impedance resonator (SIR) implemented in coplanar waveguide (CPW) technology....Show More

Metadata

Abstract:

This article proposes a novel reflective-mode phase-variation sensor based on a movable step impedance resonator (SIR) implemented in coplanar waveguide (CPW) technology. The sensing principle is the variation of the phase of the reflection coefficient at a specific (operating) frequency generated by SIR motion. The sensor is modeled by a transmission line terminated with a series resonator connected to ground, and the reactive element subjected to motion-related variations is the SIR capacitance. The movable SIR, etched on an independent substrate, can be displaced either vertically or transversally, i.e., orthogonal to the symmetry plane of the CPW. In the first case, the device can be used as a highly sensitive proximity sensor with 10- \mu m resolution. In the second case, the device can operate either as a linear or angular displacement and velocity sensor, provided that a linear or a circular chain of SIRs is etched in a movable substrate. The measurement of the (medium/long) range linear or angular displacement and velocity is based on pulse counting of the phase-modulated signal generated in the reflection coefficient by the motion of the SIR chain (transversely to the axis of the CPW). The presented prototypes, a micrometer-scale proximity sensor and a linear displacement/velocity sensor, validate the approach and point out the versatility of the proposed structure for motion sensing.
Published in: IEEE Transactions on Microwave Theory and Techniques ( Volume: 73, Issue: 1, January 2025)
Page(s): 592 - 605
Date of Publication: 15 July 2024

ISSN Information:

DOI: 10.1109/TMTT.2024.3423407

Funding Agency:

References is not available for this document.
Contents

I. Introduction

Significant efforts have been recently dedicated to the implementation of motion sensors using microwaves, and, particularly, planar microwave technology. The reasons are diverse and are detailed in [1] and [2]. In brief, planar microwave sensors are low cost and small sized and can be implemented in a diversity of substrates, including rigid, flexible (conformal), plastic, and organic substrates (e.g., paper), by means of subtractive (e.g., etching) or additive (e.g., screen printing or inkjet) processes. Moreover, planar microwave sensors are compatible with many other technologies, such as microfluidics, micromachining, 3-D printing, and textiles, and can be applied to a wide variety of scenarios, including liquid sensing, motion sensing, biosensing, and wearables.

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