Modified Waveguide Flange for Evaluation of Stratified Composites

Citation data:

IEEE Transactions on Instrumentation and Measurement, ISSN: 0018-9456, Vol: 63, Issue: 6, Page: 1524-1534

Publication Year:
2014
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Repository URL:
http://scholarsmine.mst.edu/ele_comeng_facwork/2305
DOI:
10.1109/tim.2013.2291952
Author(s):
Kempin, Matthew; Ghasr, Mohammad Tayeb Ahmad; Case, Joseph Toby; Zoughi, R.
Publisher(s):
Institute of Electrical and Electronics Engineers (IEEE)
Tags:
Physics and Astronomy; Engineering; Materials Characterization; Microwave; Nondestructive Evaluation; Open-Ended Waveguide; Stratified Composites; Waveguide Flange; Dielectric Properties; Electric Fields; Electromagnetism; Structure (Composition); Complex Reflection Coefficient; Materials Characterization; Millimeter Wave Frequencies; Open Ended Waveguides; Simultaneous Determinations; Materials Characterization; Microwave; Nondestructive Evaluation; Open-Ended Waveguide; Stratified Composites; Waveguide Flange; Dielectric Properties; Electric Fields; Electromagnetism; Structure (Composition); Complex Reflection Coefficient; Millimeter Wave Frequencies; Open Ended Waveguides; Simultaneous Determinations; Electrical and Computer Engineering
article description
Nondestructive evaluation of stratified (layered) composite structures at microwave and millimeter-wave frequencies is of great interest in many applications where simultaneous determination of the complex dielectric properties and thicknesses of multiple layers is desired. Open-ended rectangular waveguide probes, radiating into such structures, are effective tools for this purpose. The technique utilizes a full-wave electromagnetic model that accurately models the complex reflection coefficient as a function of frequency and material properties. While the electromagnetic model assumes an infinite waveguide flange (or ground plane), the measurements are conducted using a finite-sized flange. Consequently, the results of the electromagnetic model and those from measurements may not be sufficiently alike for accurate dielectric property and thickness evaluation. This paper investigates the effect of using an openended waveguide with a standard finite-sized flange on the error in evaluating the complex dielectric properties of a composite structure. Additionally, we present the design of a novel flange that markedly reduces this undesired effect by producing very similar electric field properties, at the flange aperture, to those created by an infinite flange. Finally, the efficacy of the design for evaluating the dielectric properties of a layered composite structure is demonstrated as well. © 2013 IEEE.