Abstract
A novel robust approach for permittivity measurements of liquid materials in a wide frequency range is proposed. A high-sensitivity microwave-fluidic sensor is developed enabling direct determination of liquid samples' permittivity from the measured sensor's propagation constant. Importantly, neither sensor calibration using liquid standards nor sensor's geometry (except length) information is required, which is very advantageous for industrial applications. This is achieved through the sensor's geometry, which is a two-wire transmission line (TWL) encapsulated in a 3-D printed container, and thus, the liquid-under-test fully encloses the propagating electromagnetic waves. The measurement setup comprises the sensor cascaded between two microstrip-to-TWL transitions for which a simplified de-embedding procedure is proposed using only a THRU standard. For demonstration, a setup was developed with transitions operating within 1-10 GHz and tested up to 18 GHz by measurement of a set of alcohols to produce useful data within the transition bandwidth, which can be extended at the cost of increased uncertainty by postprocessing. Finally, the measurement error study has shown that a relatively low uncertainty and error with respect to the reference is obtained, verifying the usability of the developed measurement technique.
Highlights
C HARACTERIZATION of and monitoring the properties of resources for quality assessment are important industrial processes
We propose a novel robust approach for liquid chemicals’ complex permittivity measurements in a wide
The THRU printed circuit board (PCB) was assembled in a way to enable de-embedding solely the TW sensor-related propagation constant, i.e., short wires were soldered to compensate for the coplanar strip (CPS)-to-TW transitions wires influence while the printed parts were attached using the same epoxy glue to compensate for the liquid chamber end walls material and glue influence
Summary
C HARACTERIZATION of and monitoring the properties of resources for quality assessment are important industrial processes. Methods utilizing electromagnetic (EM) waves are of great interest since the EM waves penetrate the materials and allow for nondestructive characterization with high measurement speed In such cases, the electrical permittivity is a quantity of interest. The resonant methods can yield high accuracy; the material-under-test is characterized only at one or more discrete frequencies Such methods are suitable, among others for the determination of permittivity deviation or constituents’ mixing ratio in a solution once an appropriate model is known. A transmission-type sensor is proposed, comprised a two-wire transmission line (TWL) enclosed within a 3-D-printed liquid chamber that is to be filled with LUT Such a configuration ensures high sensitivity as to when LUT is present, it fully constitutes the dielectric medium for the TWL. It is shown that after postprocessing of the measured data, the frequency range of the measured permittivity is not limited to one of the transitions and certifying the broadband operation
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