Study on Sensing Urine Concentrations in Water Using a Microwave Sensor Based on Hilbert Structure
Author:
Abdulsattar Rusul Khalid1ORCID, Al-Kaltakchi Musab T. S.2ORCID, Mocanu Iulia Andreea3ORCID, Al-Behadili Amer Abbood2ORCID, Abdu Hassain Zaid A.2ORCID
Affiliation:
1. Department of Electrical Engineering, University of Technology, Baghdad 10066, Iraq 2. Department of Electrical Engineering, College of Engineering, Mustansiriyah University, Baghdad 10052, Iraq 3. Telecommunications Department, National University of Science and Technology Politehnica Bucharest, 060042 Bucharest, Romania
Abstract
In this study, a two-port network-based microwave sensor for liquid characterization is presented. The suggested sensor is built as a miniature microwave resonator using the third iteration of Hilbert’s fractal architecture. The suggested structure is used with the T-resonator to raise the sensor quality factor. The suggested sensor is printed on a FR4 substrate and has a footprint of 40×60×1.6mm3. Analytically, a theoretical investigation is made to clarify how the suggested sensor might function. The suggested sensor is created and put to the test in an experiment. Later, two pans to contain the urine Sample Under Test (SUT) are printed on the sensor. Before loading the SUT, it is discovered that the suggested structure’s frequency resonance is 0.46 GHz. An 18 MHz frequency shift is added to the initial resonance after the pans are printed. They monitor the S-parameters in terms of S12 regarding the change in water content in the urine samples, allowing for the sensing component to be completed. As a result, 10 different samples with varying urine percentages are added to the suggested sensor to evaluate its ability to detect the presence of urine. Finally, it is discovered that the suggested process’ measurements and corresponding simulated outcomes agreed quite well.
Funder
National Program for Research of the National Association of Technical Universities—GNAC ARUT 2023
Reference39 articles.
1. Abdulkarim, Y.I., Deng, L., Karaaslan, M., Dalgaç, Ş., Mahmud, R.H., Ozkan Alkurt, F., Muhammadsharif, F.F., Awl, H.N., Huang, S., and Luo, H. (2020). The detection of chemical materials with a metamaterial-based sensor incorporating oval wing resonators. Electronics, 9. 2. Obaid, S.M., Elwi, T., and Ilyas, M. (2024, May 24). Fractal Minkowski-Shaped Resonator for Noninvasive Biomedical Measurements: Blood Glucose Test. Available online: https://openaccess.altinbas.edu.tr/xmlui/handle/20.500.12939/1020. 3. Biris, A.S., Al-Rizzo, H., Elwi, T., and Rucker, D. (2014). Nano and Micro Based Antennas and Sensors and Methods of Making Same. (8,692,716), U.S. Patent. 4. Makeev, Y., Lifanov, A., and Sovlukov, A. (2014, January 7–13). Microwave measurement of water content in flowing crude oil with improved accuracy. Proceedings of the 2014 24th International Crimean Conference Microwave & Telecommunication Technology, IEEE, Sevastopol, Ukraine. 5. Ashton, S., Cutmore, N., Roach, G., Watt, J., Zastawny, H., and McEwan, A. (1994, January 7–10). Development and trial of microwave techniques for measurement of multiphase flow of oil, water and gas. Proceedings of the SPE Asia Pacific Oil and Gas Conference and Exhibition, SPE, Melbourne, Australia.
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