Browsing by Author "Sobhani, M. R."

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    Blood clotting time measurement using a miniaturized high-frequency ultrasound sensor
    (IEEE, 2023) Sobhani, M. R.; Majidi, Negar; Yaralıoğlu, Göksen Göksenin; Electrical & Electronics Engineering; YARALIOĞLU, Göksen Göksenin; Majidi, Negar
    This paper demonstrates a novel blood coagulation time measurement methodology that requires as low as 1 microliter of whole blood. The blood sample is placed on the top surface of a fused quartz plate where an ultrasonic transducer is fabricated on the bottom surface. The location of the blood sample is aligned with the transducer; therefore, the reflected acoustic waves from the blood/quartz interface are captured and converted to electrical signals by the transducer. The transducer is made of an 8 μm thick zinc oxide (ZnO) thin film that operates at 400 MHz. The acoustic impedance of blood changes due to the coagulation process. This affects the reflection coefficient and amplitude of the reflected waves from the blood/quartz interface. Thus, the blood coagulation time is determined by monitoring the amplitude of reflected acoustic waves. In the experiments, whole blood was used without any sample preparation. The method was tested using citrated blood with calcium chloride and activated partial thromboplastin (aPTT) reagents. We observed that aPTT coagulation times lengthened from 25 sec. to 47 sec. with the addition of heparin. The proposed method has the potential to be used in a disposable low-cost portable coagulation time measurement cartridge for patient self-testing.
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    Blood coagulation time measurement using a 1μL of whole blood on a TE mode BAW resonator
    (IEEE, 2018-12-20) Majidi, Negar; Sobhani, M. R.; Yaralıoğlu, Göksen Göksenin; Electrical & Electronics Engineering; YARALIOĞLU, Göksen Göksenin; Majidi, Negar
    This paper presents a possible way to blood coagulation time measurement using a TE (Thickness Extensions) mode BAW (Bulk Acoustic Wave) resonator which requires as low as 1 micro-liter of whole blood. The blood sample is placed on the top surface of a glass plate where a compressional ultrasonic transducer is fabricated on the bottom surface. The transducer is made of 8 μm thick zinc oxide (ZnO) thin film that has a thickness resonance frequency around 400 MHz. The transducer generates compressional (longitudinal) acoustic wave inside the piezoelectric thin film and glass substrate. The acoustic waves are mostly reflected and trapped inside the device from both sides of it; 1) the glass/liquid (blood) interface, and 2) the transducer/air interface. Most of the acoustic waves are reflected from the second interface because of the higher impedance mismatch, while the reflections from the first boundary are related to impedance (mechanical properties) of the liquid sample or blood. The acoustic impedance of blood changes due to the coagulation process. This affects the reflection coefficient and amplitude of the reflected waves from the blood/glass interface. Thus, the overall acoustic energy trapped inside the bulk film changes over the time which consequently affects the resonator parameters. The blood coagulation time was determined by monitoring the amplitude of the reflected sinusoidal acoustic waves at 400 MHz in the previous work using the same device. However, in this paper we demonstrate the resonance frequency shifts obtained by numerical modeling and practical measurements for a few liquid samples with different mechanical properties. The proposed method has a potential to be used in a low-cost portable coagulation time measurement cartridge which requires only 1μL of whole blood without centrifuging. A simple resonator can be implemented for tracking the resonating frequency to further reduce the size and cost of the device, to make it more suitable for patient self-testing applications.
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    ArticlePublicationOpen Access
    Design and comparison of 4 types of dual resonance proximity coupled microstrip patch antennas
    (The Applied Computational Electromagnetics Society, 2018-10) Majidi, Negar; Sobhani, M. R.; Kılıç, B.; İmeci, M.; Güngör, O. S.; İmeci, Ş. T.; Majidi, Negar
    In this paper there are four different shapes of proximity patch antennas (straight, trimmed, trapezoid and ribbon). The minimum input match achieved with the straight proximity patch antenna as -39.68 dB. The maximum gain is achieved with the ribbon proximity patch antenna as 12.1 dB. Simulation and measurement results are presented. There is a perfect match with simulated and measured gain. The antenna is first demonstrated example of working with four different geometries, having satisfactory gain and input match.
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    ArticlePublicationOpen Access
    Design and implementation of a quad element patch antenna at 5.8 GHz
    (The Applied Computational Electromagnetics Society, 2018-10) Sobhani, M. R.; Majidi, Negar; İmeci, Ş. T.; Majidi, Negar
    This paper presents simulation and experimental verification of a quad microstrip patch antenna that operates at 5.8 GHz. Sonnet antenna design software was used to simulate the performance of the antenna. To reduce the design's complexity and the computational load, the antenna and the feeding lines were simulated separately. An optimization was done for each subpart to get the optimum desired results. Finally, all the subparts were merged and the final structure was simulated to check the performance. A prototype of the antenna was fabricated on a double-sided PCB substrate (relative permittivity=10.2, thickness=1.28 mm) using a PCB milling machine. The S11 of -14 dB and -18.8 dB and maximum gain of 6.2 dB and 4.2 dB were obtained, from the simulation and experimental measurements, respectively.
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    Design of a quad element patch antenna at 5.8 GHz
    (IEEE, 2018) Majidi, Negar; Yaralıoğlu, Göksen Göksenin; Sobhani, M. R.; Imeci, T.; Electrical & Electronics Engineering; YARALIOĞLU, Göksen Göksenin; Majidi, Negar
    This paper presents simulation and experimental verification of a quad microstrip patch antenna that operates at 5.8 GHz. Sonnet antenna design software was used to simulate the performance of the antenna. To reduce the design's complexity and the computational load, the antenna and the feeding lines were simulated separately. An optimization was done for each subpart to get the optimum desired results. Finally, all the subparts were merged and the final structure was simulated to check the performance. A prototype of the antenna was fabricated on a double sided PCB substrate (relative permittivity=10.2, thickness=1.28 mm) using a PCB milling machine. The s 11 of -14 dB and -18.8 dB and maximum gain of 6.2 dB and 4.2 dB were obtained, from the simulation and experimental measurements, respectively.
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    Dual resonance proximity coupled patch antenna
    (IEEE, 2018-05-24) Kılıç, B.; İmeci, T.; Güngör, O. S.; İmeci, M.; Majidi, Negar; Sobhani, M. R.; Majidi, Negar
    In this paper there are four different shape of proximity patch antennas (straight, trimmed, trapezoid and ribbon). The minimum input match achieved with the straight proximity patch antenna as -39.68 dB. The maximum gain is achieved with the ribbon proximity patch antenna as 12.1 dB. Simulation and measurement results are presented. There is a perfect match with simulated and measured gain. The antenna is first demonstrated example of working with four different geometries, having satisfactory gain and input match.