Microstrip Copper Nanowires Antenna Array for Connected Microwave Liquid Sensors

Cardillo, Emanuele; Tavella, Francesco; Ampelli, Claudio

doi:10.3390/s23073750

Cited by 4 publications

(2 citation statements)

References 35 publications

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“…We should mention that, despite the fact that the proposed sensor detects the presence of liquid in fabric, it cannot be considered a microwave liquid sensor. Liquid sensors are mainly focused on the characterization of the complex dielectric constant of a certain liquid under study [4][5][6][7] or on the determination of the composition of liquid mixtures [51,57,[71][72][73][74][75][76][77][78][79][80][81]. Such sensors are typically implemented by means of fluidic channels [51,57,[71][72][73][74][75][76][77].…”

Section: Discussionmentioning

confidence: 99%

Microwave Humidity Sensor for Early Detection of Sweat and Urine Leakage

Vélez

Casacuberta

et al. 2023

Electronics

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A planar microwave sensor devoted to the detection of humidity in underwear and clothes in general is proposed. The ultimate goal of the sensor is to detect the presence of liquids in fabrics, which is of interest to aid patients who suffer from certain pathologies, such as hyperhidrosis and enuresis. The main target in the design of the sensor, considering the envisaged application, is simplicity. Thus, the sensor operates at a single frequency, and the working principle is the variation in the magnitude of the transmission coefficient of a matched line loaded with an open-ended quarter-wavelength sensing stub resonator. The stub, which must be in contact with the so-called fabric under test (FUT), generates a notch in the transmission coefficient with a resonance frequency that depends on the humidity level of the fabric. By designing the stub with a moderately high-quality factor, the variation in the resonance frequency causes a significant change in the magnitude level at the operating frequency, which is the resonance frequency when the sensing stub is loaded with the dry fabric, and the presence of liquid can be detected by means of an amplitude detector. A prototype device is proposed and experimentally validated. The measured change in the magnitude level by simply depositing one 50 μL drop of water in the FUT is roughly 25 dB.

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Section: Discussionmentioning

confidence: 99%

Microwave Humidity Sensor for Early Detection of Sweat and Urine Leakage

Vélez

Casacuberta

et al. 2023

Electronics

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“…Metamaterial structures can boost the efficacy of microwave sensors by enhancing their sensitivity, selectivity, and compactness. Due to their artificial nature, metamaterials provide unique design flexibility in terms of frequency modulation and miniaturization [2]. The properties of metamaterial structures can be controlled by adjusting their geometrical parameters, such as shape, size, and periodicity.…”

Section: Introductionmentioning

confidence: 99%

New Complementary Resonator for Permittivity- and Thickness-Based Dielectric Characterization

Haq,

Koziel

2023

Sensors

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The design of high-performance complementary meta-resonators for microwave sensors featuring high sensitivity and consistent evaluation of dielectric materials is challenging. This paper presents the design and implementation of a novel complementary resonator with high sensitivity for dielectric substrate characterization based on permittivity and thickness. A complementary crossed arrow resonator (CCAR) is proposed and integrated with a fifty-ohm microstrip transmission line. The CCAR’s distinct geometry, which consists of crossed arrow-shaped components, allows for the implementation of a resonator with exceptional sensitivity to changes in permittivity and thickness of the material under test (MUT). The CCAR’s geometrical parameters are optimized to resonate at 15 GHz. The CCAR sensor’s working principle is explained using a lumped-element equivalent circuit. The optimized CCAR sensor is fabricated using an LPKF protolaser on a 0.762-mm thick dielectric substrate AD250C. The MUTs with dielectric permittivity ranging from 2.5 to 10.2 and thickness ranging from 0.5 mm to 1.9 mm are used to investigate the properties and calibrate the proposed CCAR sensor. A two-dimensional calibration surface is developed using an inverse regression modelling approach to ensure precise and reliable measurements. The proposed CCAR sensor is distinguished by its high sensitivity of 5.74%, low fabrication cost, and enhanced performance compared to state-of-the-art designs, making it a versatile instrument for dielectric characterization.

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