An Ultrahigh Sensitive Microwave Microfluidic System for Fast and Continuous Measurements of Liquid Solution Concentrations

Słobodzian, Piotr; Szostak, Krzysztof; Skowronek, Katarzyna; Jasińska, Laura; Malecha, Karol

doi:10.3390/s21175816

Cited by 4 publications

(2 citation statements)

References 29 publications

(36 reference statements)

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“…Real-time and high-accuracy measurement can provide the time-frequency characteristic of microwave signals in a realtime dynamic fashion, while enabling clear analysis of the generating source. In recent years, such measurements have quickly attracted interest for applications in astronomy, [1][2][3] communications, [4] materials, [5][6][7][8] medicine, and healthcare, [9][10][11][12][13][14][15] and devices. [16] For these applications, electronic solutions are the most straightforward and widely implemented microwave measurements today.…”

Section: Introductionmentioning

confidence: 99%

Real‐Time and High‐Accuracy Microwave Frequency Identification Based on Ultra‐Wideband Optical Chirp Chain Transient SBS Effect

Wang

Dong

2023

Laser & Photonics Reviews

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The use of stimulated Brillouin scattering (SBS) for microwave photonics frequency measurement is widely studied because of its unique advantage of high accuracy. However, the technique's slow response severely limits its use for real-time applications. To solve this problem, this work proposes and demonstrates the use of an ultra-wideband optical chirp chain (OCC) transient SBS effect to avoid the need to slowly frequency sweep the Brillouin spectrum. This innovation enables real-time and high-accuracy microwave frequency identification. It is shown that real-time microwave tracking can be achieved by continuously repeating the OCC-modulated wave, which allows for wide-range frequency sweeping over a very short time. High accuracy is achieved by exploiting the narrow bandwidth characteristic of the transient Brillouin spectrum. In the experiments, the temporal resolution is 100 ns for the time-varying frequency microwave identification, enabled by the transient SBS effect, representing at least three orders of magnitude improvement over previously reported SBS-based methods. The frequency measurement is accurate to 1 MHz. In addition, several further benefits, such as resolving multifrequency signals, reconfigurable instantaneous bandwidth, and 20 GHz frequency measurement range, are demonstrated.

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Section: Introductionmentioning

confidence: 99%

Real‐Time and High‐Accuracy Microwave Frequency Identification Based on Ultra‐Wideband Optical Chirp Chain Transient SBS Effect

Wang

Dong

2023

Laser & Photonics Reviews

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“…Advanced structuring capabilities and multilayer approach allow for high packaging density, reducing the volume and weight of the device, both of which are very valuable in space missions. This technology is proven through a wide variety of sensors and microsystems [7], including pressure sensors [8], accelerometers [9], magnetic sensors [10], and biosensing microsystems with optical [11] and microwave detection [12]. Due to its robustness and reliability, the LTCC technology is well known in military and space applications [13,14].…”

Section: Introductionmentioning

confidence: 99%

LTCC Strip Electrode Arrays for Gas Electron Multiplier Detectors

Dąbrowski

Nawrot

Czok

et al. 2022

Sensors

Self Cite

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The Low Temperature Cofired Ceramic (LTCC) technology has proven to be highly suitable for 3D microstructures manufacturing in electronic devices due to its excellent electrical and mechanical properties. In this paper, a novel idea of implementing the LTCC structures into high-energy particle detectors technology is proposed. It can be applied in High Energy Physics (HEP) laboratories, where such sophisticated sensors are constantly exposed to particles of the TeV energy range for many years. The most advanced applications of the concept are based on dedicated gas amplifier systems coupled with readout microstructures. Typically, the readout microstructures are made in the Printed Circuit Boards (PCB) technology and processed in a sophisticated and patent-protected way. This article presents the manufacturing process and parameters of the novel microstructures made in the LTCC technology. The structures were implemented into the high-energy particle detector, and the first results are presented.

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Single-Frequency Microwave Measuring System for Liquid Characterization for Point-of-Care Testing

Javadizadeh,

Tabalvandani,

Badieirostami

et al. 2024

2024 32nd International Conference on Electrical Engineering (ICEE)

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An Ultrahigh Sensitive Microwave Microfluidic System for Fast and Continuous Measurements of Liquid Solution Concentrations

Cited by 4 publications

References 29 publications

Real‐Time and High‐Accuracy Microwave Frequency Identification Based on Ultra‐Wideband Optical Chirp Chain Transient SBS Effect

Real‐Time and High‐Accuracy Microwave Frequency Identification Based on Ultra‐Wideband Optical Chirp Chain Transient SBS Effect

LTCC Strip Electrode Arrays for Gas Electron Multiplier Detectors

Single-Frequency Microwave Measuring System for Liquid Characterization for Point-of-Care Testing

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