AI-Assisted Ultra-High-Sensitivity/Resolution Active-Coupled CSRR-Based Sensor with Embedded Selectivity

Abdolrazzaghi, Mohammad; Kazemi, Nazli; Nayyeri, Vahid; Martín, Ferran

doi:10.3390/s23136236

Cited by 40 publications

(5 citation statements)

References 60 publications

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“…In this regard, Mohammad Abdolrazzaghi et al have proposed certain methods for enhancing the Q values of the metamaterial resonator sensor in the presence of lossy samples which may lead to more accurate results. 43–45 The proposed metamaterial WSRR sensor-based moisture measurement doesn't alter the composition of the sample and there is no need for elaborate sample preparation.…”

Section: Dielectric Properties Of Cereal Grainsmentioning

confidence: 99%

A metamaterial based sensor for moisture and density of cereal flours

P. V.,

Sebastian,

Varghese

et al. 2024

Sustainable Food Technol.

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Section: Dielectric Properties Of Cereal Grainsmentioning

confidence: 99%

A metamaterial based sensor for moisture and density of cereal flours

P. V.,

Sebastian,

Varghese

et al. 2024

Sustainable Food Technol.

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“…In the field of scientific research, various sensors for fluid process monitoring are under exploration, each at different stages of applicability. For instance, certain electrochemical sensors demonstrate potential as on-site monitoring tools [5]- [7], while others are especially promising for selective determination of individual substances [8], [9]. Micro-wave sensors are suitable for the simultaneous determination of different liquid volume fractions [10], [11], but require complex data evaluation.…”

Section: Introductionmentioning

confidence: 99%

Determination of Specific Volume Fractions in Multicomponent Liquids Using Hydrogel-Functionalized Plasmonic Sensors

Herzog,

Sobczyk,

Schuster

et al. 2024

IEEE Sensors J.

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Plasmonic sensors based on nanostructured metal substrates offer a promising solution for on-site implementation and continuous monitoring of process liquids due to their compact design, cost-effectiveness and rapid sensor response. The sensors are qualified for the functionalization with biological recognition elements and thus for biosensing. A functionalization with stimulusresponsive hydrogels further enhance their utility by enabling selective determination of specific substances in complex solutions. However, challenges arise in accurately interpreting the sensor signals due to the nonlinearity between the swelling curve of the hydrogel and the sensor signal and due to interferences from nontarget substances. An important objective of this study is to develop a methodology to accurately determine the concentration of a target substance in a multi-component solution, eliminating the influence of interfering substances. For this, it is imperative to enhance the comprehension of the system, elucidating the impact of the hydrogel's swelling state and of the composition on the sensor signal. An analytical model is presented, conveying a linear relationship between the sensor signal and the volume fraction of each constituent in the hydrogel. Based on the proposed model, a novel difference method is established to eliminate the influence of interfering substances, particularly at low concentrations of interfering substances. In a proof-of-concept, using an ethanol-sensitive hydrogel for detection of ethanol in aqueous ethanol-glucose solution, the method was validated, showing a negligible impact of the glucose concentration on the result.

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“…Ceramics waveguide components are widely utilized in modern communication and semiconductor packaging systems [1,2]. High-permittivity microwave dielectric ceramics (MWDCs) can significantly reduce the size of waveguide components, such as oscillators [3], filters [4], antennas [5], and sensors [6][7][8], while MWDCs with a low permittivity are more suitable for high-speed, high-frequency waveguides and semiconductor packages [9,10]. The frequency stability of waveguide devices is crucial for all the above applications, especially high-sensitivity frequency-variation systems [11].…”

Section: Introductionmentioning

confidence: 99%

Microwave Frequency Offset Induced by Subsurface Damage in Abrasive-Machined Semiconductor Ceramic Waveguide

Wang,

Wei,

Lin

et al. 2023

Machines

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Ceramic waveguide components play a critical role in modern microwave semiconductor systems. For the first time, this work reports experimental results obtained when dielectric ceramics are abrasive-machined into waveguide components. This process will cause subsurface damage (SSD), resulting in a deviation in their working frequency which can degrade the performance of the system. For a substrate-integrated waveguide (SIW) resonator working at 10.1 GHz, SSD with a depth of 89 um can cause a maximum frequency offset of 20.2%. For a mm wave component working at 70 GHz, the corresponding frequency offset could increase to 169%. Three resonator SIW filters with SSD are studied, and the results demonstrate that the frequency offset induced by SSD can reduce the pass rate of the filters from 95.4% to 0%. A theoretical analysis is performed to reveal the mechanism and to offer a quantitative estimation of the limiting range of the offset caused by SSD. Feasible methods for reducing the offset caused by SSD, such as structure design, processing optimization, and material reinforcement, are discussed.

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AI-Assisted Ultra-High-Sensitivity/Resolution Active-Coupled CSRR-Based Sensor with Embedded Selectivity

Cited by 40 publications

References 60 publications

A metamaterial based sensor for moisture and density of cereal flours

A metamaterial based sensor for moisture and density of cereal flours

Determination of Specific Volume Fractions in Multicomponent Liquids Using Hydrogel-Functionalized Plasmonic Sensors

Microwave Frequency Offset Induced by Subsurface Damage in Abrasive-Machined Semiconductor Ceramic Waveguide

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