Microwave sensor technologies for food evaluation and analysis: Methods, challenges and solutions

Meng, Zhaozong; Wu, Zhipeng; Gray, J.O.

doi:10.1177/0142331217721968

Cited by 38 publications

(18 citation statements)

References 80 publications

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“…17 Out of many planar resonant RF sensor structures, substrate integrated waveguide (SIW) usually provides a somewhat higher Q-factor, maintaining low radiation and leakage loss at specified frequency range, improving its applicability for accurate RF sensing application. [18][19][20][21] Therefore, In recent time, SIW-based RF sensors have been considered for numerous industrial applications such as agriculture, 22,23 bio-sensing, 24,25 pharmaceutical, chemical detection, [18][19][20][21]23,[25][26][27] food adulterate detection, 28 and so on. 29 Additionally, SIW-based RF sensors have also been efficiently employed in the chemical, 21,23 food, 18 and biomedical industries 24 for qualitative analysis of test samples under consideration.…”

Section: Introductionmentioning

confidence: 99%

CSIWC RF sensor for micro‐fluidic non‐contact quality assessment of milk

Jain

Tiwari

Akhtar

2021

Int J RF Mic Comp-Aid Eng

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In this work, the design of the SIW-based RF sensor is presented to assess the targeted quality of milk. In the present scenario, mainly two parameters, namely, purity and fat level are considered to assess the milk quality. Customized in-lab preparation of milk adulterant using low-grade vegetable oil, detergent, water, and glucose is carried out to analyze the practical milk adulteration scenario. Moreover, commonly consumed pure cow and buffalo milk samples are also collected to record the corresponding reference RF properties. A systematic approach is followed to develop the complete database related to actual milk samples with known fat percentages. Then accordingly, the proposed RF sensing mechanism is employed to identify the possible deviation in milk quality. The proposed work mainly employs the SIW-based noncontact RF sensing mechanism where the perturbation formulation is used to perform a qualitative assessment. Mathematical processing of the relative shift in the obtained S-parameters, corresponding to the variation in dielectric property of test samples at specified RF frequency, is carried out. Even though the work's main aim is a qualitative assessment of milk quality, dielectric property estimation of considered test samples is also performed to visualize their quantitative RF attributes. A compact, low-cost, non-contact, real-time, and microfluidic CSIWC RF sensor with high-quality factor and improved accuracy and sensitivity is designed.

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Section: Introductionmentioning

confidence: 99%

CSIWC RF sensor for micro‐fluidic non‐contact quality assessment of milk

Jain

Tiwari

Akhtar

2021

Int J RF Mic Comp-Aid Eng

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“…Consequently, skilled operators are required to handle and use these microstrip‐based sensors. Therefore, for food quality monitoring, a more cost‐effective, novel, and simple method is required with wider bandwidth and high frequency range to improve the spatial resolution and penetration depth 25 …”

Section: Introductionmentioning

confidence: 99%

Novel monkey‐wrench‐shaped microstrip patch sensor for food evaluation and analysis

2021

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BACKGROUND: Microwave sensor technology is considered to be a non-destructive and hygienic means for food evaluation and analysis. The rapid progress in microwave sensor technologies motivated us to present a novel monkey-wrench-shaped microstrip patch sensor for evaluating food quality. The proposed antenna is considered as a liquid sensor to detect adulteration in liquids by examining the relationship between concentration, shift in resonant frequency, and variation in reflection coefficient. RESULTS:The sensor has a compact size of 17 × 14 mm 2 imprinted on an FR4 substrate of thickness 1.57 mm. This microwave system is proposed for monitoring overall milk quality using a microstrip sensor and has considerably good numerical sensitivity and accuracy (13.11% and 88.5% respectively), which makes the system attractive for detecting adulteration. Further, the Q-factor for the proposed sensor is 209 and has a standard deviation less than the difference between non-adulterated and adulterated values, giving resolution high enough to distinguish adulteration with an acceptable statistical accuracy. In this study, different milk categories (buffalo, goat, and cow milk) are considered as liquid samples to detect adulteration by demonstrating the variation in reflection coefficient due to change in dielectric properties for the following different cases: (i) adulteration of milk with water; (ii) adulteration of milk with synthetic milk powder; (iii) adulteration of milk with caustic soda; and (iv) adulteration of milk with vegetable oil. The referred variation in reflection coefficient and resonant frequency is due to a change in the dielectric properties of a liquid when a varying concentration of an adulterant/solute is added to the liquid sample.CONCLUSION: The simulation and measured results show good agreement that validates the proposed sensor for food adulteration detection with high sensitivity. In terms of performance, the proposed sensor shows accuracy with high spatial resolution and reduced penetration depth to detect the adulteration in various milk samples (i.e. buffalo, goat, and cow milk).

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“…Recently, myriad studies have offered microwave-based techniques for the identification and observation of numerous liquid samples [7][8][9][10][11][12]. These techniques offer a cost-effective and simple solution to the sensing problem where sensing takes place due to the interaction between the sample and resonating modes of electromagnetic waves.…”

Section: Introductionmentioning

confidence: 99%

Rectangular Cavity Sensor for Distinguishing Between Normal and High-Drivability-Index Gasolines

2020

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The Drivability Index (DI) of gasoline is a measure of fuel performance of engine operations. Therefore, distinguishing a gasoline of specific DI in advance is useful for improving engine efficiency and maintenance. We consider the problem of distinguishing between normal gasoline and HiDI (High DI) gasolines and propose an electromagnetic wave-based rectangular cavity sensor. For commercialization, it is designed to have a simple structure and basic resonance mode TM110 in the common frequency range of 5 GHz to 6 GHz. The proposed sensor has a simple structure of monopole radiating electromagnetic waves and a metal rectangular cavity containing gasoline samples. By considering one commercial normal gasoline sample of permittivity 2.157 and five HiDI gasoline samples of permittivity in the range of 2.018 to 2.218, we obtain 11.5 MHz resonance separation at room temperature to the closest HiDI sample from the simulation and 8 MHz resonance separation from the fabricated sensor experiment. To verify the feasibility of the fabricated sensor under temperature variation from 0°C to 20°C, we derived a simple linear distinction function of resonance frequency and S11 parameter and obtained a minimum 4.4MHz resonance separation. These results showed that the distinction performance for normal gasoline is robust to temperature variations. Furthermore, we showed that the distinction property is robust to design parameter errors, installation position variations and sensing time variations. These results show that the proposed sensor can be utilized effectively for distinguishing normal gasoline.

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Microwave sensor technologies for food evaluation and analysis: Methods, challenges and solutions

Cited by 38 publications

References 80 publications

CSIWC RF sensor for micro‐fluidic non‐contact quality assessment of milk

CSIWC RF sensor for micro‐fluidic non‐contact quality assessment of milk

Novel monkey‐wrench‐shaped microstrip patch sensor for food evaluation and analysis

Rectangular Cavity Sensor for Distinguishing Between Normal and High-Drivability-Index Gasolines

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