Analysis of the Principle, Facility and State-of-art Applications of Different Types Inductive Sensor

Authors

  • Yuze Tang

DOI:

https://doi.org/10.54097/svg0be13

Keywords:

Electromagnetic induction, electromagnetic sensors, differential electromagnetic sensors.

Abstract

As a matter of fact, different types of inductive sensor are widely used in various aspects. In this case, this study introduces the development history and current status of electromagnetic sensors, as well as the basic principles and future trends of different types of electromagnetic sensors. It provides a detailed introduction to the principles, structures, and measurement specifications of self-inductive sensors, differential air gap self-inductive sensors, mutual inductance sensors, and helical coil mutual inductance electromagnetic sensors. The characteristics and application scenarios of each sensor are analyzed. A comparison of the advantages and disadvantages of various electromagnetic sensors is presented. Furthermore, predictions are made regarding the future research directions and application trends of electromagnetic sensors. This study has gained a good understanding of the basic principles of various electromagnetic sensors and has learned about the selection of electromagnetic sensors for different scenarios, providing guidance for the study of new electromagnetic sensors and their practical applications.

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References

Won I J, Keiswetter D A, Fields G R A, et al. GEM-2: A new multifrequency electromagnetic sensor. Journal of Environmental and Engineering Geophysics, 1996, 1 (2): 129 - 137.

Saadon S, Sidek O. A review of vibration-based MEMS piezoelectric energy harvesters. Energy conversion and management, 2011, 52 (1): 500 - 504.

Li H Y, Zhao H T, Wei M L, et al. Intelligent electromagnetic sensing with learnable data acquisition and processing. Patterns, 2020, 1 (1).

Hatipoglu G, Ürey H. FR4-based electromagnetic energy harvester for wireless sensor nodes. Smart Materials and Structures, 2009, 19 (1): 015022.

Almazán J, Bergasa L M, Yebes J J, et al. Full auto-calibration of a smartphone on board a vehicle using IMU and GPS embedded sensors. 2013 IEEE Intelligent Vehicles Symposium (IV). IEEE, 2013: 1374 - 1380.

Bo F, Jiwen F, Jiuchun Z, et al. Bionic flutter wing piezoelectric-electromagnetic composite energy harvesting system. Energy Conversion and Management, 2022, 271: 116319.

Martini M L, Oermann E K, Opie N L, et al. Sensor modalities for brain-computer interface technology: a comprehensive literature review. Neurosurgery, 2020, 86 (2): E108 - E117.

Wang D H, Wang T. Principle, design and modeling of an integrated relative displacement self-sensing magnetorheological damper based on electromagnetic induction. Smart Materials and Structures, 2009, 18 (9): 095025.

Reinholz B A, Seethaler R J. Sensor Fusion of Self-Sensed Measurements for Position Control of a Constant Air-Gap Solenoid. IEEE Sensors Journal, 2022, 22 (24): 23997 - 24005.

Zhou X, Ruan Y, Mou X, et al. A Design of Electromagnetic Velocity Sensor with High Sensitivity Based on Dual-Magnet Structure. Sensors, 2022, 22 (18): 6925.

Martin J, Rashidi R. A differential transformer-based force sensor utilizing a magnetic fluid core. Microsystem Technologies, 2021, 27 (1): 115 - 126.

Yan K, Ge P, Hong J. Experimental study of shell side flow-induced vibration of conical spiral tube bundle. Journal of Hydrodynamics, 2013, 25 (5): 695 - 701.

Chandravanshi S, Katare K K, Akhtar M J. Broadband integrated rectenna using differential rectifier and hybrid coupler. IET Microwaves, Antennas & Propagation, 2020, 14 (12): 1384 - 1395.

Jaikla W, Adhan S, Suwanjan P, et al. Current/voltage-controlled quadrature sinusoidal oscillators for phase sensitive detection using commercially available IC. Sensors, 2020, 20 (5): 1319.

Nabavi M R, Nihtianov S. Eddy-current sensor interface for advanced industrial applications. IEEE Transactions on Industrial Electronics, 2010, 58 (9): 4414 - 4423.

Pavo J, Miya K. Optimal design of eddy current testing probe using fluxset magnetic field sensors. IEEE Trans. Magn, 1996, 32: 1597 - 1600.

Park J, Lee J, Min J, et al. Defects inspection in wires by nonlinear ultrasonic-guided wave generated by electromagnetic sensors. Applied Sciences, 2020, 10 (13): 4479.

Walter J, Acuna J, Kallfass I. Design and implementation of an integrated current sensor for a gallium nitride half-bridge. PCIM Europe 2018; International Exhibition and Conference for Power Electronics, Intelligent Motion, Renewable Energy and Energy Management. VDE, 2018: 1 - 8.

Nosenko A V, Kyrylchuk V V, Semen'ko M P, et al. Soft magnetic cobalt based amorphous alloys with low saturation induction. Journal of Magnetism and Magnetic Materials, 2020, 515: 167328.

Wahlström J, Kok M, de Gusmao P P B, et al. Sensor fusion for magneto-inductive navigation. IEEE Sensors Journal, 2019, 20 (1): 386 - 396.

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Published

15-12-2023

How to Cite

Tang, Y. (2023). Analysis of the Principle, Facility and State-of-art Applications of Different Types Inductive Sensor. Highlights in Science, Engineering and Technology, 72, 261-268. https://doi.org/10.54097/svg0be13