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Journals & Magazines >IEEE Transactions on Electrom... >Volume: 67 Issue: 1

A Slot-Type Ez Probe With a Lower Effective Center

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Yu Tian; Xing-Chang Wei; Di Wang; Richard Xian-Ke Gao
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Abstract:

This article introduces a novel slot-type Ez probe engineered to achieve a lower effective center. This innovation addresses the limitation inherent in traditional Ez pro...Show More

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Abstract:

This article introduces a novel slot-type Ez probe engineered to achieve a lower effective center. This innovation addresses the limitation inherent in traditional Ez probes, which have a higher effective center and consequently suffer from low spatial resolution. The proposed probe incorporates a slot structure in its detection part, greatly lowering its effective center. Through simulation optimization, the slot structure is carefully designed to strike a balance between a high sensitivity and low effective center. To further elucidate the working principle of the slot probe, this article examines the effect of the probe's geometry on the effective center. The probe's design on a four-layer printed circuit board enables cost-effective fabrication without compromising stable performance. Operating within a frequency range of up to 30 GHz, the probe also effectively suppresses unwanted fields across a wide spectrum. Both simulation and measurement results corroborate the exceptional performance of the proposed probe, validating its efficacy in practical applications.
Published in: IEEE Transactions on Electromagnetic Compatibility ( Volume: 67, Issue: 1, February 2025)
Page(s): 33 - 41
Date of Publication: 11 December 2024

ISSN Information:

DOI: 10.1109/TEMC.2024.3503725

Funding Agency:

References is not available for this document.
Contents

I. Introduction

Near-field scanning technology [1], [2], in conjunction with radiation source reconstruction method [3], [4], has emerged as a widely used approach for electromagnetic interference (EMI) analysis [5]. Near-field probes are the critical component in the near-field scanning systems.

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