2013
DOI: 10.1109/tmtt.2013.2288089
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Space Difference Magnetic Near-Field Probe With Spatial Resolution Improvement

Abstract: To achieve good spatial resolution, small loop size is required in the traditional loop probe. However, the smaller loop size will lead to lower sensitivity for the probe. In addition, loop size is always limited by the minimum line spacing of the fabrication process. Another problem is that the asymmetric electric field coupling into a probe will not be canceled perfectly even if the structure of this probe is symmetric. To circumvent these problems, a space difference magnetic near-field probe with three kin… Show more

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Cited by 65 publications
(14 citation statements)
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References 17 publications
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“…19 The measurement accuracy of the proposed differential probes is increased by about 6% compared with that in Reference 14. For EFSR, the proposed probes improves at least 20 dB compared with the single probe in The bandwidth of the proposed probes is larger than that of the stacked differential probes, 21 where the two types of the differential probes have similar size.…”
Section: Measurement Accuracymentioning
confidence: 96%
See 1 more Smart Citation
“…19 The measurement accuracy of the proposed differential probes is increased by about 6% compared with that in Reference 14. For EFSR, the proposed probes improves at least 20 dB compared with the single probe in The bandwidth of the proposed probes is larger than that of the stacked differential probes, 21 where the two types of the differential probes have similar size.…”
Section: Measurement Accuracymentioning
confidence: 96%
“…The introduction of differential pairs can effectively improve performance of magnetic probes. In Reference 21, the differential probes with high spatial resolution were proposed, which has stacked differential structure. However, the coupling between the two parts of the differential probes is large at high frequency, which limits operation bandwidth.…”
Section: Introductionmentioning
confidence: 99%
“…The recognition of interference path and ground loop, and the location of interference source have become the main challenges in improving the electromagnetic compatibility of compact electronic products [1][2][3]. A magnetic near-field (H-field) probe acting as a useful near-field diagnostic tool is now widely used for radiation emission measurement [4,5], EMI source localisation [6,7], time-domain voltage and current measurement [8][9][10], and magnetic field measurement [11][12][13][14].…”
Section: Introductionmentioning
confidence: 99%
“…An open-ended monopole can be employed to pick up the normal electric field [12,13,14,15], while the electrically small electric dipole is utilized to detect the tangential electric field [16,17,18] over a surface above the planar circuit. The electromagnetic sensors can effectively sense electromagnetic fields so that there has been increasing attention given to developing high-performance electric-/magnetic-field sensors, such as extending the bandwidth [19,20,21], improving the spatial resolution [22,23,24] and enhancing the sensitivity [25,26,27,28]. Nowadays, there exists a situation where the reconstruction of the interference source based on the dipole moments needs to detect the tangential electric field [29,30].…”
Section: Introductionmentioning
confidence: 99%