Symmetrical double‐loop H‐field probe with floating shield for improving sensitivity and electric field suppression

Liu, Jiesheng; Xiao, Meizhen; He, Xiao; Fang, Wenxiao; Shao, Weiheng; Huang, Quan; Lu, Guoguang; Wang, Lei; Huang, Yun; En, Yunfei; Yao, Ruohe

doi:10.1049/mia2.12050

Cited by 9 publications

(11 citation statements)

References 24 publications

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“…13 The differential electric field suppression η d is defined as the maximum of H-field distribution measublack by the probe at θ ¼ 90 divided by the maximum of H-field distribution measublack by the probe at θ ¼ 0 . 19 Figure 8 shows that the η d is 14 dB at 10 GHz. The η d from 500 MHz to 20 GHz is shown in Figure 9.…”

Section: Differential Electric Field Suppression η Dmentioning

confidence: 96%

“…In Equation ( 1), it can be seen that the sensitivity is related to the noise floor of the spectrum analyzer after composing the system and the frequency response (S 21 ) of the probe. Further, the reliable measurement H-field intensity sensitivity δ H can be calculated by 19 δ…”

Section: Sensitivity δmentioning

confidence: 99%

“…The third probe is the popular passive probe as a reference probe (shown in Figure 10). 14,19 The current sensitivity of system (δ I ) with the same liftoff = 500 μm by using these probes RF-R 3-2, RF-U 2,5-2, reference probe and proposed probe are shown in Table 2. In order to obtain the current sensitivity, a spectrum analyzer (FSW43, manufactublack by ROHDE & SCHWARZ) is used to measure the noise floor, the internal attenuation is set to 0, the internal preset amplifier is set to off, and RBW refers to IEC61967-1.…”

Section: Differential Electric Field Suppression η Dmentioning

confidence: 99%

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A miniature shielded‐loop active H‐field probe design with high spatial resolution for near‐field measurement

Tang

Liu

et al. 2021

Int J RF Microw Comput Aided Eng

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A miniature practical active magnetic field (H-field) probe with 0.5 mm Â 0.15 mm loop size is designed for electromagnetic interference analysis in electronic systems from 150 kHz to 12 GHz. This probe is fabricated in a four-layer printed circuit board using high-performance and low-loss Rogers material (RO4350B). A low noise amplifier with 14 dB-gain is applied to amplify the radio frequency detect signal. The spatial resolution of the proposed probe is verified under the microstrip with different widths (1.55 and 0.24 mm). In addition, the verification results indicate that the proposed small loop active shielded H-field probe can obtain the better spatial resolution of 422 μm with liftoff = 100 μm. Regarding to the sensitivity of the probe, the proposed probe realizes 16.7 dB μA at 3 GHz with the liftoff = 100 μm. compared with other commercial probes and a reference probe, the proposed probe has better spatial resolution at 150 kHz-12 GHz and sensitivity at 1.5-12 GHz.

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Section: Differential Electric Field Suppression η Dmentioning

confidence: 96%

Section: Sensitivity δmentioning

confidence: 99%

Section: Differential Electric Field Suppression η Dmentioning

confidence: 99%

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A miniature shielded‐loop active H‐field probe design with high spatial resolution for near‐field measurement

Tang

Liu

et al. 2021

Int J RF Microw Comput Aided Eng

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“…The voltage

U_{m}

induced by detected structure in the frequency domain can be calculated by

{boldU}_{normalm} = N j ω {boldΦ}_{normalm},

where

N

is the number of turns. Figure 5b shows the equivalent circuit model of proposed probe [22]. the output voltage

U_{o}

of the probe can be expressed as

{boldU}_{o} = \frac{N j ω {boldΦ}_{normalm} R}{j ω L_{normals} + R},

where

R

= 50

normalΩ

is internal resistance of the instrument,

L_{s}

is the self‐induction of the detected structure, it is positively related to the number of turns

N

and the area

S

.…”

Section: Proposed Two‐turn Active Probementioning

confidence: 99%

“…At this time, the probe senses different electric fields on the left and right metal walls of the detection loop, one direction is down, the other direction is up. But sometimes,

\max (U false(y false) {false|}_{θ = 90^{\circ}})

will also appear at y = 0, which may be due to leaked magnetic fields [22]. For the above two cases, Equation (10) has some representational significance, and to some extent, it represents the ability of the probe to suppress the unwanted field.…”

Section: Characteristics Of the Proposed Probementioning

confidence: 99%

A two‐turn loop active magnetic field probe design for high sensitivity near‐field measurement

Shao

Huang

et al. 2021

IET Science Measure & Tech

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This paper develops an active magnetic near field probe (H-field probe) by using a fourlayer printed circuit board (PCB) technique. Two-turn detection structure and a low noise amplifier are used to improve probe's frequency response. The two-turn detection structure can maximize the use of PCB stack resources, and a 14.5 dB gain amplifier can increase signal output capability. The probe can then be used for electromagnetic compatibility (EMC) test from 150 kHz to 3 GHz. Compared with traditional active shielded-loop H-field probe (TAHP) with loop area of 500 𝜇m 2 , the frequency response of the proposed probe can improve 20 dB at 0.5 GHz. Different from the method of comparing the sensitivity of the probe only through the frequency response, this paper measures and analyzes the real sensitivity of the probing device composed of the proposed probe. Under the condition of the same receiver parameter setting, the sensitivity at 0.5 GHz is increased by 11.7 dB compared with commercial passive probing device and 20.2 dB at 0.5 GHz compared with the probing device with TAHP device. It reaches −32.4 dB µA. In addition, the proposed probe has acceptable spatial resolution of 1.28 mm at 1 GHz, which is more suitable for printed circuit board level EMI analysis.

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Asymmetric calibration method on a back‐to‐back double‐loop differential magnetic field probe

He,

Huang,

Zeng

et al. 2023

IET Science Measure & Tech

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The asymmetric calibration method is a very interesting technology for differential output probes. It has been proven that the asymmetric calibration method (ACM) can broaden the application scenarios of the electromagnetic field dual probe. However, ACM is not verified on a back‐to‐back double‐loop differential magnetic field probing system. This paper calibrates a back‐to‐back double‐loop differential magnetic field probing system by inserting a connector for creating an asymmetry using ACM. The calibration results show that ACM can be used to calibrate an asymmetric back‐to‐back double‐loop differential magnetic field probing system. The calibration results are further verified by measuring the standing wave magnetic field, and the verification results show that the asymmetric calibration method is effective in eliminating the asymmetry of the back‐to‐back double‐loop differential magnetic field probing system and the work frequency band reaches up to 12 GHz.

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Symmetrical double‐loop H‐field probe with floating shield for improving sensitivity and electric field suppression

Cited by 9 publications

References 24 publications

A miniature shielded‐loop active H‐field probe design with high spatial resolution for near‐field measurement

A miniature shielded‐loop active H‐field probe design with high spatial resolution for near‐field measurement

A two‐turn loop active magnetic field probe design for high sensitivity near‐field measurement

Asymmetric calibration method on a back‐to‐back double‐loop differential magnetic field probe

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