A tunable EBG absorber for radio-frequency power imaging

Yagitani, Satoshi; Keigo, Katsuda; Tanaka, Ryo; Nojima, Masayuki; Yoshimura, Y.; Sugiura, Hiroaki

doi:10.1109/ursigass.2011.6050776

Cited by 4 publications

(1 citation statement)

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“…The equivalent circuit model of the absorber is given in Figure 7, where C D , L D and R D are the stray capacitance, stray inductance and resistance of a varactor diode, respectively, and R loss represents the dielectric loss of the substrate. Detailed analysis of such a circuit was made to reveal that even a small varactor resistance (a few Ohms) is translated to a larger surface resistance which severely degrades the absorption performance especially at lower frequencies (Yagitani et al, 2011b).…”

Section: Rf Power Distribution Measurementmentioning

confidence: 99%

In-Situ Measurement and Visualization of Electromagnetic Fields

Ozaki

Sugiura

Yagitani

et al. 2013

Proceedings of the 2nd International Conference on Telecommunications and Remote Sensing

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In-situ monitoring of electromagnetic field distributions is useful for localizing and identifying EM noise sources, as well as for evaluating actual antenna characteristics. A couple of new techniques developed for in-situ measurement and visualization of electromagnetic fields are reported. At first, visualization of EM field distributions measured by a freehand scanning sensor on a live video image is described. Secondly, imaging of 2-d RF field distributions incident on a metamaterial absorber is explained. Then, in-situ visualization techniques for EM vectors and RF polarizations are discussed. Such techniques are expected to be quite useful for measuring EM field distributions in various scenarios in the fields of EMC, antennas and propagation.

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Section: Rf Power Distribution Measurementmentioning

confidence: 99%

In-Situ Measurement and Visualization of Electromagnetic Fields

Ozaki

Sugiura

Yagitani

et al. 2013

Proceedings of the 2nd International Conference on Telecommunications and Remote Sensing

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Direction-of-Arrival Estimation With Planar Luneburg Lens and Waveguide Metasurface Absorber

Ohmae

Yagitani

2023

IEEE Access

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Direction of arrival (DOA) estimation using array antennas is known to have high resolution. However, these algorithms require high computational resources. This paper proposes a unique DOA estimation system without a sophisticated algorithm, using a planar Luneburg lens and a waveguide metasurface absorber. The planar Luneburg lens consists of a convex lens and a waveguide that separates incoming electromagnetic waves from different directions and focuses them at different points on the sides of the convex lens. The metasurface absorber consists of a mushroom-shaped structure that, when placed at the focal point of the lens, behaves like a compact 2D sensor array. Information regarding the intensity and angle of the incident electromagnetic wave can be obtained from the power and position of the sensor element. The resolution of the system is 2.2-2.4 degrees (depending on the sensor position), and the maximum estimation error is within 2.4 degrees in the 5.65 GHz frequency band.

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