The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. ex. Some numerals are expressed as "XNUMX".
Copyrights notice
The original paper is in English. Non-English content has been machine-translated and may contain typographical errors or mistranslations. Copyrights notice
Cet article présente un filtre coupe-bande à résonateur à anneau divisé (SRR) dans la bande de 120 GHz dont la perte d'insertion peut être contrôlée en couplant un autre substrat à motif de réseau. Le filtre coupe-bande et le substrat à motif en treillis SRR sont composés d'un substrat de quartz de 200 µm d'épaisseur et de motifs en or de 5 µm d'épaisseur. S21 du filtre coupe-bande SRR est de -37.8 dB et sa bande passante de -10 dB est de 115 à 130 GHz. S21 du filtre coupe-bande SRR passe à -4.1 dB à 125 GHz en disposant le substrat à motif de réseau à proximité immédiate du filtre à bande d'arrêt SRR, car le couplage entre le SRR et le motif de réseau se produit lorsque le SRR et le motif de réseau sont opposés à proximité immédiate. Il a été constaté qu'une transmission de données de 10 Gbit/s peut être obtenue en plaçant le substrat à motif de treillis juste au-dessus du filtre coupe-bande SRR avec une épaisseur d'espacement de 50 µm, même si la transmission de données est impossible lorsque seul le filtre coupe-bande SRR est inséré entre l'émetteur. et le récepteur.
Koichiro ITAKURA
Chiba Institute of Technology
Akihiko HIRATA
Chiba Institute of Technology
Masato SONODA
Osaka University
Taiki HIGASHIMOTO
Osaka University
Tadao NAGATSUMA
Osaka University
Takashi TOMURA
Tokyo Institute of Technology
Jiro HIROKAWA
Tokyo Institute of Technology
Norihiko SEKINE
National Institute of Information and Communications Technology (NICT)
Issei WATANABE
National Institute of Information and Communications Technology (NICT)
Akifumi KASAMATSU
National Institute of Information and Communications Technology (NICT)
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Koichiro ITAKURA, Akihiko HIRATA, Masato SONODA, Taiki HIGASHIMOTO, Tadao NAGATSUMA, Takashi TOMURA, Jiro HIROKAWA, Norihiko SEKINE, Issei WATANABE, Akifumi KASAMATSU, "Control of 120-GHz-Band Split Ring Resonator Filter by Coupling Lattice Pattern Substrate" in IEICE TRANSACTIONS on Electronics,
vol. E104-C, no. 3, pp. 102-111, March 2021, doi: 10.1587/transele.2019ECP5052.
Abstract: This paper presents a 120-GHz-band split ring resonator (SRR) bandstop filter whose insertion loss can be controlled by coupling another lattice pattern substrate. The SRR bandstop filter and lattice pattern substrate is composed of 200-µm-thick quartz substrate and 5-µm-thick gold patterns. S21 of the SRR bandstop filter is -37.8 dB, and its -10-dB bandwidth is 115-130 GHz. S21 of the SRR bandstop filter changes to -4.1 dB at 125 GHz by arranging the lattice pattern substrate in close proximity to the SRR stopband filter, because coupling between the SRR and the lattice pattern occurs when the SRR and lattice pattern are opposed in close proximity. It was found that 10 Gbit/s data transmission can be achieved by setting the lattice pattern substrate just above the SRR bandstop filter with a spacer thickness of 50 µm, even though data transmission is impossible when only the SRR bandstop filter is inserted between the transmitter and the receiver.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/transele.2019ECP5052/_p
Copier
@ARTICLE{e104-c_3_102,
author={Koichiro ITAKURA, Akihiko HIRATA, Masato SONODA, Taiki HIGASHIMOTO, Tadao NAGATSUMA, Takashi TOMURA, Jiro HIROKAWA, Norihiko SEKINE, Issei WATANABE, Akifumi KASAMATSU, },
journal={IEICE TRANSACTIONS on Electronics},
title={Control of 120-GHz-Band Split Ring Resonator Filter by Coupling Lattice Pattern Substrate},
year={2021},
volume={E104-C},
number={3},
pages={102-111},
abstract={This paper presents a 120-GHz-band split ring resonator (SRR) bandstop filter whose insertion loss can be controlled by coupling another lattice pattern substrate. The SRR bandstop filter and lattice pattern substrate is composed of 200-µm-thick quartz substrate and 5-µm-thick gold patterns. S21 of the SRR bandstop filter is -37.8 dB, and its -10-dB bandwidth is 115-130 GHz. S21 of the SRR bandstop filter changes to -4.1 dB at 125 GHz by arranging the lattice pattern substrate in close proximity to the SRR stopband filter, because coupling between the SRR and the lattice pattern occurs when the SRR and lattice pattern are opposed in close proximity. It was found that 10 Gbit/s data transmission can be achieved by setting the lattice pattern substrate just above the SRR bandstop filter with a spacer thickness of 50 µm, even though data transmission is impossible when only the SRR bandstop filter is inserted between the transmitter and the receiver.},
keywords={},
doi={10.1587/transele.2019ECP5052},
ISSN={1745-1353},
month={March},}
Copier
TY - JOUR
TI - Control of 120-GHz-Band Split Ring Resonator Filter by Coupling Lattice Pattern Substrate
T2 - IEICE TRANSACTIONS on Electronics
SP - 102
EP - 111
AU - Koichiro ITAKURA
AU - Akihiko HIRATA
AU - Masato SONODA
AU - Taiki HIGASHIMOTO
AU - Tadao NAGATSUMA
AU - Takashi TOMURA
AU - Jiro HIROKAWA
AU - Norihiko SEKINE
AU - Issei WATANABE
AU - Akifumi KASAMATSU
PY - 2021
DO - 10.1587/transele.2019ECP5052
JO - IEICE TRANSACTIONS on Electronics
SN - 1745-1353
VL - E104-C
IS - 3
JA - IEICE TRANSACTIONS on Electronics
Y1 - March 2021
AB - This paper presents a 120-GHz-band split ring resonator (SRR) bandstop filter whose insertion loss can be controlled by coupling another lattice pattern substrate. The SRR bandstop filter and lattice pattern substrate is composed of 200-µm-thick quartz substrate and 5-µm-thick gold patterns. S21 of the SRR bandstop filter is -37.8 dB, and its -10-dB bandwidth is 115-130 GHz. S21 of the SRR bandstop filter changes to -4.1 dB at 125 GHz by arranging the lattice pattern substrate in close proximity to the SRR stopband filter, because coupling between the SRR and the lattice pattern occurs when the SRR and lattice pattern are opposed in close proximity. It was found that 10 Gbit/s data transmission can be achieved by setting the lattice pattern substrate just above the SRR bandstop filter with a spacer thickness of 50 µm, even though data transmission is impossible when only the SRR bandstop filter is inserted between the transmitter and the receiver.
ER -