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を共同で実施した、広島大学(当時含む)の藤島実教授、吉田毅准教授、天川修平准教授、片山光亮先生、高野恭弥先生、李尚嘩先生、日本電信電話株式会社の関係皆様、富士通株式会社の関係皆様、パナソニック株式会社の関係皆様に感謝いたします。また、NICTで本研究にご協力いただいた稲垣惠三主任研究員、菅野敦史プランニングマネージャー、沢田浩和主任研究員、関根徳彦室長、諸橋功プランニングマネージャー、藤井勝巳主任研究員、李可人主任研究員に感謝いたします。【参考文献【1https://mentor.ieee.org/802.15/dcn/13/15-13-0130-01-0thz-launching-a-study-group-on-thz.pdf2Report ITU-R SM.2352 - Technology trends of active services in the band above 275 GHz 2015.3TG3d Applications Requirements Document (ARD), IEEE P802.15 Work-ing Group for Wireless Personal Area Networks, IEEE 802.15 Doc Number 14/0304r16.4AMATERASU, https://smiles-p6.nict.go.jp/thz/jp/decay.html5H.-J. Song, K. Ajito, A. Hirata, A. Wakatsuki, Y. Muramoto, T. Furuta, N. Kukutsu, T. Nagatsuma, and Y. Kado, “8 Gbp swireless data trans-mission at 250 GHz band,” Electron. Lett., vol.45, no.22, pp.1121–1122, Oct. 2009.6S. Koenig, D. Lopez-Diaz, J. Antes, F. Boes, R. Henneberger, A. Leuther, A. Tessmann, R. Shimogrow, D. Hillerkuss, R. Palmer, T. Zwick, C. Koosl, W. Freude, O. Ambacher, J. Leutholk, and I. Kallfass, “Wireless sub-THz communication system with high data rate,” Nature Photonics, vol.7, pp.977–981, 2013.7T. Nagatsuma, S. Horiguchi, Y. Minamide, Y. Yoshimizu, S. Hisatake, S. Kuwano, N. Yoshimoto, J. Terada, and H. Takahashi, “Terahertz wire-less communications based on photonics technologies,” Opt. Express, vol.21, no.20, pp.23736–23747, Sept. 2013.8A. Kanno, “Advanced photonics technology for 1-THz wireless com-municaiotn,”2017 CLEO-PR, OECC and PGC, Aug. 2017.9総務省「電波資源拡大のための研究開発の実施」, http://www.tele.soumu.go.jp/j/sys/fees/purpose/kenkyu/10H. Song, T. Kosugi, H. Hamada, T. Tajima, A. El Moutaouaki, M. Yaita, K. Kawano, T. Takahashi, Y. Nakasha, N. Hara, K. Fujii, I. Watanabe, and A. Kasamatsu, “Demonstraion of 20-Gbps Wireless Data Transmis-sion at 300 GHz for KIOSK Instant Data Downloading Applications with InP MMICs,” Int. Microwabe Symp., WEIF2, May 2016.11総務省「電波資源拡大のための研究開発」第9回成果発表会,http://www.soumu.go.jp/menu_news/s-news/01kiban09_02000202.html12S. Hara, K. Katayama, K. Takano, R. Dong, I. Watanabe, N. Sekine, A. Kasamatsu, T. Yoshida, S. Amakawa, and M. Fujishima, “A 32Gbit/s 16QAM CMOS Receiver in 300GHz Band,” IEEE International Micro-wave Symposium (IMS2017), pp.1–4, 2017.13S. Hara, K. Katayama, K. Takano, R. Dong, I. Watanabe, N. Sekine, A. Kasamatsu, T. Yoshida, S. Amakawa, and M. Fujishima, “32-Gbit/s CMOS Receivers in 300GHz Band,” IEICE Trans. Electronics, 101-C, no.7, pp.464–471, 2018.14K. Katayama, K. Takano, S. Amakawa, S. Hara, A. Kasamatsu, K. Mizuno, K. Takahashi, T. Yoshida, and M. Fujishima, “A 300 GHz CMOS transmitter with 32-QAM 17.5 Gb/s/ch capability over six chan-nels,” IEEE J. Solid-State Circuits, vol.51, no.12, pp.3037–3048, Dec. 2016.15K. Takano, S. Amakawa, K. Katayama, S. Hara, R. Dong, A. Kasamatsu, I. Hosako, K. Mizuno, K. Takahashi, T. Yoshida, and M. Fujishima, “A 105Gb/s 300GHz CMOS transmitter,” Int. Solid-State Circuits Conf., pp.308–309, Feb. 2017.16S. Lee, R. Dong, T. Yoshida, S. Amakawa, S. Hara, A. Kasamatsu, J. Sato, and M. Fujishima, “An 80Gb/s 300GHz-Band Single-Chip CMOS Transceiver,” IEEE International Solid-State Circuits Conference (ISSCC), 2019.17S. Lee, S. Hara, T. Yoshida, S. Amakawa, R. Dong, A. Kasamatsu, J. Sato, and M. Fujishima, “An 80Gb/s 300GHz-Band Single-Chip CMOS Transceiver,” IEEE J. Solid-State Circuits, vol.54, no.12, pp.3577–3588, 2019.18報道発表「毎秒80ギガビットのデータ伝送を可能にするシリコンCMOS集積回路を用いた300ギガヘルツ帯ワンチップトランシーバの開発に成功」, https://www.nict.go.jp/press/2019/02/19-1.html, 2019年2月19日19N. Masuda. “Development Activity of 0.1/0.3 THz Power Module,” En-ergy Material Nanotechnology (EMN) Meeting on Terahertz 2017, Ho-nolulu, April 2017.20増田則夫,吉田満,岡本耕治,関根徳彦,菅野敦史,寳迫巌,“テラヘルツ波電力モジュール,”MWE2017ダイジェスト,TH3A-3,2017年11月21Radio Regulations, Footnote 5.565(https://www.itu.int/pub/R-REG-RR/en等から入手可) 2016.22Resolution 767 (WRC-15), "Studies towards an identification for use by administrations for land-mobile and fixed services applications operat-ing in the frequency range 275–450 GHz” 2015.23Report ITU-R F.2416-0, “Technical and operational characteristics and applications of the point-to-point fixed service applications operating in the frequency band 275–450 GHz” 2017.24Report ITU-R M.2417-0, “Technical and operational characteristics of land-mobile service applications in the frequency range 275–450 GHz” 2017.25Recommendation ITU-R P.1238-9, “Propagation data and prediction methods for the planning of indoor radiocommunication systems and radio local area networks in the frequency range 300 MHz to 100 GHz” 2017.26Report ITU-R SM.2450-0, “Sharing and compatibility studies between land-mobile, fixed and passive services in the frequency range 275–450 GHz” 2019.27World Radiocommunication Conference 2019 (WRC-19) Final Acts28IEEE Std 802.15.3d-2017 (Amendment to IEEE Std 802.15.3-2016 as amended by IEEE Std 802.15.3e-2017), “IEEE Standard for High Data Rate Wireless Multi-Media Networks Amendment 2: 100 Gb/s Wireless Switched Point-to-Point Physical Layer,” https://standards.ieee.org/standard/802.15.3d-2017.html笠松章史 (かさまつ あきふみ)未来ICT研究所フロンティア創造総合研究室上席研究員博士(工学)ミリ波・テラヘルツ無線技術、ミリ波・テラヘルツ電子デバイス原 紳介 (はら しんすけ)未来ICT研究所フロンティア創造総合研究室主任研究員博士(理学)ミリ波・テラヘルツ波集積回路、ミリ波・テラヘルツ波電子デバイス董 鋭冰 (どん るいびん)未来ICT研究所フロンティア創造総合研究室研究員博士(工学)ミリ波・テラヘルツ集積回路64   情報通信研究機構研究報告 Vol.66 No.2 (2020)3 超高周波ICT基盤技術  —素子から回路まで—

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