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 * Overview of KAGRA : (2) Noise Budget
   PWT leaders: Kazuhiro Yamamoto, Keiko Kokeyama [[https://www.overleaf.com/project/5da539402a3f820001ef1b6f|Overleaf]]
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 * Overview of KAGRA : (7) Future plans
   PWT leader: Sadakazu Haino [[https://www.overleaf.com/project/5d9fdd83bb7b1d0001acb3f4|Overleaf]]

 * Effects of lightning strokes for underground gravitational wave observatories
   PWT leader: Tatsuki Washimi
   [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=12426|JGW-P2112426]]		  * IOO paper in preparation
   PWT leader: Keiko Kokeyama [[https://www.overleaf.com/read/ykdbdghvdsnc|Overleaf]]
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 * Overview of KAGRA : (2) Noise Budget
  * PWT leaders: Kazuhiro Yamamoto, Keiko Kokeyama, Tatsuki Washimi [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=13405|JGW-P2113405]]
  * [[https://arxiv.org/abs/2203.07011]]

 * The current status and future prospects of KAGRA, the large-scale cryogenic gravitational wave telescope built in the Kamioka underground
    * T.Ushiba, M.Nakano, T.Washimi
    * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=13549|JGW-P2113549]]


== Accepted Papers ==

<<Anchor(Journal)>>
== Journal Papers ==
 * Application of the Hilbert-Huang transform for analyzing standing-accretion-shock-instability induced gravitational waves in a core-collapse supernova
  * M. Takeda, Y. Hiranuma, N. Kanda ,K. Kotake, T. Kuroda, R. Negishi, K. Oohara, K. Sakai, Y. Sakai, T. Sawada, H. Takahashi, S. Tsuchida, Y. Watanabe, T. Yokozawa
  * Physical Review D 104, 084063 (2021) [[https://doi.org/10.1103/PhysRevD.104.084063]]

 * Local Hurst exponent computation of data from triaxial seismometers monitoring KAGRA
  * A. Longo, S. Bianchi, W. Plastinao, K. Miyo, T. Yokozawa, T. Washimi, A. Araya
  * Pure and Applied Geophysics volume 178, pages3461–3470 (2021) [[https://doi.org/10.1007/s00024-021-02810-2]]

 * The KAGRA underground environment and lessons for the Einstein Telescope
  * F. Badaracco, C. D. Rossi, I. Fiori, J. Harms, K. Miyo, F. Paoletti, T. Tanaka, T. Washimi, T. Yokozawa
  * Phys. Rev. D 104, 042006 (2021) [[https://doi.org/10.1103/PhysRevD.104.042006]]

 * Effects of lightning strokes on underground gravitational waves observatories
  * T. Washimi, T. Yokozawa, M. Nakano, T. Tanaka, K. Kaihotsu, Y. Mori, T. Narita
  * JINST 16 P07033 (2021) https://doi.org/10.1088/1748-0221/16/07/P07033
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   PWT leader: Tatsuki Washimi [[https://ja.overleaf.com/project/5f51878b1e41b00001893ac7|Overleaf]],
   [[https://arxiv.org/abs/2012.09294|arXiv:2012.09294]],
   submitted to CQG

== Accepted Papers ==

 * Overview of KAGRA : (3) Calibration, detector characterization, physical environmental monitors, and the geophysics interferometer
  * PWT leaders: Takahiro Yamamoto, Yuki Inoue, Takaaki Yokozawa
  * [[https://www.overleaf.com/project/5d9fe000bb7b1d0001acb4ca|Overleaf]]
  * accepted for publication in PTEP
  * [[https://arxiv.org/abs/2009.09305|arXiv2009/09305]]
  * 10.1093/ptep/ptab018		   * Tatsuki Washimi, Takaaki Yokozawa, Taiki Tanaka2, Yosuke Itoh, Jun'ya Kume, and Jun'ichi Yokoyama
  * Class. Quantum Grav. 38 125005 (2021); https://orcid.org/0000-0001-5792-4907

 * High performance thermal link with small spring constant for cryogenic applications
  * Tomohiro Yamada, Takayuki Tomaru, Toshikazu Suzuki, Takafumi Ushiba, Nobuhiro Kimura, Suguru Takada, Yuki Inoue, Takaaki Kajita
  * Cryogenics 116 (2021) 103280; https://www.sciencedirect.com/science/article/pii/S0011227521000382

 * Cryogenic suspension design for a kilometer-scale gravitational-wave detector
  * Takafumi Ushiba, Tomotada Akutsu, Sakae Araki, Rishabh Bajpai, Dan Chen, Kieran Craig, Yutaro Enomoto, Ayako Hagiwara, Sadakazu Haino, Yuki Inoue, Kiwamu Izumi, Nobuhiro Kimura, Rahul Kumar, Yuta Michimura, Shinji Miyoki, Iwao Murakami, Yoshikazu Namai, Masayuki Nakano, Masatake Ohashi, Koki Okutomi, Takaharu Shishido, Ayaka Shoda, Kentaro Somiya, Toshikazu Suzuki, Suguru Takada, Masahiro Takahashi, Ryutaro Takahashi, Shinichi Terashima, Takayuki Tomaru, Flavio Travasso, Ayako Ueda, Helios Vocca, Tomohiro Yamada, Kazuhiro Yamamoto, and Simon Zeidler
  *Class. Quantum Grav. 38 (2021) 085013; https://doi.org/10.1088/1361-6382/abe9f3
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  * accepted for publication in CQG


<<Anchor(Journal)>>
== Journal Papers ==		   * Class. Quant. Grav. 38 (2020) 065011
  * https://iopscience.iop.org/article/10.1088/1361-6382/abd922

 * Overview of KAGRA: Calibration, detector characterization, physical environmental monitors, and the geophysics interferometer
  * KAGRA collaboration (author-list 2018 + 2019)
  * PWT leaders: Takahiro Yamamoto, Yuki Inoue, Takaaki Yokozawa
  * Prog. Theor. Exp. Phys. (2021) Volume 2021, Issue 5, May 2021, 05A101 https://doi.org/10.1093/ptep/ptab018
  * [[https://arxiv.org/abs/2009.09305|arXiv2009/09305]]
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  * Prog. Theor. Exp. Phys. (2020) ptaa125 https://doi.org/10.1093/ptep/ptaa125 (page number not fixed)   * Prog. Theor. Exp. Phys. (2021) Volume 2021, Issue 5, May 2021, 05A101 https://doi.org/10.1093/ptep/ptaa125
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  * Prog. Theor. Exp. Phys. (2020) ptaa120 https://doi.org/10.1093/ptep/ptaa120 (page number not fixed)   * Prog. Theor. Exp. Phys. (2021) Volume 2021, Issue 5, May 2021, 05A103 https://doi.org/10.1093/ptep/ptaa120
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 *[[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=12588|Low-Vibration Conductive Cooling of KAGRA Cryogenic Mirror Suspension]]
  * Tomohiro Yamada, University of Tokyo (2021, FY2020)
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  * Kunihiko Hasegawa, University of Tokyo (2020)   * Kunihiko Hasegawa, University of Tokyo (2020, FY2019)
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  * Yutaro Enomoto, University of Tokyo (2020)   * Yutaro Enomoto, University of Tokyo (2020, FY2019)
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  * Kouseki Miyo, University of Tokyo (2020)   * Kouseki Miyo, University of Tokyo (2020, FY2019)

 * Control scheme for a Fabry–Pérot type interferometric space gravitational wave antenna”
  * Koji Nagano, The University of Tokyo (2020, FY2019)

 * “????”
  * Yoshinori Fujii, The University of Tokyo (2020, FY2019)
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  * 酒井一樹, 長岡技術科学大学 (2018)   * 酒井一樹, 長岡技術科学大学 (2018, FY2017)
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  * Hirotaka Yuzurihara, Osaka City Unversity (2017)   * Hirotaka Yuzurihara, Osaka City Unversity (2018, FY2017)
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  * Takahiro Yamamoto, Osaka City Unversity (2016)   * Takahiro Yamamoto, Osaka City Unversity (2017, FY2016)
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  * Takanori Sekiguchi, University of Tokyo (2015)   * Takanori Sekiguchi, University of Tokyo (2016, FY2015)
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  * Dan Chen, University of Tokyo (2015)   * Dan Chen, University of Tokyo (2015, FY2014)
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  * Yusuke Sakakibara, University of Tokyo (2015)   * Yusuke Sakakibara, University of Tokyo (2015, FY2014)
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  * Noriaki Ohmae, University of Tokyo (2011)   * Noriaki Ohmae, University of Tokyo (2011, FY2010)
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  * Kazuhiro Agatsuma, University of Tokyo (2010)   * Kazuhiro Agatsuma, University of Tokyo (2010, FY2009)
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 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=14013|大型低温重力波望遠鏡における鏡反射膜の機械的散逸測定装置の高精度化]]
  * 中山 遥太, 富山大学 (2022, FY2021)

 * KAGRAのレーザー強度安定化システムの構築
  * 山下 勘太, 富山大学 (2022, FY2021)

 * 事前分布にラプラス分布を仮定したベイズ深層学習による重力波解析の検討
  * 塩田紘平, 長岡技術科学大学, (2022, FY2021)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=13829|大型重力波望遠鏡KAGRAにおけるインプットモードクリーナーの鏡の角度制御]]
  * Chiaki Hirose, Niigata University (2022, FY2021)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=13875|重力波望遠鏡 KAGRA の主干渉計雑音の ガウス性・安定性評価]]
  * Nozomi Morisue, Osaka City University (2022, FY2021)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=13725|独立成分分析の KAGRA 観測データへの適用]]
  * Yuichiro Kobayashi, Osaka City University (2022, FY2021)

 * Investigation of Frequency Evolution of Gravitational waves from Core Collapse Supernova by Hilbert-Huang Transform
  * L. Malith M. De Silva, 長岡技術科学大学, (2021, FY2021)(8月修了)

 * 大型低温重力波望遠鏡KAGRAのための深層学習を用いた突発性雑音の分類 Transform
  * 上島元, 長岡技術科学大学, (2021, FY2020)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=12788|重力波望遠鏡KAGRAにおけるレーザーの輻射圧を用いた較正]]
  * 伊藤光希, 富山大学 (2021, FY2020)

 * 大型重力波望遠鏡KAGRAにおけるパラメトリック不安定性の評価
  * 開発 輝一, 富山大学 (2021, FY2020)

 * 重力波望遠鏡KAGRAにおけるレーザー強度安定化システムの改良およびビームジッター効果の考察
  * 黒宮 勇樹, 富山大学 (2021, FY2020)

 * 低温重力波望遠鏡KAGRAのための鏡の反射膜の機械的散逸測定
  * 森 有紀乃, 富山大学 (2021, FY2020)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=12440|重力波望遠鏡KAGRAにおける極低温鏡懸架システムの角度調整機構の開発]]
  * Takumi Nishimoto, University of Tokyo (2021, FY2020)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=11094|Hilbert-Huang変換を用いた重力波解析 -大きなノイズを加える場合のEnsemble Empirical Mode DecompositionとInstrinsic Mode Functionsの直交化-]]
  * Ryo Negishi, Niigata University (2020, FY2019)
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  * Mei Takeda, Niigata University (2020)   * Mei Takeda, Niigata University (2020, FY2019)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=12605|重力波望遠鏡 KAGRA における補助ロックシステムの開発]]
  * 杉本良介, 富山大学 (2020, FY2019)

 * 重力波望遠鏡KAGRAにおけるレーザー波長を用いた重力波信号の較正
  * 吉岡 聡也, 富山大学 (2020, FY2019)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=10783|重力波望遠鏡KAGRAにおける透過光モニターを用いた腕共振器鏡の角度制御システムの開発]]
  * Kenta Tanaka, The University of Tokyo (2020, FY2019)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=11456|独立成分解析によるKAGRAデータの非ガウス雑音の除去]]
  * Junya Kume, The University of Tokyo (2020, FY2019)
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  * Taiki Tanaka, University of Tokyo (2020)   * Taiki Tanaka, University of Tokyo (2020, FY2019)
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  * Kohei Yamamoto, University of Tokyo (2019)   * Kohei Yamamoto, University of Tokyo (2019, FY2018)

 * 重力波望遠鏡KAGRAにおけるレーザー強度安定化システムの構築
  * 北澤 秀昌, 富山大学 (2019, FY2018)

 * 重力波望遠鏡KAGRAのレーザー強度安定化システムの開発
  * 酒本 春人, 富山大学 (2019, FY2018)

 * 重力波望遠鏡KAGRAにおけるグリーンレーザーを用いた腕共振器長制御システムの開発
  * 横川 和也, 富山大学 (2019, FY2018)
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  * Yu-Kuang Chu, National Taiwan Normal University (2018)   * Yu-Kuang Chu, National Taiwan Normal University (2018, FY2018)
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  * Bin-Hua Hsieh, University of Tokyo (2018)   * Bin-Hua Hsieh, University of Tokyo (2018, FY2018)
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  * Tatsuhiko Morozumi, University of Tokyo (2018)   * Tatsuhiko Morozumi, University of Tokyo (2018, FY2017)

 * Vibration Analysis of Cryostat on KAGRA Site
  * Toshiro Ochi, The University of Tokyo (2018, FY2017)
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  * Tomohiro Yamada, University of Tokyo (2018)   * Tomohiro Yamada, University of Tokyo (2018, FY2017)
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  * Shin Kirii, University of Tokyo (2018)   * Shin Kirii, University of Tokyo (2018, FY2017)
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  * Tsuyoshi Kaji, Osaka City University (2018)   * Tsuyoshi Kaji, Osaka City University (2018, FY2017)

 * 重力波望遠鏡KAGRA におけるGreen レーザーシステムの開発
  * 蒲原尚吾, 富山大学 (2018, FY2017)

 * 重力波望遠鏡KAGRAのレーザー強度安定化システムの開発
  * 古畑貴行, 富山大学 (2018, FY2017)

 * 大型低温重力波望遠鏡KAGRA用超低損失鏡への付着微粒子による光損失の評価法の開発
  * Kunihiko Hasegawa, The University of Tokyo (2017, FY2016)

 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=6082|重力波望遠鏡KAGRAのための地殻変動モニターの開発]]
  * Kohseki Mio, The University of Tokyo (2017, FY2016)
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  * Koji Nagano, University of Tokyo (2017)   * Koji Nagano, University of Tokyo (2017, FY2016)
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  * Yutaro Enomoto, University of Tokyo (2017)

 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/master_atsuta.pdf|ブラックホールリングダウンからの重力波における高調波を含めた解析]]
  * Sho Atsuta, Tokyo Institute of Technology (2017)

 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/master_kataoka.pdf|非線形光学効果を用いた次世代重力波検出器の要素技術開発]]
  * Yuu Kataoka, Tokyo Institute of Technology (2017)

 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/mthesis_yano_v7.pdf|KAGRA 用アウトプットモードクリーナーのデザイン研究およびプロトタイプ制御実験]]
  * Kazushiro Yano, Tokyo Institute of Technology (2016)

 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/Kato_Thesis.pdf|重力波望遠鏡における光ばねと非線形結晶を用いた信号増幅器のデザインとその検証]]
  * Junpei Kato, Tokyo Institute of Technology (2015)

 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/Kumeta_Thesis.pdf|重力波検出器KAGRA の感度向上に向けたアウトプットモードクリーナーの開発]]
  * Ayaka Kumeta, Tokyo Institute of Technology (2015)

 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/UedaThesis.pdf|干渉計型重力波検出器における感度向上のための要素技術開発]]
  * Shinichiro Ueda, Tokyo Institute of Technology (2014)

 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/Saito_Thesis.pdf|非線形光学素子を用いた重力波信号の増幅]]
  * Nana Saito, Tokyo Institute of Technology (2014)		   * Yutaro Enomoto, University of Tokyo (2017, FY2016)

 * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/master_atsuta.pdf|ブラックホールリングダウンからの重力波における高調波を含めた解析]]
  * Sho Atsuta, Tokyo Institute of Technology (2017, FY2016)

 * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/master_kataoka.pdf|非線形光学効果を用いた次世代重力波検出器の要素技術開発]]
  * Yuu Kataoka, Tokyo Institute of Technology (2017, FY2016)

 * KAGRAで用いるレーザー強度安定化技術の開発
  * 杉本 裕介, 富山大学 (2017, FY2016)

 * KAGRA試験観測データを用いた重力波データ解析における Hilbert-Huang変換の有効性の検証
  * 植木聡史, 長岡技術科学大学, (2017, FY2016)

 * 大型低温重力波望遠鏡KAGRAにおける制御システムの開発
  * 佐々木幸次, 長岡技術科学大学, (2017, FY2016)

 * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/mthesis_yano_v7.pdf|KAGRA 用アウトプットモードクリーナーのデザイン研究およびプロトタイプ制御実験]]
  * Kazushiro Yano, Tokyo Institute of Technology (2016, FY2015)

 * ???
  * 加川智大, 富山大学 (2016, FY2015)

 * 重力波検出器KAGRA のサファイア懸架系の熱雑音に関する研究
  * Hiroki Tanaka, The University of Tokyo (2015, FY2014)

 * 重力波検出器KAGRA の低温懸架系の開発
  * Miyamoto, The University of Tokyo (2015, FY2014)

 * 重力波検出器KAGRA におけるクラックリング雑音低減に向けた実験装置の開発
  * Yamanaka, The University of Tokyo (2015, FY2014)

 * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/Kato_Thesis.pdf|重力波望遠鏡における光ばねと非線形結晶を用いた信号増幅器のデザインとその検証]]
  * Junpei Kato, Tokyo Institute of Technology (2015, FY2014)

 * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/Kumeta_Thesis.pdf|重力波検出器KAGRA の感度向上に向けたアウトプットモードクリーナーの開発]]
  * Ayaka Kumeta, Tokyo Institute of Technology (2015, FY2014)

 * 重力波検出器KAGRA のための量子雑音低減技術の開発における光共振器の光学機械的制御
  * Masayuki Nakano, The University of Tokyo (2015, FY2014)

 * 重力波検出器における輻射圧雑音低減の研究に向けた防振システムの設計・開発
  * Nishimura, The University of Tokyo (2014, FY2013)

 * 重力波検出器における量子雑音最適化のための鏡の角度揺らぎ制御に関する研究
  * Konisho, The University of Tokyo (2014, FY2013)

 * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/UedaThesis.pdf|干渉計型重力波検出器における感度向上のための要素技術開発]]
  * Shinichiro Ueda, Tokyo Institute of Technology (2014, FY2013)

 * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/Saito_Thesis.pdf|非線形光学素子を用いた重力波信号の増幅]]
  * Nana Saito, Tokyo Institute of Technology (2014, FY2013)
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  * Yusuke Sakakibara, University of Tokyo (2012)   * Yusuke Sakakibara, University of Tokyo (2012, FY2020)
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  * Takanori Sekiguchi, University of Tokyo (2012)   * Takanori Sekiguchi, University of Tokyo (2012, FY2011)
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 * [[https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=13973|重力波望遠鏡KAGRAにおける重力波信号の較正に用いる積分球の性能評価]]
  * Kazuma Matsunaga, Toyama University (2021)
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 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/kasuya_B_thesis02172120.pdf|重力波検出器KAGRAの出力モードクリーナの姿勢制御]]  * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/kasuya_B_thesis02172120.pdf|重力波検出器KAGRAの出力モードクリーナの姿勢制御]]
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 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/yaginuma.pdf|非線形光学結晶挿入型重力波検出器の応答と不安定性]]  * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/yaginuma.pdf|非線形光学結晶挿入型重力波検出器の応答と不安定性]]
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 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/Atsuta_Thesis.pdf|神岡におけるシューマン共振の測定]]  * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/Atsuta_Thesis.pdf|神岡におけるシューマン共振の測定]]
Line 444: Line 589:
 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/Kataoka_Thesis.pdf|重力波検出器で使う制御用回路の検査機構の開発とその応用]]  * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/Kataoka_Thesis.pdf|重力波検出器で使う制御用回路の検査機構の開発とその応用]]
Line 447: Line 592:
 * [[http://www.gravity.ircs.titech.ac.jp/doc/thesis/Yano_Thesis.pdf|神岡における環境雑音の測定および非線形光学素子を用いた信号増幅]]  * [[http://www.gravity.phys.titech.ac.jp/doc/thesis/Yano_Thesis.pdf|神岡における環境雑音の測定および非線形光学素子を用いた信号増幅]]
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 * [[http://www.gravity.ircs.titech.ac.jp/thesis.html|List of theses from Somiya Group at Titech]]
 * [[http://www.gw.hep.osaka-cu.ac.jp/thesis/index.html|List of theses from Kanda Group at OCU]]		  * [[http://www.gravity.phys.titech.ac.jp/thesis.html|List of theses from Somiya Group at Titech]]
 * [[https://www.gw.sci.osaka-cu.ac.jp/research/thesis/|List of theses from Kanda Group at OMU]]

KAGRA Publications

List of Journal papers, PhD theses, Master theses, and Graduation theses related to KAGRA research.

in preparation

For accessing overleaf, please contact to paper-writing team (PWT) leaders. If you plan to begin a new project with overleaf (online LaTeX sharing editor), contact to kagra-overleaf_at_icrr.u-tokyo.ac.jp

  • Overview of KAGRA : (4) Data transfer and management
  • Overview of KAGRA : (5) Data analysis methods
  • IOO paper in preparation

Submitted Papers

  • Overview of KAGRA : (2) Noise Budget
  • The current status and future prospects of KAGRA, the large-scale cryogenic gravitational wave telescope built in the Kamioka underground

Accepted Papers

Journal Papers

PhD Thesis

Master Thesis

Graduation Thesis

KAGRA/Publications (last edited 2024-07-16 18:02:47 by tatsuki.washimi)