京都大学防災研究所年報 第65号 Aへ
To DPRI Annuals, No. 65 A
京都大学防災研究所年報 第65号 Cへ
To DPRI Annuals, No. 65 C
京都大学防災研究所年報 第65号 B
DPRI Annuals, No. 65 B
表紙 | |||||||
目次 | |||||||
宇治田原及び和束盆地における微動を用いた地盤構造調査 Microtremor Measurements in Ujitawara and Wazuka Basins, Kyoto, Japan | 1 | ||||||
浅野公之・岩田知孝・関口春子 Kimiyuki ASANO, Tomotaka IWATA and Haruko SEKIGUCHI | |||||||
宇治田原盆地,和束盆地,微動H/Vスペクトル比,微動アレイ探査 Ujitawara Basin, Wazuka Basin, microtremor H/V spectral ratio, microtremor array survey | |||||||
建物のパッシブ振動制御の極配置法に基づく統一的理解 Unified Understanding of Passive Vibration Control for Buildings Based on Pole Allocation | 14 | ||||||
池田芳樹・松本祐輝 Yoshiki IKEDA and Yuki MATSUMOTO | |||||||
建物,パッシブ振動制御,統一的理解,極配置,性能規定型設計 building, passive vibration control, unified understanding, pole allocation, performance-based design | |||||||
地殻変動データの可視化システムの開発 Development of Crustal Deformation Visualization System | 30 | ||||||
千葉尭・山邉悠太・髙橋温志 Takashi CHIBA, Yuta YAMABE and Atsushi TAKAHASHI | |||||||
地殻変動,可視化,全球測位衛星システム,活断層,Unity crustal deformation, visualization, Global Navigation Satellite System, active fault, Unity | |||||||
姶良カルデラ下の地震波速度構造のイメージング Seismic Velocity Imaging below Aira Caldera | 35 | ||||||
為栗健・八木原寛・筒井智樹・井口正人 Takeshi TAMEGURI, Hiroshi YAKIWARA, Tomoki TSUTSUI and Masato IGUCHI | |||||||
姶良カルデラ,地震波速度構造,マグマ溜り Aira caldera, seismic velocity structure, magma chamber | |||||||
姶良カルデラ周辺の地盤変動に関する有限要素法モデルを用いた圧力源形状の検討 Investigation of Pressure Source Geometries Using Finite Element Method for Ground Deformation at Around Aira Caldera | 42 | ||||||
味喜大介・筒井智樹・井口正人 Daisuke MIKI, Tomoki TSUTSUI and Masato IGUCHI | |||||||
姶良カルデラ,地盤変動,圧力源形状 Aira caldera, ground deformation, pressure source geometries | |||||||
ピラー直結型海底地盤変動観測装置に関する測位実験 Experimental Assessments of Precise Positioning with Using GNSS on a Pillar-coupled Seabed Electric Benchmark System | 48 | ||||||
筒井智樹・味喜大介・井口正人 Tomoki TSUTSUI, Daisuke MIKI, and Masato IGUCHI | |||||||
火山活動監視, 火山性地殻変動, 海底地盤変動観測,GNSS, カルデラ火山 Volcano monitoring, Volcanic Ground Deformation,Seabed geodetic observations, Global Navigation Satellite System, Caldera Volcano | |||||||
桜島火山における繰り返し相対重力測定(2021年10月および2022年3月) Repeated Relative Gravity Measurements in Sakurajima Volcano (October 2021 and March 2022) | 67 | ||||||
風間卓仁・大柳 諒・山本圭吾・岡田和見・大島弘光・竹中悠亮・井口正人 Takahito KAZAMA, Ryo OYANAGI, Keigo YAMAMOTO, Kazumi OKADA, Hiromitsu OSHIMA, Yusuke TAKENAKA and Masato IGUCHI | |||||||
桜島火山,相対重力,質量移動,地殻変動,陸水重力擾乱 Sakurajima Volcano, relative gravity, mass redistribution, crustal deformation, hydrological gravity disturbance | |||||||
光学式ディスドロメータにより測定された桜島降灰粒子の解析 Analysis of Sakurajima Volcanic Ash Particles Measured with Optical Disdrometers | 77 | ||||||
真木雅之・井口正人 Masayuki MAKI and Masato IGUCHI | |||||||
桜島火山噴火,定量的降灰量推定,粒径分布,落下速度,レーダ,パーシベル Sakurajima volcanic eruption, quantitative ash fall estimation, particle size distribution, fall speed, radar, Parsivel | |||||||
諏訪之瀬島における空振観測から考える噴火ハザード Eruption Hazards Evaluated from Infrasound Observation at Suwanosejima Volcano | 97 | ||||||
井口正人・山田大志 Masato IGUCHI and Taishi YAMADA | |||||||
諏訪之瀬島火山,空振,火山岩塊,火山灰 Suwanosejima volcano, infrasound, volcanic bomb, volcanic ash | |||||||
初期構造異方性を有する多重せん断型非線形弾性体のupdated Lagrange法に基づく大変形定式化 Large Deformation Formulation Based on the Updated Lagrange Method for a Nonlinear Elastic Body within a Framework of Multiple Shear Mechanism Accounting for Inherent Anisotropy | 107 | ||||||
上田恭平・中原知洋・井川誠二 Kyohei UEDA, Tomohiro NAKAHARA and Seiji IGAWA | |||||||
初期構造異方性,非線形弾性体,多重せん断機構,幾何学的非線形性,updated Lagrange法 inherent anisotropy, nonlinear elastic body, multiple shear mechanism, geometrical nonlinearity, updated Lagrange method | |||||||
昭和28年有田川水害で発生した深層崩壊の地質地形学的素因について Geological and Geomorphological Causes of Deep-seated Catastrophic Landslides in the 1953 Aridagawa Disaster | 114 | ||||||
荒井紀之 Noriyuki ARAI | |||||||
有田川水害,深層崩壊,豪雨,地質,地形 Aridagawa disaster, deep-seated catastrophic landslide, heavy rainfall,geology, landform | |||||||
準地衡流モデルへの決定論的アンサンブルデータ同化 Deterministic Ensemble Data Assimilation for a Quasi-geostrophic Model | 126 | ||||||
榎本剛・中下早織 Takeshi ENOMOTO and Saori NAKASHITA | |||||||
アンサンブルカルマンフィルタ,局所化,荒川ヤコビアン,多重格子法 ensemble Kalman filter, localization, Arakawa Jacobian, multigrid solver | |||||||
秋季における大気境界層での風速変動 Wind Variation in the Atmospheric Boundary Layer during Autumn Season | 134 | ||||||
堀口光章 Mitsuaki HORIGUCHI | |||||||
大気境界層,風速変動,乱流輸送,超音波風速計,ウィンドプロファイラ atmospheric boundary layer, wind variation, turbulent transfer, sonic anemometer, wind profiler | |||||||
ゲリラ豪雨のライフサイクル概念を考慮した定量的危険性予測手法の提案 Design of a Quantitative Risk Prediction Method Based on Life Cycle of Guerrilla-heavy Rainfall | 146 | ||||||
Hwayeon KIM・前川智寧・中北英一 Hwayeon KIM, Tomoyasu MAEKAWA and Eiichi NAKAKITA | |||||||
ゲリラ豪雨,ライフステージ,定量的危険性予測 Guerilla heavy rainfall, Life stage, Quantitative risk prediction | |||||||
LESを用いた波動が生起する 線状対流系の勃発メカニズムの解明 Outbreak Mechanism Identification of Line-Shaped Convective Systems Caused by Waves Using LES | 157 | ||||||
山口弘誠・河谷能幸・中北英一 Kosei YAMAGUCHI, Yoshiyuki KAWATANI and Eiichi NAKAKITA | |||||||
線状対流系,LES,山岳波 Line-shaped convective system, LES, mountain waves | |||||||
Fundamental Research on Water Vapor Inflow Path into the Back-building Convective System and its Relationship with Atmospheric Stability | 173 | ||||||
Yukari NAKA, Taiga KAMIYA and Eiichi NAKAKITA | |||||||
Back-building convective system, water vapor inflow path, atmospheric stability, global warming, water vapor flux, Baiu season | |||||||
メソアンサンブルデータを活用した線状降水帯発生予測手法の開発 Development of Line-shaped Rainband Prediction Method Utilizing Meso-ensemble Data | 199 | ||||||
山路昭彦・増田有俊・真中朋久・安部智彦・齋藤泰治・齊藤洋一 Akihiko YAMAJI, Aritoshi MASUDA, Tomohisa MANAKA, Tomohiko ABE, Yasuharu SAITO and Yoichi SAITO | |||||||
線状降水帯,メソアンサンブルデータ,豪雨災害,避難情報,降雨予測 line-shaped rainband, meso-ensemble data, heavy rain disaster, evacuation information, rainfall prediction | |||||||
Preliminary Investigation of Change of Snake Line Pattern Based on Clausius-Clapeyron Relation | 204 | ||||||
Ying-Hsin WU, Eiichi NAKAKITA and Akihiko YAMAJI | |||||||
Clausius-Clapeyron scaling, snake line, climate change, NHRCM | |||||||
京都府鴨川流域を対象にしたRRIモデルによる上流の水位再現性 Reproducibility of Water Level at Upstream Gauging Stations Using RRI Model for the Kamo River Basin, Kyoto Prefecture, Japan | 214 | ||||||
山本浩大・佐山敬洋・山路昭彦・小林哲也・大石直樹・下釜卓・関本大晟・近者敦彦 Kodai YAMAMOTO, Takahiro SAYAMA, Akihiko YAMAJI, Tetsuya KOBAYASHI, Naoki OISHI, Takashi SHIMOGAMA, Taisei SEKIMOTO and Atsuhiko KONJYA | |||||||
洪水,中小河川,降雨流出氾濫モデル flash flood, small-to-medium sized rivers, Rainfall-Runoff-Inundation model | |||||||
Capturing Atmospheric Signatures with Convolutional Neural Networks to Predict Occurrences of Rainfall Events | 222 | ||||||
Sunmin KIM, Tsuguaki SUZUKI and Yasuto TACHIKAWA | |||||||
Convolutional Neural Network, Rainfall Prediction, Atmospheric variables | |||||||
計算量を削減したRBF離散化手法の性能評価 Performance of the Sparse Gaussian RBF Method | 238 | ||||||
小笠原宏司・榎本剛 Koji OGASAWARA and Takeshi ENOMOTO | |||||||
動径基底関数, 浅水波モデル,疎行列 radial basis functions, shallow water model, sparse matrix | |||||||
2019 年台風第19 号の予報進路に対する海面水温と初期擾乱の影響 Influence of the Sea Surface Temperature and Initial Perturbations on the Track Forecast of Typhoon Hagibis (2019) | 241 | ||||||
中下早織 · 榎本剛· 黒木志洸 · 氏家将志 · 竹村和人 Saori NAKASHITA, Takeshi ENOMOTO, Yukihiro KUROKI, Masashi UJIIE and Kazuto TAKEMURA | |||||||
令和元年東日本台風,気象庁全球モデル,大気海洋相互作用,アンサンブル感度解析 Typhoon Hagibis (2019), JMA-GSM, Atmosphere-ocean interaction, Ensemble sensitivity analysis | |||||||
A Study on the Application of Flash Flood Guidance with Predicting the Risk Level of Guerrilla Heavy Rainfall | 254 | ||||||
Hwayeon KIM and Eiichi NAKAKITA | |||||||
Guerrilla heavy rainfall, Flash Flood Guidance, Rainfall-Runoff model | |||||||
Investigation of Mechanisms Analysis in the Transition from Single-cell to Multicell Thunderstorms Using X-band Polarimetric Radar Observation | 261 | ||||||
Fauziana AHMAD, Kosei YAMAGUCHI and Eiichi NAKAKITA | |||||||
single-cell, multicell, updraft, convergence, stretching of vortex tube, tilting of vortex tube | |||||||
新潟県における新雪密度とKバンド鉛直レーダーの観測 The Density of Newly Fallen Snow and K-band Vertical Radar Observation in Niigata Prefecture, Japan | 278 | ||||||
高見和弥・竃本倫平・鈴木賢士・山口弘誠・中北英一 Kazuya TAKAMI ,Rinpei KAMAMOTO, Kenji SUZUKI, Kosei YAMAGUCHI and Eiichi NAKAKITA | |||||||
降雪,新雪密度,レーダー Snowfall, The density of newly fallen snow, Radar | |||||||
XRAIN 立体観測データを用いた地形性降雨算定手法による短時間降雨予測に関する研究 Investigation On a Short-term Rainfall Prediction with Orographic Rainfall Model Using Volume Scanning Radar Data of XRAIN | 285 | ||||||
中渕遥平・中北英一 Yohei NAKABUCHI and Eiichi NAKAKITA | |||||||
列車運行,降雨予測,移流モデル,地形性降雨 Train operation, Rainfall prediction, Translation model, Orographic rainfall | |||||||
線状対流系の発生・発達におけるマルチフラクタル特性 -水蒸気フラックスと降水粒子分布の観点から- Multifractal Properties in Occurrence and Development of Linear Mesoscale Convective Systems: Characterized byWater Vapor Flux and Precipitation Particles Distribution | 298 | ||||||
大野哲之・山口弘誠・中北英一 Akiyuki ONO, Kosei YAMAGUCHI, and Eiichi NAKAKITA | |||||||
線状対流系,マルチフラクタル,水蒸気フラックス,降水粒子 linear Mesoscale Convective Systems, multifractal, water vapor flux, precipitation particles | |||||||
波・流れ中における洗掘防止用袋型根固め材の安定性に関する実験 Experimental Study on Stability of Flexible Anti-Scouring Foot Unit in Wave and Current | 307 | ||||||
平石哲也・橋口萌乃 Tetsuya HIRAISHI and Moeno HASHIGUCHI | |||||||
風力発電,モノパイル構造物,洗掘問題,水理実験,洗堀防止用袋型根固め材 Wind power generator, mono-pile structure, scouring problem, hydraulicexperiment, flexible foot filter unit for anti-scouring | |||||||
大潟海岸・四ッ屋浜で観測桟橋跡周辺の海底地形と海底底質の粒度組成 ―主に弧状沿岸砂州において,その2― Field Observations on both the Profile and the Grain Size Composition of the Sediment on the Sea Bottom, Around the Vestige of Observatory Pier, Yotsuyahama, Ogata Coast. ― As for the Crescent-shaped Bar Principally, No.2 ― | 313 | ||||||
内山 清 Kiyoshi UCHIYAMA | |||||||
弧状沿岸砂州中心部,弧状沿岸砂州接合部,トラフ,バー,極深部,極浅部,累積曲線 central region of a Crescent-shaped bar, jointed region of a Crescent-shaped bar, trough, bar, extremely deep region, extremely shallow region, cumulative curve | |||||||
Evaluation of Cross-sectional Geomorphology for Lentic Habitat Restoration in the Uji River | 334 | ||||||
Jue WANG, Yasuhiro TAKEMON and Tetsuya SUMI | |||||||
Uji River, riverbed degradation, lentic habitat, nature restoration, clay layer | |||||||
裏表紙 | |||||||