京都大学防災研究所年報 第67号 Aへ
To DPRI Annuals, No. 67 A
京都大学防災研究所年報 第67号 Cへ
To DPRI Annuals, No. 67 C
京都大学防災研究所年報 第67号 B
DPRI Annuals, No. 67 B
| 表紙 | |||||||
| 目次 | |||||||
| 防災におけるアートの有効性に関する心理実験に基づいた検証 Verification on the Effectiveness of Art in Disaster Prevention Based on Psychological Experiments | 1 | ||||||
| 土佐 尚子・金井 俊・嘉沢 剛・北林 一良・川田 浩孝・宮田 愛恵・ 中津 良平 Naoko TOSA, Shun KANAI, Go KAZAWA, Kazuyoshi KITABAYASHI, Hirotaka KAWATA, Manae MIYATA and Ryohei NAKATSU | |||||||
 | 流体アート,心理実験,日常性と非日常性,快不快の感情 fluid art, psychological experiment, everydayness and unusualness, pleasant | ||||||
| 奈良盆地東縁断層帯における重点的な調査観測による地下構造調査 Seismic Reflection Surveys and Borehole Experiments near the Nara-Bonchi-Toen Active Fault System | 16 | ||||||
| 岩田知孝・浅野公之・関口春子・山田浩二・新谷加代 ・石原大亮 Tomotaka IWATA, Kimiyuki ASANO, Haruko SEKIGUCHI, Koji YAMADA, Kayo SHINTANI, and Daisuke ISHIHARA | |||||||
| 奈良盆地東縁断層帯,京都・奈良盆地,反射法地震探査,ボーリング調査,VSP調査 Nara-Bonchi-Toen active fault system, Kyoto and Nara basins, Seismic reflection survey, Boring experiment, Vertical seismic profiling | ||||||
| 極配置法に基づく建物振動の統一的理解のMaxwellモデルへの拡張 Extension of Unified Understanding Based on Pole Allocation for Building Vibration to Maxwell Model | 39 | ||||||
| 池田芳樹・宇原尚希 Yoshiki IKEDA and Naoki UHARA | |||||||
| 建物,Maxwellモデル,統一的理解,極配置,粘性ダンパ,制御効果 building, Maxwell model, unified understanding, pole allocation, viscous damper, control effect | ||||||
|
桜島火山東部における局所的沈降の定量化と物理的解釈 Quantification and Physical Interpretation of Local Subsidence in the Eastern Part of Sakurajima Volcano 
| 55 | ||||||
| 八木優明・風間卓仁・山本圭吾・大柳諒 Hiroaki YAGI, Takahito KAZAMA, Keigo YAMAMOTO and Ryo OYANAGI | |||||||
| 桜島火山,地表変位,マグマだまり,局所的沈降,圧密現象,黒神地域 Sakurajima volcano, ground displacement, magma chamber, local subsidence, consolidation, Kurokami area | ||||||
|
桜島火山における繰り返し相対重力測定 (2023年10~11月および2024年3月) Repeated Relative Gravity Measurements at Sakurajima Volcano (October–November 2023 and March 2024)
| 66 | ||||||
| 風間卓仁・山本圭吾・岡田和見・大島弘光・ 大柳 諒・小濱瑞希・竹中悠亮・井口正人 Takahito KAZAMA, Keigo YAMAMOTO, Kazumi OKADA, Hiromitsu OSHIMA, Ryo OYANAGI, Mizuki KOHAMA, Yusuke TAKENAKA and Masato IGUCHI | |||||||
| 桜島火山,重力変化,質量移動,地殻変動,陸水重力擾乱 Sakurajima Volcano, gravity change, mass redistribution, crustal deformation, hydrological gravity disturbance | ||||||
| 姶良カルデラにおける海底地盤変動観測装置の設置後1年間の挙動 Behavior of Seabed Benchmark System during the First Year after Its Installation in Aira Caldera | 79 | ||||||
| 筒井智樹・味喜大介・井口正人 Tomoki TSUTSUI, Daisuke MIKI, and Masato IGUCHI | |||||||
| 海底地殻変動観測,GNSS,姶良カルデラ Marine geodesy, Global Navigation Satellite System, Aira Caldera | ||||||
| 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(続報) Investigation of a Ground Deformation Model With a Pressure Source Resembling the Shape of the Low S-wave Velocity Region Beneath the Aira Caldera | 87 | ||||||
| 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,低S波速度領域 Aira caldera, ground deformation, pressure source geometries, low Vs region | ||||||
Comparison of Failure Modes in Benched Slopes Using Centrifugal Models and 3D DEM Simulations | 91 | ||||||
Shanzhi TAO, Thirapong PIPATPONGSA, Fan ZHU and Yosuke HIGO | |||||||
| Benched slope, centrifugal model test, 3D discrete element method | ||||||
|
拡大崩壊発生に伴う地震動計測 ―紀伊山地田長瀬の事例― Seismic Observations during a Retrogressive Failure Case Study at Tanagase in the Kii Mountains
| 101 | ||||||
| 荒井紀之・土井一生 Noriyuki ARAI and Isei DOI | |||||||
| 地震動計測,拡大崩壊,付加体,伸縮計,フーリエスペクトル seismic observation, retrogressive failure, accretionary complex, extensometer, Fourier spectrum | ||||||
| 1924年西表海底火山噴火による軽石漂流のシミュレーション Simulation of Drift of Pumice Erupted by Explosion of Iriomote Submarine Volcano in 1924 | 110 | ||||||
| 井口敬雄・榎本剛・吉田聡 Takao IGUCHI, Takeshi ENOMOTO and Akira YOSHIDA | |||||||
| 火山,軽石,漂流シミュレーション volcano, pumice, simulation of drift | ||||||
| 領域アンサンブル変分法に向けた流れに依存する大規模混合手法 Flow-dependent Large-scale Blending for Limited-area Ensemble Data Assimilation | 114 | ||||||
| 中下早織・榎本剛 SaoriNAKASHITA andTakeshiENOMOTO | |||||||
| アンサンブルデータ同化,ネスティング,流れ依存性,階層構造 ensembledataassimilation,nesting,flowdependency,hierarchicalstructure | ||||||
| 北西太平洋における台風の中心気圧推定の改善に向けた木場の関係式の再検討 Revisiting Koba’s Relationship to Improve Minimum Sea-Level Pressure Estimates of Western North Pacific Tropical Cyclones | 134 | ||||||
| 相澤正隆・伊藤耕介・嶋田宇大 Masataka AIZAWA, Kosuke ITO, and Udai SHIMADA | |||||||
| 台風,ドボラック法,歴史的データセット tropical cyclones, Dvorak technique, historical dataset | ||||||
| 偏波レーダー立体観測情報の活用による地形性降雨算定手法の改良 Improvement of Orographic Rainfall Calculation Method Using MP Radar Volume Scanning Observation | 150 | ||||||
| 中北英一・佐藤克哉 Eiichi NAKAKITA, Katsuya SATO | |||||||
| Seeder-Feeder,粒径分布,地形性降雨,地上雨量推定, 雨量計 seeder-Feeder, drop size distribution, orographic rainfall, ground rainfall estimation, rain gauge | ||||||
Weather Modification Simulation of Line-Shaped Convective System Torrential Rainfall by Introducing Offshore Curtain | 156 | ||||||
Kosei YAMAGUCHI, Shoma NISHIMURA and Eiichi NAKAKITA | |||||||
| Weather Control, Line Shaped Convective System, Offshore Curtain | ||||||
| 高解像度d4PDFを用いた停滞前線性線状対流系の再現性確認と将来変化予測 Future Projections and Reproducibility Confirmation of Line-shaped Convective System Associated with Stationary Front Using High-resolution d4PDF | 168 | ||||||
| 仲ゆかり・岡田睦巳・中北英一 Yukari NAKA, Mutsumi OKADA and Eiichi NAKAKITA | |||||||
| 線状対流系,d4PDF,停滞前線,地球温暖化 line-shaped convective system, d4PDF, stationary front, global warming | ||||||
| 上昇流に着目した線状対流系の組織化指標と大気場のマルチフラクタル的変動 Organization Index of Linear-shaped Convective Systems Basedon Updraftand Multifractal Behaviorsinthe Atmospheric Variables | 177 | ||||||
| 大野哲之・山口弘誠・中北英一 AkiyukiONO,KoseiYAMAGUCHI,andEiichiNAKAKITA | |||||||
| 線状対流系,マルチフラクタル,組織化,雲解像モデル,アンサンブル予報 linear-shapedconvectivesystems,multifractal,organization,cloud-resolvingmodel,ensembleforecast | ||||||
| LESを用いた線状対流系豪雨に対する乱流による偶然性の影響評価 Effects of Turbulence-Induced Contingency on Line-Shaped Rain Bands Using LES | 193 | ||||||
| 河谷能幸・山口弘誠・中北英一 Yoshiyuki KAWATANI, Kosei YAMAGUCHI and Eiichi NAKAKITA | |||||||
| 線状対流系,乱流,偶然性,LES Line-shaped rain band, turbulence, contingency, LES | ||||||
| 豪雨制御シミュレーションにおける風速場操作の時空間的感度解析 Spatiotemporal Sensitivity Analysis of Wind Field Manipulation in Heavy Rainfall Control Simulation | 202 | ||||||
| 西村太一・山口弘誠・中北英一 Taichi NISHIMURA, Kosei YAMAGUCHI, and Eiichi NAKAKITA | |||||||
| ゲリラ豪雨,都賀川,気象制御,水蒸気 guerrilla heavy rainfall, Toga River, meteorological control, water vapor | ||||||
| 地域性に着目した短時間豪雨をもたらす降水システムに関する解析 Analysis of Precipitation Systems Causing Short-duration Heavy Rainfall, Focusing on Difference among Regional Characteristics | 219 | ||||||
| 渡辺悠一朗・中北英一 Yuichiro WATANABE and Eiichi NAKAKITA | |||||||
| 地域性,総観規模環境場,ゲリラ豪雨,線状対流系豪雨 Regional characteristics, Synoptic-scale environment, Guerrilla heavy rainfall, Line-shaped mesoscale convective system | ||||||
| 裏表紙 | |||||||