List of publications and presentations
REVIEWED PUBLICATIONS
PAPER PUBLISHED
– Hirose, M. and K. Nakamura, 2002: Spatial and Seasonal Variation of Rain Profiles over Asia Observed by Spaceborne Radar. J. Climate, 15, 3443-3458.
– Hirose, M. and K. Nakamura, 2004: Spatiotemporal variation of the vertical gradient of rainfall rate observed by TRMM Precipitation Radar. J. Climate, 17, 3378-3397.
– Hirose, M. and K. Nakamura, 2005: Spatial and diurnal variation of precipitation systems over Asia observed by the TRMM Precipitation Radar. J. Geophys. Res., 110, D05106, doi:10.1029/2004JD004815
– Kubota, T., S. Shige, H. Hashizume, K. Aonashi, N. Takahashi, S. Seto, M. Hirose, Y. N. Takayabu, T. Ushio, M. Kachi, K. Okamoto, 2007: Global precipitation map using satelliteborne microwave radiometers by the GSMaP project: Production and Validation. IEEE Trans. Geo. Rem. Sens., 45, 2259-2275.
– Hirose, M., R. Oki, S. Shimizu, M. Kachi, and T. Higashiuwatoko, 2008: Finescale diurnal rainfall statistics refined from 8 years of TRMM PR data. J. Appl. Meteor. Clim., 47, 544-561
– Hirose, M., R. Oki, D. A. Short, and K. Nakamura, 2009: Regional characteristics of scale-based precipitation systems from 10-year TRMM PR data. J. Meteor. Soc. Japan, 353-368.
– Short, D. A., Hirose, M., and K. Nakamura, 2009: An interpretation of TRMM Radar observations of shallow convection with a rain cell model. J. Meteor. Soc. Japan, 67-81.
– Shimizu, S., R. Oki, T. Tagawa, T. Iguchi, and Hirose, M., 2009: Evaluation of the effect of the orbit boost of the TRMM satellite on the PR rain estimates. J. Meteor. Soc. Japan, 83-92.
– Aonashi, K., J. Awaka, M. Hirose, T. Kozu, T. Kubota, G. Liu, S. Shige, T. Kida, S. Seto, N. Takahashi, and Y. N. Takayabu, 2009: GSMaP passive microwave precipitation retrieval algorithm: Algorithm description and validation. J. Meteor. Soc. Japan, 119-136.
– Hirose, M., S. Shimizu, R. Oki, T. Iguchi, D. A. Short, and K. Nakamura, 2012: Incidence-angle dependency of TRMM PR rain estimates. J. Atmos. and Oceanic Technol., 192-206.
– Hibi, Y., A. Tomigashi, and M. Hirose, 2015: Evaluation of a numerical simulation model for a system coupling atmospheric gas, surface water and unsaturated or saturated porous medium. Journal of Contaminant Hydrology, 183, 121-134.
– Hirose, M., Y. N. Takayabu, A. Hamada, S. Shige, and M. K. Yamamoto, 2017: Impact of long-term observation on the sampling characteristics of TRMM PR precipitation. J. Appl. Meteor. Climatol., 56, 713-723, DOI: 10.1175/JAMC-D-16-0115.1.
– Hirose, M., Y. N. Takayabu, A. Hamada, S. Shige, and M. K. Yamamoto, 2017: Spatial contrast of geographically induced rainfall observed by TRMM PR. J. Climate, 30, 4165-4184, DOI: 10.1175/JCLI-D-16-0442.1.
– Hirose, M., and K. Okada, 2018: A 0.01° Resolving TRMM PR Precipitation Climatology. J. Appl. Meteor. Climatol., 57, 1645-1661, DOI: 10.1175/JAMC-D-17-0280.1.
– Hirose, M., S. Shige, T. Kubota, F. A. Furuzawa, H. Minda, and H. Masunaga, 2021: Refinement of surface precipitation estimates for the dual-frequency precipitation radar on the GPM Core Obsertory using near-nadir measurements. J. Meteor. Soc. Japan, DOI: 10.2151/JMSJ.2021-060.
– Terao, T., S. Kanae, H. Fujinami, S. Das, A. P. Dimri, S. Dutta, K. Fujita, A. Fukushima, K.-J. Ha, M. Hirose, J. Hong, H. Kamimera, R. B. Kayastha, M. Kiguchi, K. Kikuchi, H. M. Kim, A. Kitoh, H. Kubota, W. Ma, Y. Ma, M. Mujumdar, M. I. Nodzu, T. Sato, Z. Su, S. Sugimoto, H. G. Takahashi, Y. Takaya, S. Wang, K. Yang, S. Yokoi, Peter van Oevelen, and J. Matsumoto, 2023, AsiaPEX: Challenges and Prospects in Asian Precipitation Research. Bull. Amer. Meteor. Soc., E884-E908, https://doi.org/10.1175/BAMS-D-20-0220.1.
– Hirose, M., K. Okada, K. Kawaguchi, and N. Takahashi, 2023, Removing interfering signals in spaceborne radar data for precipitation detection at very high altitudes. J. Atmos. Ocean Technol., 40, 8, 969-985, https://doi.org/10.1175/JTECH-D-22-0114.1.
Book
– Mahakur, S. Shige, and M. Hirose, 2025: Multi-scale manifestation of tropical precipitation as evidenced from recent satellite observations, Multi-scale precipitation variability over the tropics, P. Mukhopadhyay et al., Eds., Elsevier.
EXTENDED ABSTRACTS IN CONFERENCE PROCEEDINGS, etc.
– Hirose and Nakamura, 2001: Spatial and seasonal variation of rain profiles over Asia observed by TRMM PR. Proc. of 5th Int. Study Conf. on GEWEX in Asia and GAME, 350-355, Nagoya.
– Hirose and Nakamura, 2002: Precipitation structure observed by satellite. Proc. of The First Lower Atmosphere and Precipitation Study (LAPS) Workshop, 36-39, Nagoya.
– Hirose and Nakamura, 2004: Spatial and diurnal variation of precipitation systems over Asia. Proc. of 6th Int. Study Conf. on GEWEX in Asia and GAME, CD-ROM Pibl. No. 11, T8MH06Aug04145039, Kyoto.
– Hirose, Shimizu, Higashiuwatoko, and Tanaka, 2005: Spatial variation of the vertical gradient of rainfall rate near the surface. IEEE IGARSS, Proc. CD-ROM, Friday morning precipitation 2 interactive session, Seoul.
– Hirose, 2005: TRMM PR, its possibility and limitation for the global mapping of precipitation. Proc. of 11th CEReS Int. Symp. on Rem. Sens., 9-12, Chiba, Invited speaker.
– Shimizu, Iguchi, Oki, Hirose, and Tagawa, 2008: Evaluation of the effect of the orbit boost of the TRMM satellite on the PR rain estimatesIEEE IGARSS, Proc. CD-ROM, Boston.
– Hirose, 2009: Diurnal features of scale-based precipitation systems observed by TRMM PR. Proc. of MAHASRI/HyARC worksop, 293-304, Dnang, Vietnam.
– Hirose, 2009: 長期間蓄積された衛星搭載降雨レーダデータを用いた稀な降水現象の検出, 名城大学理工学部研究報告第49号, 1-5.
– Takayabu, Nakamura, Okamoto, Iguchi, Aonashi, Shige, Hirose, Kachi, Kubota, and Oki, 2013: TRMM status and science achievements in 15 years: Japanese perspective. IEEE IGARSS, TU1.T10.1.
– Hirose, 2015: Finescale climatology of widespread precipitation systems observed by TRMM PR. IEEE IGARSS, FR2.G3.1.
– 広瀬, 2016: PMM利用検討委員会後継ミッション検討分科会:2015年度PMM利用検討委員会後継ミッション検討分科会報告書 将来の降水観測ミッションへの提案,(執筆担当:pp. 18-23)
Report on participation in congress
– 第1回熱帯降雨観測衛星(TRMM)国際科学会議報告.中澤他.天気, 50, 19-28, 2003.
Dissertation
Undergraduate thesis, 1998: 非定常流における円柱後方渦列の実験的考察
Master thesis, 2000: 衛星搭載降雨レーダによるアジア域の降雨構造と大気加熱量の研究
Doctoral dissertation, 2004: Spatial and temporal variation of vertical profiles of rainfall rate observed by spaceborne precipitation radar (衛星搭載降雨レーダで観測された降雨強度鉛直プロファイルの時空間変動に関する研究)
PRESENTATIONS
OTHER INTERNATIONAL PRESENTATIONS
– Hirose and Nakamura, 2002: Spatial and seasonal variation of rain profiles over Asia observed by TRMM PR. The 1st TRMM Int. Science Conference, Hawaii.
– Hirose and Nakamura, 2003: Precipitation system structure depicted from vertical gradient of rainfall rate observed by TRMM Precipitation Radar. IUGG XXIII General Assembly, Sapporo.
– Hirose, Nakamura, Bhatt, Matsubara, Singh, Shibakawa, and Akimoto, 2003: Diurnal and spatial variation of rainfall observed by TRMM Precipitation Radar IUGG XXIII General Assembly, Sapporo.
– Hirose and Nakamura, 2004: Spatial and diurnal variation of precipitation systems over Asia. AOGS 1st Annual Meeting, Singapore.
– Shimizu, Tanaka, Hirose, Higashiuwatoko, Satoh, Kojima, and Iguchi, 2004: Six-year rainfall observation by TRMM PR and development of DPR for GPM. AOGS 1st Annual Meeting, Singapore.
– Hirose and Nakamura, 2004: Spatial and temporal variation of vertical profiles of rainfall rate observed by TRMM PR. The 2nd TRMM Int. Science Conference, Nara.
– Hirose, 2005: Diurnal variability of surface rainfall using eight years of TRMM PR data. The 5th GPM workshop, Tokyo.
– Hirose and Takayabu, 2006: Rain profile model by using TRMM PR data. Int. workshop on precipitation retrieval algorithms using satellite microwave radiometer, radar, and IR data, Tokyo.
– Hirose, Shimizu, Oki, Kachi, and Higashiuwatoko, 2006: The detection of severe storms using eight year of TRMM PR data. EGU General Assembly, Wien.
– Hirose, 2006: JAXA’s activities on space technology applications for water management. Sixteenth United Nations/International Astronautical Federation workshop on the use of space technology for water management, Valencia.
– Hirose, 2007: Rain type and profile model. Int. workshop on the precipitation retrieval algorithms using satellite microwave radiometer, radar and IR data, Tokyo.
– Hirose and Nakamura, 2008: Climatology of diurnal variations of precipitation systems. The 3rd TRMM Int. Science Conference, Las Vegas.
– Hirose and Nakamura, 2008: Detection of extreme precipitation systems based on the long-term TRMM PR data. EGU General Assembly, Wien.
– Hirose, M., 2010: Rainfall variability grouped by the type of precipitation systems. AOGS Annual Meeting, Hyderabad.
– Hirose, M., 2011: Fine-scale rainfall climatology over East Asia by TRMM PR. AOGS Annual Meeting, Taipei.
– Hirose, M., 2011: Asian Monsoon Years (2007-2012): Spatiotemporal variability and uncertainty in rainfall observed by TRMM PR. WCRP OSC, Denver.
– Hirose, M., 2012: Fine-scale rainfall characteristics stratified by scale-based precipitation systems. Proc. of 4th TRMM and GPM int. sci. conf., Tokyo.
– Hirose, M., 2013: Climatological characteristics of TRMM PR rainfall. Proc. of AOGS, AS15-A014, Brisbane.
– Hirose, M., 2014: Sharp contrast in precipitation. Proc. of AOGS, AS29-A043, Sapporo.
– Hirose, M., 2015: Finescale climatology of widespread precipitation systems observed by TRMM PR. Proc. of IEEE 2015 Int. Geosci. and Rem. Sens. Sympo., Milan.
– Hirose, M., 2016: Fine-scale precipitation climatology refined from the 16-year TRMM PR data. Proc. of the int. sci. conf. on MAHASRI, Tokyo.
– Hirose, M., 2016: Detection of regional characteristics of precipitation systems from the short-term GPM DPR data. Proc. of AOGS, AS39-D3-AM2-311A(L3N)-010, Beijing.
– Hirose, M., 2017: Geographic patterns of fine-scale TRMM PR rain climatology and retrieval uncertainties. Proc. of 38th Conference on Radar Meteorology, QPE, 251, Chicago.
– Hirose, M., 2018: Detection of localized rainfall maxima and minima. EGU General Assembly, Wien.
– Hirose, M., 2018: Bias correction of surface rainfall based on precipitation profiles at low levels. AOGS Annual meeting, Honolulu.
– Hirose, M., 2019: Uncertainties in gridded precipitation products derived from spaceborne radars. AsiaPEX kickoff conference, Sapporo.
– Hirose, M., 2019: From a satellite perspective. International workshop on decadal challenges in Asian monsoon process studies, Nagoya.
– Hirose, M., 2019: Assessing climatological precipitation gradients in mountainous regions derived from spaceborne radars. AMS 39th international conference on radar meteorology, Nara.
– Hirose, M., 2019: Spatial rainfall uncertainty observed using spaceborne radars. 2019 Joint Satellite Conference, Boston.
– Hirose, M., 2019: Effect of clutter interference in surface rainfall estimates at off-nadir scan angles. NASA PMM science team meeting, Indianapolis.
– Hirose, M., and S. Shige, 2021: Spatial pattern of high-elevation precipitation observed through spaceborne precipitation radars. EGU General Assembly.
– Hirose, M. 2022: “Consistency of spaceborne-radar precipitation estimates across incidence angles,” Symposium on Radar Science in the Service of Earth System Predictability, AMS 102nd annual meeting, Session 10 Ground-Based Radar Studies to Advance Satellite Precipitation Retrieval Algorithms, Houston, online.
– Hirose, M., 2022: “Analyzing spatiotemporal continuity in Asian precipitation data obtained using spaceborne precipitation radars,” JpGU meeting 2022, AsiaPEX session, Chiba.
– Hirose, M., and S. Shige, 2022: “Temporal variation of incidence-angle differences in precipitation as observed by spaceborne radars,” AOGS annual meeting, AS-28 session, online.
– Hirose, M., 2023: “Spatial characteristics of precipitation associated with tropical cyclones and their retrieval uncertainties from spaceborne precipitation radars.” AMS radar conf., online.
– Hirose, M., 2023: “Spatial structure of tropical cyclone precipitation by spaceborne precipitation radars.” NASA PMM meeting, Minneapolis.
– Hirose, M., 2024: “Estimating undetected precipitation using statistics from spaceborne precipitation radar observations.” 9th Global and Energy and Water Exchanges Open Science Conference, Observational and Modeling Initiatives for the Asian Monsoon Field Campaign session, Sapporo.
– Hirose, M., 2024: “Spatiotemporal variability of gridded precipitation information updated by diverse sampling.” CGMS International Precipitation Working Group IPWG-11, poster, Tokyo.
– Hirose, M. 2024: “Retrieval uncertainties related to clutter removal in spaceborne precipitation radar data.” Orographic Precipitation Focus Group, CGMS International Precipitation Working Group IPWG-11, Tokyo.
– Hirose, M., 2024: “Estimating the impact of surface clutter removal and sensitivity constraints on precipitation climatology.” NASA PMM meeting, postern and oral, San Diego.
– Hirose, M., V. Mantas, 2025: “Detecting seasonal differences in the variations in diurnal precipitation using spaceborne Ku-band radars.” EGU General Assembly 2025, Vienna, Austria, 27 Apr–2 May 2025, EGU25-10838, https://doi.org/10.5194/egusphere-egu25-10838.
– Seto, S. and Hirose, M.: “Improved Precipitation Rate Profile Estimation Method for the Main-lobe Clutter Region in GPM/DPR”, EGU General Assembly 2025, Vienna, Austria, 27 Apr–2 May 2025, EGU25-9231, https://doi.org/10.5194/egusphere-egu25-9231.
NATIONAL PRESENTATIONS, etc. (国内学会,研究集会など)
– 広瀬, 1999: 潜熱エネルギー放出の鉛直プロファイル導出の試み. 夏の学校, 三重
– 広瀬, 中村, 加藤, 2000: 衛星搭載降雨レーダによるアジア域の降雨構造と大気加熱量導出の試み. 春季気象学会, つくば
– 広瀬, 中村, 2000: アジアの海陸における降雨の鉛直分布の特徴. 秋季気象学会, 京都
– 広瀬, 中村, 2001: 衛星搭載降雨レーダによる降雨の鉛直傾度の季節変化. 秋季気象学会, 岐阜
– 広瀬, 2003: TRMM PRから観た対流活動. 湿潤対流と環境場に関する研究会, 名古屋
– 広瀬, 中村, 2003: TRMM PRによる熱帯モンスーン域の降雨特性の解析. 春季気象学会, つくば
– 広瀬, 2004: TRMM PRで観測されたアジア域における降雨特性の地域差. アジアにおけるメソスケール擾乱の多様性, 京都
– 広瀬, 中村, 2004: TRMM PRで観測された降雨強度鉛直勾配の時空間変動. 秋季気象学会, 福岡
– 青梨, 瀬戸, 広瀬, 高薮, 2004: 衛星搭載マイクロ波放射計AMSRE降水強度リトリーバルアルゴリズムの開発(その2). 秋季気象学会, 福岡
– 広瀬, 清水, 田中, 2005: TRMM PRによる降雨強度鉛直分布の解析と地表面降水推定. 春季気象学会, 東京
– 広瀬, 沖, 清水, 可知, 東上床, 2006: 8年間蓄積されたTRMM PRによる降水量の地域特性. 春季気象学会, 東京
– 広瀬, 2006: 8年分のTRMM PRデータを用いた日周変化の検出. 第2回MAHASRI国内研究集会, 横浜
– 広瀬, 2006: TRMM PRによる衛星レーダ気象学と降水システム気候学. 夏の学校, 伊勢, 招待講演
– 広瀬, 2006: 衛星搭載降雨レーダによる降水システムの地域特性. 春季気象学会メソ気象研究会, 名古屋, 招待講演
– 広瀬, 2007: 8年分のTRMM PRデータを用いた日周変化の検出. 第2回日変化ワークショップ, 箱根
– 広瀬, 沖, 清水, 中村, Short, 2007: 背の低い雨に関するTRMM PRの観測特性と降水分布の系統誤差. 秋季気象学会, 札幌
– 古澤, 広瀬, 中村, 上田, 2008: TRMM PRの降水推定に基づく降水特性の年々変動. 春季気象学会, 横浜
– Hirose, M., 2011: Incidence-angle dependency check. Evaluation of TRMM PR 2A25 v.7 (ITE233). http://www.eorc.jaxa.jp/TRMM/documents/PR_algorithm_product_information/pr_v7_validation_jpn_j.htm
– 広瀬, 2011: 長期TRMM PRデータによる降水気候値の特徴と課題. 秋季気象学会, 名古屋
– 広瀬, 2012: 2A25 v.7の入射角依存性, 名古屋大学地球水循環研究センター平成23年度共同研究集会, 名古屋
– 土井, 広瀬, 2012: 降水季節変化に見られるTRMM PRの推定誤差, 名古屋大学地球水循環研究センター平成23年度共同研究集会, 名古屋
– 土井, 広瀬, 2012: TRMM PRとAMeDASによる降水季節変化の地域的特徴, 春季気象学会, つくば
– Hirose, M., 2012: Rainfall measurement from space (2). Proc. 22nd International Hydrological Programme (IHP) training course, Nagoya
– Hirose, M., 2013: Evaluation of rainfall climatology from the long-term spaceborne radar data. Proc. JAXA 7th PMM RA meeting, Tokyo.
– 広瀬, 2013: 衛星搭載降雨レーダデータの気候学的利用について. 秋季気象学会, 仙台.
– Hirose, M., 2014: Evaluation of rainfall climatology from the long-term spaceborne radar data (2). JAXA joint PI workshop, PMM session, Tokyo.
– 広瀬, 2014: 01F降水量の評価. 第2回DPR Quick Evaluation Team会合.
– 広瀬, 2014: 02A降水量の評価. 第3回DPR Quick Evaluation Team会合.
– 広瀬, 2014: 2つの衛星搭載降水レーダデータの特性. 秋季気象学会, 福岡
– Hirose, M., 2015: Evaluation of rainfall climatology from the long-term spaceborne radar data (3). JAXA joint PI workshop, PMM session, Tokyo.
– 岡田, 広瀬, 2015: 山岳域における降水の局所的特徴に関する比較研究, 名古屋大学地球水循環研究センター平成26年度共同研究集会, 名古屋
– 岡田, 広瀬, 2015: TRMM PRを用いた超高解像度降水気候値に見られる局所性, 春季気象学会, つくば
– Hirose, M., 2016: Evaluation of rainfall climatology from the long-term spaceborne radar data (4). JAXA joint PI workshop, PMM session, Tokyo.
– Hirose, M., 2016: Evaluation of high-resolution precipitation climatology based on two spaceborne radar data (1), JAXA PI workshop, PMM session, Tokyo.
– 広瀬, 小川, 堤, 2016: 地表近傍降水鉛直分布に関する入射角依存性の低減. 秋季気象学会, 名古屋
– Hirose, M., 2017: Evaluation of high-resolution precipitation climatology based on two spaceborne radar data (2), JAXA PI workshop, PMM session, Tokyo.
– 広瀬, 堤, 2017: 海岸線付近の降水変動, 名古屋大学宇宙地球環境研究所平成28年度共同研究集会, 名古屋
– 広瀬, 堤, 2017: GPM DPR観測における背の低い雲による降水の見逃し, 秋季気象学会, 北海道
– 堤, 広瀬, 2017: GSMaPによる中・高緯度の降雪推定, 秋季気象学会, 北海道
– 堤, 広瀬, 2017: 衛星搭載降水レーダによる降雪推定値の空間分布, 日本気象学会平成29年度中部支部研究会, 岐阜
– 広瀬, 2017: PRとDPRの地表近傍降水情報の補正, JAXA PMM 国内サイエンスチーム会合, 東京
– Hirose, M., 2018: Evaluation of high-resolution precipitation climatology based on two spaceborne radar data (3), JAXA PI workshop, PMM session, Tokyo.
– 広瀬, 2018: 高高度の降水, JAXA PMM 第2回国内サイエンスチーム会合, 東京
– 広瀬, 2018: GPM DPRデータによる中高緯度域の降水気候値の抽出, 日本気象学会2018年度秋季大会, 仙台
– 山本,広瀬, 2018: アラビア半島における降雨の空間的特徴, 日本気象学会2018年度秋季大会, 仙台
– 山本,広瀬, 2018: 少雨域における降水の鉛直勾配, 日本気象学会平成30年度中部支部研究会, 三重
– Hirose, M., 2019: Evaluation of high-resolution precipitation climatology based on two spaceborne radar data (4), JAXA PI workshop, PMM session, Tokyo.
– 山本,広瀬, 2019: アラビア半島の衛星降水観測, 平成30年度GPMおよび衛星シミュレータ合同研究集会, 名古屋
– 広瀬, 2019: 衛星搭載降水レーダによる高精細降水マップの特徴, 第7回京都大学大気科学コロキウム, 京都
– 広瀬, 2019: 衛星搭載降水レーダによる降水気候プロダクトの評価と拡張, JAXA PMMサイエンスチーム国内キックオフ会合, 東京
– Hirose, M., 2020: Assessing and enhancing climate precipitation products derived from spaceborne radars (1), JAXA PI workshop, PMM session, Tokyo.
– 黒沢,広瀬, 2020: GPM DPRによる冬季日本域の降水推定精度, 令和2年度GPMおよび衛星シミュレータ合同研究集会, 名古屋
– Hirose, M., 2020: Assessing and enhancing climate precipitation products derived from spaceborne radars (2), JAXA PI workshop, PMM session, Tokyo.
– 広瀬, 2021: 山岳域の地表付近降水量と地表面降水量, 日本気象学会2021年度春季大会
– Hirose, M., 2021: Assessing and enhancing climate precipitation products derived from spaceborne radars (3), JAXA PI workshop, PMM session, Tokyo.
– 広瀬正史, 2021: Bline zone (クラッターの影響を受ける高度)における降水推定.京都大学ミニ研究集会,京都
– 広瀬正史, 2021: 衛星搭載降水レーダによるヒマラヤ山岳地域の降水気候値, 第4回ヒマラヤ降水研究会合, online.
– 西村俊輝,広瀬正史, 2022:“ユーラシア大陸中高緯度夏季降水の空間分布特性”,令和3年度GPMおよび衛星シミュレータ合同研究集会予稿集, 名古屋
– M. Hirose, 2022: “Temporal variability and spatial uncertainty in precipitation climatology refined from the long-term spaceborne radar data (1),” the joint PI meeting of JAXA Earth Observation Missions FY2022, PMM session, Tokyo.
– 広瀬正史, 2023: “2つの衛星搭載降水レーダによる降水気候値の不確かさの推定.” GPMおよび衛星シミュレータ合同研究集会,名古屋.
– 広瀬正史, 2023: “衛星搭載降水レーダによる熱帯低気圧に伴う降水域の観測.” 日本気象学会2023年度秋季大会,仙台.
– Hirose, M., 2023: “Variability of precipitation statistics associated with tropical cyclones based on long-term spaceborne radar data.” JAXA joint PI meeting, special session on typhoon science in collaboration with TRC/YNU, Tokyo.
– Hirose, M., 2023: Temporal variability and spatial uncertainty in precipitation climatology refined from the long-term spaceborne radar data (2),” the joint PI meeting of JAXA Earth Observation Missions FY2023, PMM session, Tokyo.
– 広瀬正史, 2023: “PR・DPR降水気候値の空間的不均一性・不確実性.” ヒマラヤ降水研究会,名古屋.
– Hirose, M., 2024: Temporal variability and spatial uncertainty in precipitation climatology refined from the long-term spaceborne radar data (3),” the joint PI meeting of JAXA Earth Observation Missions FY2024, PMM session, Tokyo.
– 広瀬正史, 2024: “山岳域における降水変動と統計の偏りと不確かさ.” ヒマラヤ降水研究会,名古屋.
– 西垣拓哉,広瀬正史, 2025:「目視観測によるGPM DPRの雨雪判別の検証」,令和6年度GPMおよび衛星シミュレータ合同研究集会予稿集, p. 15-16. 名古屋.
Research Projects
– Evaluation of spatial information on precipitation near the center of tropical cyclones, ISEE joint research program, 2025/4-2028/3, Hirose, Masunaga, Furuzawa, Minda, and Mantas
– Examination of the features and challenges of precipitation climate information updated by long-term spaceborne radar data, JAXA EORA4, 2025-present
– Unravelling precipitation systems in the Himalayas using in-situ observations, remote sensing and cloud-resolving models, Grants-in-Aid for Scientific Research, Fund for the Promotion of Joint International Research (International Collaborative Research), Japan Society for the Promotion of Science, Sep, 2023 – Mar, 2028, Hatsuki Fujinami (Nagoya Univ)
– Temporal variability and spatial uncertainty in precipitation climatology refined from the long-term spaceborne radar data, EORA3, JAXA, 2022-2024
– Assessing and enhancing climate precipitation products derived from spaceborne radars, EO-RA2, JAXA, Apr, 2019 – Mar, 2022
– 衛星搭載降雨レーダと雲解像モデルによる小規模急峻地形の降雨への影響解明
基盤研究B(一般), 文部科学省, Apr, 2019, 重尚一 (京都大学)
– Evaluation of high-resolution precipitation climatology based on two spaceborne radar data, PMM8, JAXA, Apr, 2016 – Mar, 2019
– ヒマラヤ山岳域における複雑地形と大規模湿潤気流がもたらす降水変動メカニズムの解明, 国際共同研究加速基金(国際共同研究強化(B)), 文部科学省, Oct, 2018, 藤波初木 (名古屋大学)
– 衛星搭載マイクロ波放射計による地形性豪雨の降雨推定精度の向上, 科学研究費助成事業(科学研究費補助金)基盤研究(B)(研究分担者), 文部科学省, Apr, 2014 – Mar, 2018, 重 尚一 (京都大学)
– メガラヤ・バングラデシュ・ミャンマー地域に豪雨をもたらす渦状低気圧の実態解明, 科学研究費助成事業(科学研究費補助金)基盤研究(C), 文部科学省, Apr, 2014 – Mar, 2018, 藤波 初木 (名古屋大学)
– 広域観測データによる強雨・大雨の地域的特徴の検出, NDRR, 名城大学, Apr, 2012 – Mar, 2017
– Evaluation of rainfall climatology from the long-term spaceborne radar data
pmm7, JAXA, Apr, 2013 – Mar, 2016
– DPR/GMI複合アルゴリズムの開発, 宇宙航空研究開発機構, Apr, 2008 – Mar, 2013, 増永浩彦 (名古屋大学)
– 降水システム群の時空間変化, 科学研究費助成事業(科学研究費補助金)若手研究(B), 文部科学省, Apr, 2009 – Mar, 2011, 広瀬 正史
Award
– NASA RHG Exceptional achievement for science team to GPM algorithm team 2015
– NASA Group achievement award presented to the GPM post-launch team 2015
Short history
Job
Apr 2025-Mar 2026: Investigador visitante, Universidade de Coimbra, Portugal
Apr 2012-present: Faculty of Science and Technology, Meijo University, Associate Prof.
Apr 2008 – Mar 2012: Faculty of Science and Technology, Meijo University, Assistant Prof.
May 2007 – Mar 2008: HyARC, Nagoya University, Postdoc fellow
Apr 2007 – May 2007: Nagoya University, Postdoc fellow
Apr 2004 – Mar 2007: JAXA EORC, Aerospace project research associate
Education
2004: Ph. D, Satellite Meteorology, Nagoya Univ.
2000: M. S., Satellite Meteorology, Nagoya Univ.
1998: B. S., Aerospace Engineering Tokyo Metropolitan Institute of Technology
Professional memberships
1998-present: Meteorological Society of Japan
2011-present: American Meteorological Society
2013-present: Japan Geoscience Union
2021-present: European Geoscience Union
Others
– SR-PS (PR-PS and DPR-PS) DB: https://www.rain-clim.com
– External committee member related to Nagoya University and JAXA
Curriculum lectures
Undergraduate: Environmetal meteorology, Environmental remote sensing, Experiments in environmental science and technology II, Exercise in surveying, Seminar, Graduation research, Omnibus courses: Introduction of environmental science and technology I, II. Study of contemporary societies, Human beings and nature, The history of science and technology,
Gradate schools: Advanced theory of atmospheric constituent I, II, Advanced seminar and experiments in atmosphere and water environment IA, IB, IIA, IIB, Scientific and technical English (omnibus style).
