土木研究所資料 第4245号 - ICHARM The International Centre for

㹇㹑㹑㹌ࠉ㸮㸱㸶㸴㸫㸳㸶㸵㸶
ᅵᮌ◊✲ᡤ㈨ᩱࠉ➨㸲㸰㸲㸳ྕ
,&+$503XEOLFDWLRQ1R-
ࠉಟኈㄢ⛬ࠕ㜵⅏ᨻ⟇ࣉࣟࢢ࣒ࣛ
ࠉỈ⅏ᐖࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺࢥ࣮ࢫࠖ
ᐇ᪋ሗ࿌᭩
ᖹᡂᖺ᭶
⊂❧⾜ᨻἲேࠉᅵᮌ◊✲ᡤ
Ỉ⅏ᐖ࣭ࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺᅜ㝿ࢭࣥࢱ࣮,&+$50
ISSN0386-5878
ᅵᮌ◊✲ᡤ㈨ᩱ
➨ 4245 ྕ 2012 ᖺ 11 ᭶
ᅵᮌ◊✲ᡤ㈨ᩱ
2011-2012
ಟኈㄢ⛬ࠕ㜵⅏ᨻ⟇ࣉࣟࢢ࣒ࣛ
Ỉ⅏ᐖࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺࢥ࣮ࢫࠖ
ᐇ᪋ሗ࿌᭩
ᖹᡂ 24 ᖺ 11 ᭶
⊂❧⾜ᨻἲேᅵᮌ◊✲ᡤ
Ỉ ⅏ ᐖ ࣭ ࣜ ࢫ ࢡ ࣐ ࢿ ࢪ ࣓ ࣥ ࢺ ᅜ 㝿 ࢭ ࣥ ࢱ ࣮ (ICHARM)
Copyright © (2012) by P.W.R.I
All rights reserved. No part of this book may be reproduced by any means,
nor transmitted, nor translated into a machine language without the written
permission of the Chief Executive of P.W.R.I.
ࡇࡢሗ࿌᭩ࡣࠊ⊂❧⾜ᨻἲேᅵᮌ◊✲ᡤ⌮஦㛗ࡢᢎㄆࢆᚓ࡚ห⾜ࡋࡓࡶࡢ࡛
࠶ࡿࠋࡋࡓࡀࡗ࡚ࠊᮏሗ࿌᭩ࡢ඲㒊ཪࡣ୍㒊ࡢ㌿㍕ࠊ」〇ࡣࠊ⊂❧⾜ᨻἲேᅵ
ᮌ◊✲ᡤ⌮஦㛗ࡢᩥ᭩࡟ࡼࡿᢎㄆࢆᚓࡎࡋ࡚ࡇࢀࢆ⾜ࡗ࡚ࡣ࡞ࡽ࡞࠸ࠋ
ᅵᮌ◊✲ᡤ㈨ᩱ
➨ 4245 ྕ 2012 ᖺ 11 ᭶
2011-2012
ಟኈㄢ⛬ࠕ㜵⅏ᨻ⟇ࣉࣟࢢ࣒ࣛ
Ỉ⅏ᐖࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺࢥ࣮ࢫࠖ
ᐇ᪋ሗ࿌᭩
Ỉ⅏ᐖ◊✲ࢢ࣮ࣝࣉ
Ỉ⅏ᐖ࣭ࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺᅜ㝿ࢭࣥࢱ࣮㸦,&+$50㸧ࡣࠊᨻ⟇◊✲኱Ꮫ㝔኱Ꮫ㸦*5,36㸧ࠊ
㸦⊂㸧ᅜ㝿༠ຊᶵᵓ㸦-,&$㸧࡜㐃ᦠࡋࠊ ᖺ ᭶ ᪥࠿ࡽ ᖺ ᭶ ᪥࡟࠿ࡅ࡚ࠊ
ᖺ㛫ࡢಟኈㄢ⛬ࠗ㜵⅏ᨻ⟇ࣉࣟࢢ࣒ࣛ Ỉ⅏ᐖࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺࢥ࣮ࢫ࠘ࢆᐇ᪋ࡋࡓࠋ
Ꮫ⏕ࡣࠊ୺࡜ࡋ࡚Ⓨᒎ㏵ୖᅜࡢὥỈ㛵㐃⅏ᐖ㜵Ṇ࣭㍍ῶ࡟ಀࡿ㜵⅏ᐇົࢆᢸᙜࡍࡿᢏ⾡⫋ဨ
ே࡛࠶ࡿࠋ
ᮏࢥ࣮ࢫ࡛ࡣࠊỈ⅏ᐖ⿕ᐖ㍍ῶࡢ⥲ྜⓗィ⏬❧᱌ࠊᐇ㊶άື࡟ᑓ㛛ⓗ࡞▱㆑ࢆᣢࡗ࡚ཧຍ
࡛ࡁࡿᐇ㊶ⓗேᮦࢆ㣴ᡂࡍࡿࡇ࡜ࢆ┠ⓗ࡜ࡋ࡚࠸ࡿࠋ
ࢥ࣮ࢫ๓༙࡛ࡣ୺࡟ㅮ⩏࣭₇⩦ࢆᐇ᪋ࡋࠊࢥ࣮ࢫᚋ༙࡛ࡣᏛ⏕ࡢಶே◊✲ࡢࡓࡵ࡟᫬㛫ࢆ
඘࡚ࠊ᏶ᡂᗘࡢ㧗࠸ಟኈㄽᩥࢆసᡂ࡛ࡁࡿࡼ࠺㓄៖ࡋࡓࠋࡲࡓࠊ᪥ᮏࡢ἞Ỉᢏ⾡ࢆᏛࡪࡓࡵ
࡟㐺ᐅ⌧ᆅぢᏛࡸ₇⩦ࢆᐇ᪋ࡋࡓࠋ
ᮏሗ࿌᭩ࡣࠊࢥ࣮ࢫෆᐜ࡟ࡘ࠸࡚ሗ࿌ࡍࡿ࡜࡜ࡶ࡟ࢥ࣮ࢫ࡟ᑐࡍࡿホ౯ࢆ⾜࠸ࠊḟᖺᗘࡢ
ᨵၿ࡟㈨ࡍࡿࡶࡢ࡛࠶ࡿࠋ
࣮࣮࢟࣡ࢻ㸸◊ಟࠊಟኈㄢ⛬ࠊ㜵⅏ࠊὥỈ
2011-2012 ಟኈㄢ⛬ࠕ㜵⅏ᨻ⟇ࣉࣟࢢ࣒ࣛ Ỉ⅏ᐖࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺࢥ࣮ࢫࠖ
ᐇ᪋ሗ࿌᭩
㸫┠ḟ㸫
Chapter 1: ᮏࢥ࣮ࢫࡢ⫼ᬒ࡜┠ⓗ
1.1 ᮏࢥ࣮ࢫࡢ⫼ᬒ
1.2 ᮏࢥ࣮ࢫࡢ┠ⓗ
1.3 ᮏࢥ࣮ࢫ࠿ࡽᚓࡽࢀࡿ࢔࢘ࢺࣉࢵࢺ
1.4 ᮏࢥ࣮ࢫࡢ≉ᚩ
1.5 ᮏࢥ࣮ࢫ࡬ࡢཧຍ㈨᱁
1.5.1 JICA ◊ಟ⏕࡜ࡋ࡚ᛂເࡍࡿሙྜ
1.5.2 GRIPS ࡬┤᥋ᛂເࡍࡿሙྜ
1.5.3 ᭱⤊ỴᐃཧຍᏛ⏕
1.6 ᮏࢥ࣮ࢫࡢᣦᑟయไ
࣭࣭࣭
࣭࣭࣭
࣭࣭࣭
࣭࣭࣭
࣭࣭࣭
࣭࣭࣭
Chapter 2: ᮏࢥ࣮ࢫࡢෆᐜ
2.1 ࢥ࣮ࢫࢫࢣࢪ࣮ࣗࣝ
2.2 ࢥ࣮ࢫ࣒࢝ࣜ࢟ࣗࣛ
2.2.1 ㅮ⩏࣭₇⩦
2.2.2 ㅮᖌ࣭ᣦᑟᩍᐁ
2.2.3 ⌧ᆅどᐹ࠾ࡼࡧ㜵⅏⾜ᨻᢸᙜ⪅࠿ࡽࡢㅮ⩏
2.2.4 Ꮫ⩦࣭⏕ά⎔ቃ
2.3 ಟኈㄽᩥ
࣭࣭࣭ 㸵
࣭࣭࣭ 㸵
࣭࣭࣭ 㸷
Chapter 3: 2011-2012 ᖺᗘάືሗ࿌
࣭࣭࣭㸯㸴
Chapter 4: ಟኈㄽᩥ
࣭࣭࣭㸰㸰
Chapter 5: ࢥ࣮ࢫホ౯࡜௒ᚋࡢㄢ㢟
5.1 ࢥ࣮ࢫホ౯
5.1.1 ࢥ࣮ࢫࢹࢨ࢖ࣥ࡟ࡘ࠸࡚
5.1.2 ༢ඖ┠ᶆ㸦࢔࢘ࢺࣉࢵࢺ㸧࡟ࡘ࠸࡚
5.1.3 ㅮ⩏࣭₇⩦࡟ࡘ࠸࡚
5.1.4 ࢔ࣥࢣ࣮ࢺ࡟࠾ࡅࡿ⮬⏤ᅇ⟅ពぢ
5.2 ௒ᚋࡢㄢ㢟
࣭࣭࣭㸰㸲
࣭࣭࣭㸰㸲
Chapter 6:
࣭࣭࣭㸱㸮
⤊ࢃࡾ࡟
㸯
㸯
㸱
㸱
㸲
㸲
࣭࣭࣭ 㸴
࣭࣭࣭㸯㸳
࣭࣭࣭㸰㸶
㸫ཧ⪃㈨ᩱ㸫
ཧ⪃㈨ᩱ 1-1
Ꮫ⏕ྡ⡙
࣭࣭࣭Annex 1
ཧ⪃㈨ᩱ 2-1
ࢥ࣮ࢫ඲యヲ⣽᪥⛬⾲
࣭࣭࣭Annex 2
ཧ⪃㈨ᩱ 2-2
୍࣒࢝ࣜ࢟ࣗࣛぴ⾲
࣭࣭࣭Annex 8
ཧ⪃㈨ᩱ 2-3
ྛ⛉┠ࢩࣛࣂࢫ
࣭࣭࣭Annex 14
ཧ⪃㈨ᩱ 2-4
⌧ᆅどᐹ⾜⛬⾲
࣭࣭࣭Annex 31
ཧ⪃㈨ᩱ 5-1 ࢔ࣥࢣ࣮ࢺ࡟࠾ࡅࡿ⮬⏤ᅇ⟅ពぢ
࣭࣭࣭Annex 48
㸺Opening Ceremony㸦10 ᭶ 7 ᪥㸧㸼 㸦⫪᭩࡞࡝ࡣᙜ᫬ࡢࡶࡢ㸧
బ⸨ JICA ⟃Ἴᡤ㛗ࡢࡈᣵᣜ ᒸᓮ GRIPS ᩍᤵࡢࡈᣵᣜ
㨶ᮏ ᅵᮌ◊✲ᡤ⌮஦㛗ࡢᣵᣜ BARUN Ặ࡟ࡼࡿỴព⾲᫂
㛤ㅮᘧᚋࡢ㞟ྜ෗┿
Photo 1
㸺Lecture & Exercise㸼
➉ෆᩍᤵ ⴙ▮෸ᩍᤵ
㯤ᩍᤵ ⚟ᒸᩍᤵ Ώ㑔ᩍᤵ Ụ㢌ᩍᤵ
Photo 2
Jayawardena ᩍᤵ ⏣୰ᩍᤵ
῝ぢ෸ᩍᤵ బᒣ෸ᩍᤵ
ụ㇂ᩍᤵ ᯇᮏᩍᤵ
Photo 3
᳃ᆅᩍᤵ ᒸᓮᩍᤵ
Photo 4
㸺Field Trip㸼
㸦10 ᭶ 27 ᪥ Ⲩᕝ㸧
᪂⏣ᆅ༊ࢫ࣮ࣃ࣮ሐ㜵 ᪧᒾῡỈ㛛࡜ᐇ⦼ὥỈᾐỈ῝⾲♧ᯈ
ⲨᕝୗὶἙᕝ஦ົᡤ ⅏ᐖᑐ⟇ᐊ ▱Ỉ㈨ᩱ㤋ࠕamoaࠖ
Ἑᕝᩜ࡛ࡢㄝ᫂ ᾋ㛫㜵⅏ࢫࢸ࣮ࢩࣙࣥ
Photo 5
㸦10 ᭶ 28 ᪥ 㛵ᮾᆅ᪉ᩚഛᒁࠊ㤳㒔ᅪእ㒌ᨺỈ㊰㸧
⅏ᐖᑐ⟇ᐊ࡛ࡢㅮ⩏ 㞟ྜ෗┿
㱟 Q 㤋࡛ࡢㄝ᫂ 㤳㒔ᅪእ㒌ᨺỈ㊰ෆ ㄪᅽỈᵴ
㸦11 ᭶ 10 ᪥ ஂ႐ᕷᰩᶫෆࠊΏⰋ℩㐟Ỉᆅ㸧
฼᰿ᕝୖὶἙᕝ஦ົᡤ࡛ࡢㅮ⩏ ฼᰿ᕝ᝟ሗ┙㸦ᰩᶫ㥐㸧
Photo 6
⏫ෆࡢࠕࡲࡿࡈ࡜ࡲࡕࡈ࡜ࣁࢨ࣮ࢻ࣐ࢵࣉࠖ ᰩᶫᨭᡤෆ࡟࠶ࡿ฼᰿ᕝỈ఩⾲♧ሪ
ΏⰋ℩ฟᙇᡤ࡟࡚㐟Ỉᆅࡢㄝ᫂ ᒎᮃࢱ࣮࣡
஦ົᡤࡢ᪉࡜㞟ྜ෗┿
Photo 7
㸦11 ᭶ 22 ᪥ ⓑᏊᕝㄪᩚụ⩌ࠊ▼⚄஭ᕝ㸧
ⓑᏊᕝẚୣᑽᶫୗὶㄪᩚụྲྀỈཱྀ ㄪᩚụෆ㒊
❧ᆙᘓタ⌧ሙ ఫᏯᐦ㞟ᆅ࡛ࡢἙᕝᨵಟ
஦ົᡤࡢ᪉࡜㞟ྜ෗┿
Photo 8
㸦12 ᭶ 9 ᪥ 㭯ぢᕝὶᇦ㸧
ᚷ㒊⌮஦࡟ࡼࡿㅮ⩏ 㭯ぢᕝὶᇦࢭࣥࢱ࣮࡛ࡢㄝ᫂
㐟Ỉᆅ㐲ᮃ 㟝ࡀୣㄪᩚụ
ᜠ⏣ᕝ㐟Ỉᆅ 㧗ᶫྡ㄃ᩍᤵᏯ࡛ࡢࡈㄝ᫂
Photo 9
ᚷ㒊⌮஦࡜஦ົᡤࡢ᪉࡜㞟ྜ෗┿
Photo 10
㸦3 ᭶ 14 ᪥ ᩫఀᕝὶᇦ㸧
኱ᶫᕝࢥ࣑ࣗࢽࢸ࢕ࢭࣥࢱ࣮࡛ࡢㄝ᫂ ᩫఀᕝᨺỈ㊰ᘓタ⌧ሙ
ᑿཎࢲ࣒⟶⌮ᐊ࡛ࡢㄝ᫂ ᑿཎࢲ࣒
㸦3 ᭶ 15 ᪥ ኴ⏣ᕝὶᇦ㸧
㧗℩ሖ ᗈᓥᕷෆࡢ◁㜵ሖሐ
Photo 11
♲ᅬ࣭኱ⰪỈ㛛 ඖᏳᕝぶỈࢸࣛࢫ
㸦3 ᭶ 16 ᪥ ࠕே࡜㜵⅏ᮍ᮶ࢭࣥࢱ࣮ࠖࠊ኱࿴ᕝὶᇦ㸧
ࢭࣥࢱ࣮࡛ࡢㄝ᫂ டࡢ℩ᆅࡍ࡭ࡾᑐ⟇ࡢㄝ᫂
Ỉᢤࡁࢺࣥࢿࣝࡢෆ㒊 㞟ྜ෗┿
Photo 12
㸦5 ᭶ 19 ᪥ ࠕ➨ 61 ᅇ฼᰿ᕝỈ⣔㐃ྜỈ㜵₇⩦ࠖ㸧
㸦5 ᭶ 21 ᪥ ࢲ࣒࣭◁㜵஦ᴗ㸧
ᕝ἞ࢲ࣒࣭஬༑㔛ࢲ࣒㐃⤖ࢺࣥࢿࣝ ᕝ἞ࢲ࣒
㊊ᑿ◁㜵ሖሐ๓࡛ࡢㄝ᫂ ᯇᮌᒣ⭡ᕤ
Photo 13
㖡ぶỈබᅬ࡟࡚ࣃ࢟ࢫࢱࣥὥỈ࣮࣡ࢡࢩࣙࢵࣉཧຍ⪅࡜ࡢ㞟ྜ෗┿
㸦5 ᭶ 22 ᪥ ฼᰿኱ሖ㸧
஦ົᡤᒇୖ࠿ࡽሖࢆ㐲ᮃ ஦ົᡤᒇୖ࠿ࡽ㝣ഃࢆ㐲ᮃ
⟶⌮ᐊࡢᵝᏊ ฼᰿኱ሖ
Photo 14
㸦9 ᭶ 7 ᪥ ᪂ᐑᕷᙺᡤࠊ⇃㔝ᕝὶᇦࠊఀໃᕷ኱‖᣺⯆఍㸧
ᕷᙺᡤ࡛ࡢᢿᡭ࡛ࡢฟ㏄࠼ ᕷᙺᡤ࡛ࡢㅮ⩏
㐨ࡢ㥐 ⏣㛗 ࡛ࡢㄝ᫂ ௬タఫᏯࡢㄝ᫂
⇃㔝ᕝᨵಟ஦ᴗࡢㄝ᫂ ≉Ṧሐ
Photo 15
ఀໃᕷ኱‖᣺⯆఍㛗࠿ࡽࡢㄝ᫂
Photo 16
㸺Ỉ⌮Ꮫ₇⩦㸼
㸦2 ᭶ 14 ᪥ ࡘࡃࡤᕷෆ࡟࡚㸧
ᐇ㦂ෆᐜࡢㄝ᫂ ⴙ▮෸ᩍᤵ࠿ࡽࡢㄝ᫂
ᐇ㦂ࡢᵝᏊ
㸦5 ᭶ 22 ᪥ ῰ᕝᕷ኱ṇᶫ࡟࡚㸧
ᐇ㦂ࡢᵝᏊ
Photo 17
㸺Master’s Thesis㸼
ࢢ࣮ࣝࣉ࡟ศ࠿ࢀ࡚ࡢ Project Cycle Management ၥ㢟ศᯒ₇⩦ࡢᵝᏊ
ㄽᩥ᭱⤊Ⓨ⾲఍㸦8 ᭶ 10 ᪥㸧ࡢᵝᏊ
➨ 14 ᅇᅵᮌᏛ఍ࢧ࣐࣮ࢩ࣏ࣥࢪ࣒࢘Ⓨ⾲㸦9 ᭶ 5 ᪥㸧ࡢᵝᏊ
Photo 18
㸺Others㸼
ICHARM ୺ദࠕ࠾Ⲕ఍ࠖࡢᵝᏊ ᅵᮌ◊✲ᡤ๓ࡢᱜࡢࡶ࡜࡛グᛕ෗┿
Photo 19
㸺㛢ㅮᘧ㸦9᭶13᪥㸧㸼
◊ಟಟ஢ドᤵ୚ ICHARM Award ᤵ୚㸦HASSAN Ặ㸧
Best Paper Award ᤵ୚㸦ZHU BING Ặ㸧 Best Paper Award ᤵ୚㸦ARSLAN USMAN Ặ㸧
㞟ྜ෗┿
Photo 20
㸺Ꮫ఩ᤵ୚ᘧ㸦9 ᭶ 14 ᪥㸧㸼
Photo 21
Photo 22
Photo 23
Photo 24
Chapter 1: ᮏࢥ࣮ࢫࡢ⫼ᬒ࡜┠ⓗ
1.1 ᮏࢥ࣮ࢫࡢ⫼ᬒ
⮬↛⅏ᐖࡣ࡝ࡇ࡛㉳ࡇࡗ࡚ࡶே㛫ࡢᝒ๻࡜⤒῭ᦆኻ࡜ᘬࡁ㉳ࡇࡋࠊᅜࡢⓎᒎࢆጉࡆࡿࠋ≉࡟ࠊⓎᒎ㏵ୖ
ᅜ࡟࠾࠸࡚ࡣ㒔ᕷ໬ࡀ㐍⾜ࡋࠊ㈋ࡋ࠸⪅ࡣ⮬↛⅏ᐖ࡟ᑐࡋ࡚ࡼࡾ⬤ᙅ࡞ᘓ≀࡜ᆅᇦ࡟ᐃఫࡍࡿࡓࡵࠊⓎᒎ
㏵ୖᅜ࡟࠾ࡅࡿ⮬↛⅏ᐖ࡬ࡢ⬤ᙅࡉࡣࡲࡍࡲࡍᣑ኱ࡍࡿࠋ
⮬↛⅏ᐖࡢ୰࡛ࡶ≉࡟ࠊὥỈࡸ࠿ࢇࡤࡘࡢࡼ࠺࡞Ỉ㛵㐃⅏ᐖࡢ㍍ῶࡣࠊᣢ⥆ྍ⬟࡞ே㛫♫఍ࡢⓎᒎ࡜㈋
ᅔ㍍ῶࡢࡓࡵ࡟ࡶࠊᅜ㝿♫఍ࡀ༠ຊࡋ࡚ඞ᭹ࡉࢀࡿ࡭ࡁ኱ࡁ࡞ᣮᡓ࡛࠶ࡿࠋࡑࡢࡼ࠺࡞◚ቯⓗ࡞⅏ᐖࡢᩘ
ࡣ⥲ィⓗ࡟ቑຍࡋ࡚࠸ࡿࡔࡅ࡛࡞ࡃࠊ≉࡟࢔ࢪ࢔ࡸ࢔ࣇࣜ࢝࡟࠾࠸࡚㢧ⴭ࡛࠶ࡿ㸦ᅗ 1-1㸧
ࠋࡲࡓࠊᅜ㐃ࡢ
ୡ⏺ேཱྀ᥎ィ㸦ࠕୡ⏺㒔ᕷ໬ண 㸦2005㸧ࠖ㸧࡟ࡼࢀࡤࠊୡ⏺࡟࠾ࡅࡿ㒔ᕷᒃఫ⪅ࡢᩘ࡜ࡑࡢ๭ྜࡣ௒ᚋ
ࡶቑ࠼⥆ࡅࠊࡇࡢࡼ࠺࡞ேཱྀቑຍࡢ࡯࡜ࢇ࡝ࡣⓎᒎ㏵ୖᅜ࡛㉳ࡁࡿ࡜ண ࡉࢀ࡚࠸ࡿࠋ౛࠼ࡤࠊ2000 ᖺ࠿
ࡽ 2030 ᖺࡢ㛫࡟ࠊ࢔ࢪ࢔ࡢ㒔ᕷேཱྀࡣ 13 ൨ 6000 ୓ே࠿ࡽ 26 ൨ 4000 ୓ே࡟ࠊ࢔ࣇࣜ࢝ࡢ㒔ᕷேཱྀࡣ 2
൨ 9400 ୓ே࠿ࡽ 7 ൨ 4200 ୓ே࡟ᛴቑࡍࡿ࡜ぢ㎸ࡲࢀ࡚࠸ࡿ㸦ᅗ 1-2㸧ࠋࡲࡓࠊ௒ᚋ 10 ᖺ㛫ࡢண ࡛ࡶࠊ
ࢲࢵ࢝㸦ࣂࣥࢢࣛࢹࢩࣗ㸧ࠊ࣒ࣥࣂ࢖㸦࢖ࣥࢻ㸧ࡸࢪࣕ࢝ࣝࢱ㸦࢖ࣥࢻࢿࢩ࢔㸧࡞࡝ᾏ࡟㠃ࡋ࡚࠸ࡿ࢔ࢪ
࢔ࡢ኱㒔ᕷ࡛ேཱྀࡢᛴቑࡀண᝿ࡉࢀࠊ
㜵⅏᪋タࡢᩚഛ࡞࡝ࡢᑐ⟇ࡀ㐺ษ࡟⾜ࢃࢀ࡞࠸ሙྜࠊ
ὥỈࡸᭀ㢼㞵ࠊ
ὠἼ࡞࡝኱つᶍỈ⅏ᐖ࡟ᑐࡍࡿ⬤ᙅᛶࡀࡲࡍࡲࡍ㧗ࡲࡿ࠾ࡑࢀࡀ࠶ࡿ㸦ᅗ 1-3㸧ࠋ
ࡲࡓࠊ࢔ࢪ࢔ᆅᇦࡣỈ㛵㐃⅏ᐖ࡟ࡼࡿṚ⪅ᩘࡢ࠺ࡕࠊୡ⏺ࡢ 80%௨ୖࢆ༨ࡵ࡚࠸ࡿ㸦ᅗ 1-4㸧
ࠋ௒ᚋࠊẼ
ೃኚ໬࡟ࡼࡾ㝆㞵㔞ࡸࡑࡢ㝆ࡾ᪉ࡢศᕸࣃࢱ࣮ࣥࡀኚ໬ࡍࡿࡇ࡜ࡀண ࡉࢀ࡚࠾ࡾࠊỈ㛵㐃⅏ᐖࡢᙉᗘ࡜
㢖ᗘࢆᝏ໬ࡉࡏࡿྍ⬟ᛶࡀ࠶ࡿࠋࡲࡓࠊᾏ㠃ࡣᆅ⌫ ᬮ໬ࡢࡓࡵ࡟ୡ⏺୰࡛ୖ᪼ࡍࡿࡇ࡜ࡀண ࡉࢀ࡚࠾
ࡾࠊࡑࢀࡣ㡰␒࡟ᾏᓊᆅᇦࠊἙཱྀࡢࢹࣝࢱᇦ࡜ᑠࡉ࡞ᓥࢆ༴㝤࡟ࡉࡽࡍࡇ࡜࡟࡞ࡿࠋ
450
400
350
300
250
Africa
Americas
Asia
Europe
Ocenia
200
150
100
50
0
ᅗ 1-1 Ỉ㛵㐃⅏ᐖᩘࡢ⤒ᖺኚ໬㸦ᆅᇦู㸧
㸦⅏ᐖ␿Ꮫࢭࣥࢱ࣮(CRED)ࡢࢹ࣮ࢱࢆࡶ࡜࡟ ICHARM సᡂ㸧
1
ᅗ 1-2 㒔ᕷ㒊࡜㒔ᕷ㒊௨እࡢேཱྀண 㸦ᆅᇦู㸧
㸦ᅜ㐃ࡢୡ⏺ேཱྀ᥎ィ㸦ᅜ㐃⤒῭♫఍⌮஦఍ ேཱྀ㒊ࠕୡ⏺㒔ᕷ໬ண 㸦2005㸧ࠖ㸧ࡢࢹ࣮ࢱࢆࡶ࡜࡟ ICHARM సᡂ㸧
䠄million䠅
6.0
1975-1985
1985-1995
5.0
1995-2005
4.0
2005-2015 (predicted)
3.0
2.0
1.0
0.0
㸦ᅜ㐃ࡢୡ⏺ேཱྀ᥎ィ㸦ᅜ㐃⤒῭♫఍⌮஦఍ ேཱྀ㒊ࠕୡ⏺㒔ᕷ໬ண 㸦2005㸧ࠖ㸧ࡢࢹ࣮ࢱࢆࡶ࡜࡟ ICHARM సᡂ㸧
Africa
2.6%
Europe
0.8%
Oceania
0.5%
America
12.7%
ᅗ 1-4
Asia
Ỉ㛵㐃⅏ᐖ࡟ࡼࡿṚ⪅ᩘࡢᆅᇦูศᕸ(1980-2006)
83%
㸦⅏ᐖ␿Ꮫࢭࣥࢱ࣮(CRED)ࡢࢹ࣮ࢱࢆࡶ࡜࡟ ICHARM సᡂ㸧
2
Seoul
ᅗ 1-3 1975 ᖺ࠿ࡽ 2015 ᖺࡲ࡛ࡢୡ⏺኱㒔ᕷ࡟࠾ࡅࡿேཱྀቑຍ
䕦 Paris
䕦 Osaka-Kobe
䕦 Tokyo
Moskva
䕦 Los Angeles
Buenos Aires
䕦 New York
Rio de Janeiro
Istanbul
䖃 Cairo
䖃 Beijing
䖃 Mexico City
䖃 São Paulo
Metro Manila
Calcutta
Shanghai
Karachi
䖃 Delhi
Jakarta
Mumbai
Dhaka
Lagos
-1.0
ࡇࡢࡼ࠺࡞⮬↛⅏ᐖࡢᙳ㡪ࢆῶࡽࡍࡓࡵ࡟ࡣࠊ⅏ᐖࡢ஦๓࣭஦୰࣭஦ᚋࡢࣂࣛࣥࢫࡢ࡜ࢀࡓ༴ᶵ⟶⌮ࡀࠊ
ࢲ࣒ࡸሐ㜵࡞࡝ࡢᵓ㐀≀ࢆࡶࡕ࠸ࡓᑐ⟇ࠊὥỈண㆙ሗࢩࢫࢸ࣒ࡸࣜࢫࢡ࣐ࢵࣉ࣭ࣁࢨ࣮ࢻ࣐ࢵࣉ࡞࡝ࡢ㠀
ᵓ㐀≀ᑐ⟇ࠊ♫఍ᚰ⌮Ꮫ࡞࡝ከࡃࡢᑓ㛛ศ㔝࡟ࢃࡓࡗ࡚ࡉࢀ࡞ࡅࢀࡤ࡞ࡽ࡞࠸ࠋࡇࡢࡓࡵࠊᑓ㛛ᩍ⫱࡜ࢺ
࣮ࣞࢽࣥࢢ࡟ࡼࡗ࡚ࠊ㐺ษ࡞⅏ᐖ⟶⌮᪉㔪࡜ᆅඖࡢ≧ἣࢆ⪃៖ࡋࡓᢏ⾡ࢆ㐺ษ࡟㛤Ⓨࡋࠊࢥ࣑ࣗࢽࢸ࢕ࡢ
㜵⅏ព㆑ࢆྥୖࡉࡏࡿࡓࡵ࡟ᆅඖࡢఫẸ࡜ᵝࠎ࡞᝟ሗ஺᥮ࡀ࡛ࡁࡿࡼ࠺࡞ࠊ⅏ᐖ⟶⌮ࡢᑓ㛛ᐙࢆ㣴⫱ࡍࡿ
ᚲせࡀ࠶ࡿࠋ
ࡇࢀࡽࡢ⫼ᬒࡢࡶ࡜ࠊⓎᒎ㏵ୖᅜ࡟࠾࠸࡚Ỉ㛵㐃⅏ᐖ࡟ᑐฎ࡛ࡁࡿᑓ㛛ᐙࡢ⬟ຊࢆྥୖࡉࡏࡿࡓࡵࠊ
ICHARM ࡣࠊᨻ⟇◊✲኱Ꮫ㝔኱Ꮫ㸦௨ୗࠊGRIPS㸧࡜㸦⊂㸧ᅜ㝿༠ຊᶵᵓ㸦௨ୗࠊJICA㸧࡜༠ຊࡋࠊ2007
ᖺ࠿ࡽಟኈㄢ⛬ࠗ㜵⅏ᨻ⟇ࣉࣟࢢ࣒ࣛ Ỉ⅏ᐖࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺࢥ࣮ࢫ㸦Water-related Disaster
Management Course of Disaster Management Policy Program㸧
࠘
㸦௨ୗࠊᮏࢥ࣮ࢫ࡜⾲グࡍࡿ㸧ࢆ❧ࡕ
ୖࡆࡓࠋ࡞࠾ࠊJICA ◊ಟྡ࡜ࡋ࡚ࡣࠗ㞟ᅋ◊ಟࠕὥỈ㛵㐃⅏ᐖ㜵⅏ᑓ㛛ᐙ⫱ᡂࠖ
㸦TRAINING FOR
EXPERT ON FLOOD-RELATED DISASTER MITIGATION㸧
࡛࠘࠶ࡿࠋᮏᖺᗘࡣ 5 ᮇ┠ࡢࢥ࣮ࢫ࡜࡞
ࡿࠋ
ᅜ㝿㐃ྜࡣࠊࣘࢿࢫࢥࡢ୺ᑟࡢࡶ࡜࡛ 2005 ᖺ࠿ࡽ 2014 ᖺࡲ࡛ࢆࠕᩍ⫱࡜ᣢ⥆ྍ⬟࡞㛤Ⓨࡢࡓࡵࡢ 10
ᖺࠖ࡜ᐃࡵ࡚࠸ࡿࠋᮏࢥ࣮ࢫࡣࡲࡉ࡟ࡑࡢ⌮ᛕ࡟ྜ⮴ࡍࡿࡶࡢ࡛࠶ࡾࠊ࠿ࡘࠊࣘࢿࢫࢥࡢᚋ᥼ࡢࡶ࡜࡟タ
❧ࡉࢀࡓ ICHARM ࡀࡇࡢࢥ࣮ࢫࢆ㐠Ⴀࡍࡿࡇ࡜ࡣࠊ㠀ᖖ࡟ගᰤ࡛࠶ࡿ࡜⪃࠼࡚࠸ࡿࠋ
1.2 ᮏࢥ࣮ࢫࡢ┠ⓗ
ୖࡢࡼ࠺࡞⫼ᬒࡢࡶ࡜ࠊᮏࢥ࣮ࢫࡢ᭱⤊ⓗ࡞฿㐩Ⅼ࠾ࡼࡧ┠ⓗࡣࠊ௨ୗࡢࡼ࠺࡟タᐃࡋ࡚࠸ࡿࠋ
<Overall Goal>
The damage of water-related disasters is reduced by planning and implementing the
countermeasures of water-related disasters in their countries.
<Program Objective>
The participant’s capacity to practically manage the problems and issues concerning
water-related disasters is developed for contributing to mitigation of water-related disasters in
their countries.
1.3 ᮏࢥ࣮ࢫ࠿ࡽᚓࡽࢀࡿ࢔࢘ࢺࣉࢵࢺ
ᮏࢥ࣮ࢫ࡛Ꮫ⩦ࡍࡿࡇ࡜࡛ࠊᏛ⏕ࡣ௨ୗࡢࡇ࡜ࡀฟ᮶ࡿࡼ࠺࡟࡞ࡿࠋ
Participants are expected to achieve the following outputs;
(1) To be able to explain basic concept and theory on generation process of water-related
disasters, water-related hazard risk evaluation, disaster risk management policy and
technologies.
(2) To be able to explain basic concept and theory on flood countermeasures including
landslide and debris flow.
(3) To formulate the countermeasures to solve the problems and issues concerning
3
water-related disasters in their countries by applying techniques and knowledge acquired
through the program.
1.4 ᮏࢥ࣮ࢫࡢ≉ᚩ
ᮏࢥ࣮ࢫࡢ≉ᚩ࡜ࡋ࡚ࡣࠊ௨ୗࡢ 3 ࡘࢆᣲࡆࡿࡇ࡜ࡀ࡛ࡁࡿࠋ
I. “Problem Solving-Oriented” course 㸦ㄢ㢟ゎỴᆺ◊ಟ㸧
኱つᶍỈ⅏ᐖ࡟ᑐᛂࡍࡿࡓࡵ࡟ࡣࠊ⫋ဨಶேࡢ⬟ຊྥୖࡶ኱஦࡛࠶ࡿࡀࠊ୍ே࡛ฟ᮶ࡿࡇ࡜࡟ࡣ࠾
ࡢࡎ࡜㝈⏺ࡀ࠶ࡾࠊ㜵⅏⤌⧊࡜ࡋ࡚ࡢᑐᛂ⬟ຊྥୖࢆᅗࡿࡇ࡜ࡀᚲせ୙ྍḞ࡛࠶ࡿࠋ
㏆ᖺ JICA ◊ಟࡣࠊ⤌⧊࡜ࡋ࡚ࡢᑐᛂ⬟ຊྥୖࢆ┠ⓗ࡜ࡋࡓࠗㄢ㢟ゎỴᆺ◊ಟ࠘࡟㍈㊊ࡀ⛣ࡉࢀ࡚
࠸ࡿࠋࡇࢀࡣࠊᏛ⏕ࡀ⮬ᅜ࡟࠾ࡅࡿỈ⅏ᐖ࡟㛵ࡍࡿㄢ㢟ࢆࡲࡎ≉ᐃ࣭ㄆ㆑ࡋࡓୖ࡛ࠊࡑࡢㄢ㢟ࢆゎỴ
ࡍࡿࡓࡵ࡟⮬ࡽ୺యⓗ࡟Ꮫ⩦ࡍࢀࡤࠊಶே࡜ࡋ࡚ࡢຠ⋡ⓗ࡞Ꮫ⩦ຠᯝࡀᚓࡽࢀࡿ࡜࡜ࡶ࡟ࠊᡤᒓࡍࡿ
⤌⧊࡟࡜ࡗ࡚ࡶࠊㄢ㢟ゎỴࡢࡓࡵ࡟᭷ຠ࡞⤖ᯝࡀᚓࡽࢀࡿ࡜ᛮࢃࢀࡿ࠿ࡽ࡛࠶ࡿࠋ
ࡇࡢࡼ࠺࡞⪃࠼࠿ࡽࠊᮏࢥ࣮ࢫࡣࠕᢲࡋࡘࡅࡢ◊ಟ࡛ࠖࡣ࡞ࡃࠊ
ࠕ⮬ࡽ⪃࠼ࠊㄢ㢟ࢆゎỴࡍࡿ◊ಟࠖ
ࢆ┠ᣦࡋ࡚࠸ࡿࠋᮏࢥ࣮ࢫࡢಟኈㄽᩥ࡛ࡣࠊᏛ⏕ࡀ⮬ࡽ⮬ᅜࡢㄢ㢟ゎỴ࡟㛵ࢃࡿࢸ࣮࣐ࢆ◊✲ࡍࡿࡇ
࡜࡟ࡋ࡚࠸ࡿࡇ࡜࠿ࡽࠊ⥲ྜⓗ࡞Ỉ⅏ᐖ⿕ᐖ㍍ῶࡢ⥲ྜⓗィ⏬❧᱌ࡀྍ⬟࡞ேᮦ⫱ᡂࡀᅗࡽࢀࠊᖐᅜ
ᚋࡢ⮬ᅜ࡛ࡢㄢ㢟ゎỴಁ㐍࡟ࡶᙺ❧ࡘࡇ࡜ࡀᮇᚅࡉࢀࡿࠋ
II. “Practical” rather than “Theoretical” 㸦⌮ㄽࡼࡾࡶᐇົ㸧
ୖグࡢࡼ࠺࡟ㄢ㢟ゎỴᆺࡢ◊ಟ࡜ࡋ࡚࠸ࡿࡓࡵࠊᇶ♏⌮ㄽࡼࡾࡶᐇົ࡛ࡢᛂ⏝ࡀฟ᮶ࡿࡼ࠺࡞ᐇ㊶
ⓗ࡞ㅮ⩏࣭₇⩦࡞ࡽࡧ࡟⌧ᆅどᐹࢆ⾜ࡗ࡚࠸ࡿࠋ
III. 1 year master’s course 㸦1 ᖺ࡛ಟኈྕࡀྲྀᚓ࡛ࡁࡿ㸧
ᮏࢥ࣮ࢫࡣࠊ⌧ᅾ⾜ᨻᶵ㛵࡛ാ࠸࡚࠸ࡿ⌧⫋ࡢ⫋ဨࢆᑐ㇟࡜ࡋ࡚࠸ࡿࡶࡢ࡛࠶ࡿࡓࡵࠊᴗົ࡟ฟ᮶
ࡿࡔࡅᨭ㞀ࢆ᮶ࡉ࡞࠸ࡼ࠺࡟ࠊ㏻ᖖ 2 ᖺ࡛ྲྀᚓࡍࡿಟኈྕࢆ 1 ᖺ࡛ྲྀᚓ࡛ࡁࡿࡼ࠺ᵓᡂࡉࢀ࡚࠸ࡿࠋ
1.5 ᮏࢥ࣮ࢫ࡬ࡢཧຍ㈨᱁
ᮏࢥ࣮ࢫ࡬ࡢཧຍ᪉ἲࡣࠊJICA ࡢᾏእ⌧ᆅ஦ົᡤࢆ㏻ࡌ࡚ເ㞟࣭㑅⪃ࡉࢀࡓ JICA ◊ಟࠕὥỈ㛵㐃⅏
ᐖ㜵⅏ᑓ㛛ᐙ⫱ᡂࠖࡢ◊ಟ⏕ࡀࠊGRIPS ࡢᏛ⏕࡜ࡋ࡚ཧຍࡍࡿሙྜ࡜ࠊGRIPS ࡬┤᥋ᛂເࡋ㑅⪃ࡉࢀ࡚
ཧຍࡍࡿሙྜࡢ 2 ✀㢮ࡀ࠶ࡿࠋ๓⪅࡛ࡣࠊྛᅜ࡟࠾ࡅࡿ JICA ⌧ᆅ஦ົᡤࡀࠊ஦๓࡟ᮏࢥ࣮ࢫ࡬ࡢཧຍࢽ࣮
ࢬࢆ⌧ᆅᅜࡢ㛵ಀᶵ㛵࡟↷఍࣭ᢕᥱࡋࡓ࠺࠼࡛ᮏࢥ࣮ࢫ࡬ࡢཧຍࢆỴᐃࡍࡿࡓࡵࠊཧຍࢆỴᐃࡋ࡞࠿ࡗࡓ
ᅜ࠿ࡽࡣᏛ⏕ࡣཧຍ࡛ࡁ࡞࠸ࠋ
1.5.1 JICA ◊ಟ⏕࡜ࡋ࡚ᛂເࡍࡿሙྜ
஦๓ࡢཧຍࢽ࣮ࢬㄪᰝࡢ⤖ᯝࠊJICA ◊ಟ⏕࡜ࡋ࡚ࡢᛂເ⪅ࡢೃ⿵ᅜࠊᑐ㇟ᶵ㛵ࠊཧຍ㈨᱁ࡣ௨ୗࡢ㏻
ࡾ࡜࡞ࡗࡓࠋ
Candidate Countries㸸
Philippines, Bangladesh, Nepal, Indonesia, Laos, China, Mongolia, Pakistan, Sri Lanka,
Republic of the Fiji Islands, Barbados, Brazil, Guyana, Tunisia, Republic of Moldova, Viet Nam
4
Eligible/Target Organization㸸
Governmental organizations concerning river management or water-related disasters
Nominee Qualifications㸸
Applicants should;
(1) be nominated by their governments.
(2) be technical officials, engineers or researchers who have three (3) or more year of
experience in the field of flood management in governmental organizations.
(* Basically, researcher in the University (ex: professor, etc) are excluded.)
(3) be university graduates in civil engineering, water resource management, or disaster
mitigation, etc. or have an equivalent academic background.
(4) have working knowledge of civil engineering, especially of hydraulics and hydrology.
(5) be familiar with mathematics such as differentiation and integration techniques.
(6) be able to write research reports on the individual study in English.
(7) be proficient in MS Word, Excel and Power Point.
(8) have a competent command of spoken and written English which is equivalence to
TOEFL CBT 213/iBT79, IELTS 6.0 or more (This program includes active participation
in discussions and development of the action plan and Master thesis, thus requires high
competence of English ability both in conversation and composition. Please attach an
official certificate for English ability such as TOEFL, TOEIC etc.)
(9) be in good health, both physically and mentally, to participate in the program in Japan.
(10) be over twenty-two (22) and under forty (40) years of age.
(11) not be serving any form of military service.
1.5.2 GRIPS࡬┤᥋ᛂເࡍࡿሙྜ
GRIPS࡟┤᥋ᛂເࡍࡿሙྜࡢࠊᛂເ⪅㈨᱁ࡣ௨ୗࡢ㏻ࡾ࡛࠶ࡗࡓࠋ
To be eligible for admission to this master's program, an applicant
1) must hold a bachelor's degree or its equivalent from a recognized/accredited university of the
highest standard in the field of civil engineering, water resource management, or disaster
mitigation.
2) must have working knowledge of civil engineering, especially of hydraulics and hydrology.
3) must be familiar with mathematics such as differentiation and integration techniques.
4) must satisfy the English language requirements with a minimum TOEFL score of Internet-Based
Test (iBT) 79 (Paper-Based Test 550) , IELTS 6.0 or its equivalent.
5) must be in good health.
5
1.5.3 ᭱⤊ỴᐃཧຍᏛ⏕
1.5.1ࠊ1.5.2 ࡟ࡼࡾᏛ⏕ເ㞟ࢆ⾜ࡗࡓᚋࠊᒸᓮ ೺஧ ᩍᤵ㸦ᨻ⟇◊✲኱Ꮫ㝔኱Ꮫ㸧ࢆࢹ࢕ࣞࢡࢱ࣮࡜ࡍ
ࡿࣉࣟࢢ࣒ࣛጤဨ఍࡟ࡼࡗ࡚ࠊ㜵⅏ᨻ⟇ࣉࣟࢢ࣒ࣛ࡬ࡢධᏛ⏕ࡀ᭱⤊ⓗ࡟Ỵᐃࡉࢀࡓࠋࣉࣟࢢ࣒ࣛጤဨ఍
ࡣࠊ௨ୗࡢ࣓ࣥࣂ࣮࡟ࡼࡗ࡚ᵓᡂࡉࢀ࡚࠸ࡿࠋ
࣭ᒸᓮ ೺஧ ᨻ⟇◊✲኱Ꮫ㝔኱Ꮫ ᩍᤵ 㸦ࢹ࢕ࣞࢡࢱ࣮㸧
࣭᳃ᆅ ⱱ ᨻ⟇◊✲኱Ꮫ㝔኱Ꮫ ≉ูᩍᤵ
࣭⚟஭ ⚽ኵ ᨻ⟇◊✲኱Ꮫ㝔኱Ꮫ ᩍᤵ
࣭ụ㇂ ᾈ ᨻ⟇◊✲኱Ꮫ㝔኱Ꮫ ≉௵ᩍᤵ
࣭Ṋ⏣ ᩥ⏨ ᨻ⟇◊✲኱Ꮫ㝔኱Ꮫ ᩍᤵ
࣭Ᏻ⸨ ᑦ୍ 㸦⊂㸧ᘓ⠏◊✲ᡤ ᅜ㝿ᆅ㟈ᕤᏛࢭࣥࢱ࣮㛗
࣭ᶼ஭ ಇ᫂ 㸦⊂㸧ᘓ⠏◊✲ᡤ ᅜ㝿ᆅ㟈ᕤᏛࢭࣥࢱ࣮ୖᖍ◊✲ဨ
࣭➉ෆ 㑥Ⰻ 㸦⊂㸧ᅵᮌ◊✲ᡤ ICHARM ࢭࣥࢱ࣮㛗
࣭⏣୰ ⱱಙ 㸦⊂㸧ᅵᮌ◊✲ᡤ ICHARM ࢭࣥࢱ࣮ Ỉ⅏ᐖ◊✲ࢢ࣮ࣝࣉ㛗
ࣉࣟࢢ࣒ࣛጤဨ఍࡟ࡼࡿ㆟ㄽࡢ⤖ᯝࠊ㐣ཤ᭱ከ࡜࡞ࡿྜィ19ྡࡀྜ᱁࡜࡞ࡗࡓࠋᏛ⏕ྡ⡙ࢆཧ⪃㈨ᩱ1-1
࡟♧ࡍࠋ࡞࠾௒ᖺᗘࡣࠊ19ྡ඲ဨࡀJICA◊ಟ⏕࡜ࡋ࡚ࡢཧຍ࡜࡞ࡗ࡚࠸ࡿࠋࡲࡓࠊࣃ࢟ࢫࢱࣥ࠿ࡽࡢୗ
グ3ྡࡣࠊ2010ᖺࡢࣃ࢟ࢫࢱࣥ࡟࠾ࡅࡿ኱Ỉᐖࢆዎᶵ࡟ࣘࢿࢫࢥ࡜ICHARMࡀ୰ᚰ࡜࡞ࡗ࡚㐍ࡵ࡚࠸ࡿࣉ
ࣟࢪ࢙ࢡࢺࠕࣃ࢟ࢫࢱࣥ࡟࠾ࡅࡿὥỈண㆙ሗཬࡧ⟶⌮⬟ຊࡢᡓ␎ⓗᙉ໬ࠖࡢ୍⎔࡜ࡋ࡚ཧຍࡋࡓࠋ
z
Mr. RANA MUHAMMAD ATIF, Pakistan Meteorological Department
z
Mr. MUHAMMAD ALEEM UL HASSAN RAMAY, Pakistan Meteorological Department
z
Mr. AHMAD ALI GUL, Pakistan Space and Upper Atmosphere Research Commission
(SUPARCO)
1.6 ᮏࢥ࣮ࢫࡢᣦᑟయไ
ᮏࢥ࣮ࢫ࡟࠾ࡅࡿ ICHARM ࡢᣦᑟయไࡣ௨ୗࡢ㏻ࡾ࡛࠶ࡿࠋ࡞࠾ࠊ඲ဨ GRIPS ࠿ࡽ㐃ᦠᩍᐁ࡜ࡋ࡚
௵࿨ࡉࢀ࡚࠸ࡿࠋ
㸦⊂㸧ᅵᮌ◊✲ᡤ Ỉ⅏ᐖ࣭ࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺᅜ㝿ࢭࣥࢱ࣮㸦ICHARM㸧
㐃ᦠᩍᤵ㸦ICHARM ࢭࣥࢱ࣮㛗㸧
➉ෆ 㑥Ⰻ
㐃ᦠᩍᤵ㸦ICHARM ◊✲࣭◊ಟᣦᑟ┘㸧
Jayawardena Amithirigala
㐃ᦠᩍᤵ㸦ICHARM ࢢ࣮ࣝࣉ㛗㸧
⏣୰ ⱱಙ
㐃ᦠᩍᤵ㸦ICHARM ୖᖍ◊✲ဨ㸧
ⴥ ோ㢼㸦2012.4 ࠿ࡽ㸧
㐃ᦠ෸ᩍᤵ㸦ICHARM ୖᖍ◊✲ဨ㸧
῝ぢ ࿴ᙪ
㐃ᦠ෸ᩍᤵ㸦ICHARM ◊✲ဨ㸧
ⴙ▮ ᩔၨ
㐃ᦠ෸ᩍᤵ㸦ICHARM ◊✲ဨ㸧
బᒣ ᩗὒ
ࡑࡢ௚ࠊᏛ⏕ࡢ◊✲ࢸ࣮࣐࡟ᛂࡌ࡚ࠊᙜヱศ㔝ࡢᑓ㛛࡛࠶ࡿ ICHARM ◊✲ဨࡀ㐺ᐅᣦᑟࢆ⾜ࡗࡓࠋ
6
Chapter 2: ᮏࢥ࣮ࢫࡢෆᐜ
2.1 ࢥ࣮ࢫࢫࢣࢪ࣮ࣗࣝ
Dec.
Feb.
Lectures
Orientation
Exercises
IndividualStudy
Individual Study
(Master Thesis)
Inception
Report
1st
Presen
Apr.
QualificationScreening
Oct.
Jun.
IndividualStudy
(MasterThesis)
Degree
Progra m
NonͲdegree
tra i ning
progra m
(NonͲdegree exercise)
3rd
Presen
2nd
Presen
Aug.
Oct.
Action
Plan
Action
Plan
Final
4th
5th
Presen Presen Presen
Submissiontosupervisor
Submissiontoexaminer
SubmissiontoGRIPS
Field Trip
ᅗ 2-1 ࢥ࣮ࢫ඲యࢫࢣࢪ࣮ࣗࣝᴫᛕᅗ
ᮏࢥ࣮ࢫࡢᮇ㛫ࡣࠊ2011 ᖺ 10 ᭶ 2 ᪥㸦᮶᪥᪥㸧࠿ࡽ 2012 ᖺ 9 ᭶ 15 ᪥㸦㞳᪥᪥㸧ࡲ࡛ࡢ⣙ 1 ᖺ㛫࡛
࠶ࡿࠋGRIPS ࡛ࡢධᏛᘧࡣ 2011 ᖺ 10 ᭶ 3 ᪥ࠊಟ஢ᘧࡣ 2012 ᖺ 9 ᭶ 14 ᪥࡛࠶ࡿࠋ
ᮏࢥ࣮ࢫࡢ඲యࢫࢣࢪ࣮ࣗࣝࡢᴫᛕᅗࢆᅗ 2-1 ࡟♧ࡍࠋ
ࢥ࣮ࢫ๓༙㸦10 ᭶㹼3 ᭶㸧࡛ࡣ୺࡟ࠕLectures㸦ㅮ⩏㸧
ࠖ
㸦11 ⛉┠㸧ཬࡧࠕExercises㸦₇⩦㸧
ࠖ
㸦6 ⛉┠㸧
ࢆᐇ᪋ࡍࡿࠋࡉࡽ࡟ㅮ⩏ࡢ⌮ゎࢆ῝ࡵࡿࡓࡵ࡟ࠊ1 ᖺ㛫ࢆ㏻ࡌ࡚ᩘᅇࠕField Trip㸦⌧ᆅどᐹ㸧
ࠖࢆ⾜࠺ࠋ
ࡲࡓࠊICHARM ࡀᑓ㛛ᐙࢆᣍ࠸࡚㐺ᐅᐇ᪋ࡍࡿ“ICHARM R&D Seminar”࡟Ꮫ⏕ࢆཧຍࡉࡏ࡚ࠊỈ㛵㐃
⅏ᐖ࡟㛵ࡍࡿ᭱᪂ࡢ▱㆑ࡸືྥ࡟ゐࢀࡿᶵ఍ࢆ୚࠼ࡿࠋ
3 ᭶ᚋ༙࡟ࡣࠕQualification Screeningࠖࢆᐇ᪋ࡋࠊಟኈㄽᩥࢆ᭩ࡃࡇ࡜ࡢ࡛ࡁࡿ▱㆑ࣞ࣋ࣝ࡟㐩ࡋ࡚
࠸ࡿ࠿ࢆ ICHARM ᣦᑟᩍᐁ࡟ࡼࡗ࡚ᑂᰝࢆ⾜࠺ࠋ
ࢥ࣮ࢫᚋ༙
㸦4 ᭶㹼9 ᭶㸧
࡛ࡣ୺࡟ࠊ
ࡑࢀࡒࢀࡢᣦᑟᩍᐁ
㸦ICHARM ◊✲ဨ࡞࡝㸧
࡜┦ㄯࡋࡘࡘ
ࠕIndividual
Study㸦ಶே◊✲㸧
ࠖ
㸦1 ⛉┠㸧ࢆ⾜࠸ࠊಟኈㄽᩥࢆసᡂࡍࡿࠋ1㹼2 ࣨ᭶࡟ 1 ᅇ⛬ᗘࠊಟኈㄽᩥࡢ㐍ᤖࢆ☜
ㄆࡍࡿࡓࡵ࡟ࠊ୍ே࠶ࡓࡾ 10 ศ⛬ᗘ࡛ྛᏛ⏕ࡀⓎ⾲ࢆ⾜࠺ࠕInterim Presentationࠖࢆᐇ᪋ࡋࠊ௚ࡢᏛ⏕
ࡸᣦᑟᩍᐁ࠿ࡽ㐺ᐅ࢔ࢻࣂ࢖ࢫࢆཷࡅࡿࠋಟኈㄽᩥᥦฟࠊJICA ເ㞟ᯟࡢᏛ⏕ࡣࠊᖐᅜᚋࡢάືෆᐜ࡟ࡘ
࠸࡚ࡢࠕAction Plan㸦࢔ࢡࢩࣙࣥࣉࣛࣥ㸧
ࠖసᡂ࡟ྲྀࡾ࠿࠿ࡿࠋ
ᮏࢥ࣮ࢫࡢ୺࡞ᖺ㛫ࢫࢣࢪ࣮ࣗࣝࢆ⾲ 2-1 ࡟♧ࡍࠋࡲࡓࠊᮏࢥ࣮ࢫ඲యࡢヲ⣽᪥⛬⾲ࡣࠊཧ⪃㈨ᩱ 2-1
࡟♧ࡍࠋ
7
⾲ 2-1 ୺࡞ᖺ㛫ࢫࢣࢪ࣮ࣗࣝ
Date
2011
October
3rd
7th
12th
18th
19th -25th
27th
28th
November
December
2012
January
February
March
1st
10th
22nd
9th
13th
10th - 12th
16th
23rd -2nd
3rd – 4th
14th
Event
Entrance Guidance & Orientation at GRIPS
Ph.D. & M.Sc. Joint Opening Ceremony at ICHARM
Joint lectures with students of DMP earthquake/Tsunami Course
Site visit of PWRI experimental facilities
Presentation on Inception Report
Individual discussion with ICHARM researchers
Site Visit (1) River in Japan (Ara River)
Site Visit (2) Flood Information (MLIT Kanto Regional Office) &
Metropolitan Area Outer Underground Discharge Channel
Lecture & Site visit at JAXA
Site Visit (3) Kuki City & Watarase Retarding Basin
Site Visit (4) River improvement in urban area (Tokyo Shirako River)
Site Visit (5) Integrated flood management (Tsurumi River)
ICHARM R&D Seminar by Prof. Koike & Prof. Asaeda
Exercise on Project Cycle Management (PCM)
1st Interim Presentation
Lectures at GRIPS
Site Visit (6) Northern Part of Kyusyu Region
Hydraulic Experiment
9th
14th – 16th
2nd Interim Presentation
Site Visit (7) Chugoku & Kinki Region (Hii River, Ota River, Kamenose
Landslide, etc.)
24th
3rd Interim Presentation
18th
19th
21st
22nd
Lecture & Site visit at Japan Meteorological Agency
Site Visit (8) Flood Fighting Drill in Tone River (Kurihashi)
Site Visit (9) Dam & Sabo Project (Ikari Dam & Kawaji Dam, Ashio
Sabo)
Hydraulic Experiment using ADCP in Tone River
4th Interim Presentation
ICHARM R&D Seminar by Mr. Eisa Bozorgzadeh and Dr. Saied Yosefi
Deadline of submission of the 1st draft thesis
5th Interim Presentation
Deadline of submission of the 2nd draft thesis
Final Presentation at ICHARM
Deadline of submission of the complete draft thesis
Submission of Master Thesis to GRIPS
JSCE Annual Meeting at Nagoya Univ.
Site Visit (10) Shingu City and Ise City
ICHARM R&D Seminar by Mr. Imbe (ARSIT)
Presentation on Action Plan
Closing Ceremony at JICA
Graduation Ceremony at GRIPS
April
May
June
1st
11th
July
6th
10th
27th
August
10th
16th
27th
September 6th
7th -8th
11th
12th
13th
14th
8
2.2 ࢥ࣮ࢫ࣒࢝ࣜ࢟ࣗࣛ
2.2.1 ㅮ⩏࣭₇⩦
ᮏࢥ࣮ࢫࡣࠊᐇົ࡬ࡢᛂ⏝ࢆ㔜どࡍࡿㄢ㢟ゎỴᆺࢥ࣮ࢫ࡛࠶ࡿࡓࡵࠊỈ⅏ᐖࣜࢫࢡ࣐ࢿࢪ࣓ࣥࢺ࡟㛵ࡍ
ࡿᇶ♏Ꮫ⩦ࡔࡅ࡛ࡣ࡞ࡃࠊᛂ⏝Ꮫ⩦ࡸ₇⩦ࢆከࡃྲྀࡾධࢀ࡚࠸ࡿࡢࡀ≉ᚩ࡛࠶ࡿࠋ
ᮏࢥ࣮ࢫࡢᒚಟ⛉┠୍ぴ⾲ࡣ⾲ 2-2 ࡢ㏻ࡾ࡛࠶ࡿࠋィ 18 ⛉┠࡛ᵓᡂࡉࢀ࡚࠾ࡾࠊ3 ࡘࡢ࢝ࢸࢦ࣮ࣜ㸦I:
Required Course, II: Recommended Course, III Elective Course ࡟ศ㢮ࡉࢀ࡚࠸ࡿࠋᇶᮏⓗ࡟ࠊ୺࡟ㅮ⩏
࠿ࡽᵓᡂࡉࢀࡿ⛉┠ࡣ Recommended Course ࡟ࠊ₇⩦࠿ࡽᵓᡂࡉࢀࡿ⛉┠ࡣ Elective Course ࡜ࡋ࡚࠸
ࡿࠋ
ྛ⛉┠ࡣ 15 ࢥ࣐࠿ࡽᵓᡂࡉࢀ࡚࠾ࡾࠊRecommended Course ࡣ඲࡚ᚲಟ㸦2 ༢఩㸧
ࠊElective Course
ࡣ඲࡚㑅ᢥ㸦1 ༢఩㸧
ࠊࡑࡋ࡚ Individual Study㸦ಶேᏛ⩦㸧ࡣ 10 ༢఩࡛࠶ࡿࠋಟኈྕྲྀᚓࡢࡓࡵ࡟ࡣࠊ
᭱ప 30 ༢఩ࢆྲྀᚓࡏࡡࡤ࡞ࡽࡎࠊ࠿ࡘࡑࡢ࠺ࡕ 16 ༢఩ࡣ Recommended Course ࠿ࡽྲྀᚓࡋ࡞ࡅࢀࡤ࡞
ࡽ࡞࠸ࠋࡑࡢୖ࡛ㄽᩥᑂᰝ࡟ྜ᱁ࡍࢀࡤࠊ
ࠕ㜵⅏ᨻ⟇ࠖࡢಟኈྕࡀྲྀᚓ࡛ࡁࡿࠋ࡞࠾ࠊ༢఩ୖࡣᚲࡎࡋࡶ඲
࡚ࡢ⛉┠ࢆཷㅮࡍࡿྲྀᚓࡍࡿᚲせࡣ࡞࠸ࡀࠊᮏࢥ࣮ࢫࡢᏛ⏕ࡣ඲࡚ࡢ⛉┠ࢆཷㅮࡋ࡚࠸ࡿࠋ
ྛ⛉┠ࡢෆᐜࡣࠊ1.3 ࡛ᣲࡆࡓᮏࢥ࣮ࢫ࢔࢘ࢺࣉࢵࢺ࡟ࡣ⾲ 2-3 ࡢࡼ࠺࡟ᑐᛂࡍࡿࠋ
ཧ⪃㈨ᩱ 2-2 ࡟ྛ⛉┠ࡢ୍࣒࢝ࣜ࢟ࣗࣛぴ⾲ࢆࠊཧ⪃㈨ᩱ 2-3 ࡟ GRIPS ࡢ࣮࣒࣮࣍࣌ࢪୖ࡛ࡶබ㛤ࡉ
ࢀࡿྛ⛉┠ࡢࢩࣛࣂࢫࢆࡑࢀࡒࢀ♧ࡍࠋ
2.2.2 ㅮᖌ࣭ᣦᑟᩍᐁ
ྛ⛉┠ࡢㅮᖌ࡟ࡣࠊICHARM ◊✲ဨࡔࡅ࡛ࡣ࡞ࡃࠊᅵᮌ◊✲ᡤ࣭ᅜᅵᢏ⾡ᨻ⟇⥲ྜ◊✲ᡤཬࡧ኱Ꮫ࠿
ࡽࡶከࡃࡢㅮᖌࢆᣍࡁࠊᏛ⏕ࡀ᭱᪂ࡢ᝟ሗࢆᏛ⩦࡛ࡁࡿࡼ࠺ດࡵࡿࠋ⾲ 2-4 ࡟♧ࡍࡼ࠺࡟ࠊㅮᖌᩘ࠾ࡼࡧ
ᣦᑟᩍᐁࡢᩘࡣࠊ኱Ꮫ࠿ࡽ 12 ྡࠊ⊂❧⾜ᨻἲே࣭㈈ᅋἲே࣭ᰴᘧ఍♫ࡢ◊✲ᡤ࡞࡝࠿ࡽ 16 ྡࠊෆ㛶ᗓ࣭
ᅵᮌ◊✲ᡤ࣭ᅜ⥲◊࠿ࡽ 7 ྡࠊICHARM ࠿ࡽࡣ 15 ྡࡢࠊෆ㒊ㅮᖌ࣭እ㒊ㅮᖌྵࡵ࡚ 50 ྡ࡜࡞ࡗࡓࠋ
࡞࠾ࠊᮏࢥ࣮ࢫࡢㅮ⩏࣭₇⩦࣭ಶே◊✲ࡢᐇ᪋࡟࠶ࡓࡗ࡚ࡣࠊICHARM ࢫࢱࢵࣇ࠾ࡼࡧ㈐௵ᩍᐁࡢ᪉ࠎ
ࢆ GRIPS ࡢ㐃ᦠᩍᐁ࡜ࡋ࡚ጤკࡋࠊᣦᑟࢆ௮ࡄࡇ࡜࡜ࡋ࡚࠸ࡿࠋ
2.2.3 ⌧ᆅどᐹ࠾ࡼࡧ㜵⅏⾜ᨻᢸᙜ⪅࠿ࡽࡢㅮ⩏
ᮏ◊ಟ࡛ࡣࠊ᪥ᮏࡢὥỈᑐ⟇࡟ࡘ࠸࡚⌧ᆅࡢ≧ἣࢆぢ⪺ࡋ࡞ࡀࡽࡼࡾ῝ࡃᏛࡪࡓࡵࠊICHARM ࡟࠾ࡅ
ࡿㅮ⩏࣭₇⩦ࡢ௚࡟ࠊ㐟ỈᆅࡸᨺỈ㊰ࠊࢲ࣒ࡸᆅ⁥ࡾᑐ⟇࡞࡝ࡢ⌧ᆅどᐹࢆᐇ᪋ࡍࡿࠋేࡏ࡚ࠊᅜᅵ஺㏻
┬ᆅ᪉஦ົᡤࡸᆅ᪉⮬἞య࡟㉱ࡁࠊᐇ㝿࡟ఫẸ࡜ࡢࡸࡾ࡜ࡾࡢ᭱๓⥺࡟❧ࡘ㜵⅏⾜ᨻᢸᙜ⪅࠿ࡽࠊ᪥ᮏࡢ
ὥỈ᝟ሗఏ㐩ࢩࢫࢸ࣒ࡸὥỈࣁࢨ࣮ࢻ࣐ࢵࣉ࡟㛵ࡋ࡚ㅮ⩏ࢆ㡬ࡁࠊ᪥ᮏࡢ㜵⅏⾜ᨻ࡟࠾ࡅࡿ⌧ሙ࡛ࡢㄢ㢟
࡞࡝࡟ࡘ࠸࡚⌮ゎࢆ῝ࡵࡿࠋ⾲ 2-5 ࡟どᐹ⟠ᡤ୍ぴࢆ♧ࡍࠋ
⌧ᆅどᐹඛࡣࠊㅮ⩏࡛⤂௓ࡉࢀࡓὥỈᑐ⟇᪋タࡸᡃࡀᅜ࡟࠾ࡅࡿ௦⾲ⓗ࡞ὥỈᑐ⟇᪋タࢆฟ᮶ࡿ㝈ࡾ⮬
ศࡢ┠࡛☜࠿ࡵࡽࢀࡿࡼ࠺㓄៖ࡋ࡚㑅ᐃࡋࡓࠋぢᏛᚋ࡟ࡣᏛ⏕࡟࣏࣮ࣞࢺᥦฟࢆㄢࡋࠊࡓࡔࡢ≀ぢ㐟ᒣ࡟
࡜࡝ࡲࡽࡎྛᏛ⏕ࡢ⌮ゎࢆ῝ࡵࡉࡏࡿࡼ࠺㓄៖ࡋࡓࠋཧ⪃㈨ᩱ 2-4 ࡟ྛ⌧ᆅどᐹࡢ⾜⛬⾲ࢆ♧ࡍࠋ
9
⾲ 2-2 ᒚಟ⛉┠୍ぴ⾲
10
⾲ 2-3 ྛ࢔࢘ࢺࣉࢵࢺ࡬㈉⊩ࡍࡿ⛉┠
Outputs
Subjects
1. To be able to explain basic Basic Hydrology
concept
and
generation
theory
process
water-related
of Hydraulics
disasters, Flood hydraulics and sediment transport
water-related
evaluation,
on Advanced Hydrology
hazard
disaster
management
policy
risk Mechanics of sediment transportation and river changes
risk Sustainable reservoir development & management
and Control measures for landslide & debris flow
technologies.
Computer Programming
Practice on Flood Hazard Modeling & Flood Forecasting
2. To be able to explain basic Disaster management policy
concept and theory on flood Disaster risk management
countermeasures
including Basic concepts of IFRM: Integrated Flood Risk Management
landslide and debris flow.
3.
To
formulate
Urban Flood Management and Flood Hazard Mapping
the Individual study
countermeasures to solve the Action Plan
problems and issues concerning
water-related disasters in their
countries
techniques
by
applying
and
knowledge
acquired through the program.
11
⾲ 2-4 ㅮᖌ୍ぴ⾲㸦ᙺ⫋ࡣᙜ᫬ࡢࡶࡢ㸧
Lecturer
University
Prof. Shigeru Morichi
Prof. Muneo Hori
Asso. Prof. Kazushi Sano
Prof. Kenji Okazaki
Prof. Guangwei Huang
Prof. Taikan Oki
Prof. Shigeko Haruyama
Prof. Haruo Hayashi
Affiliation
GRIPS
University of Tokyo
Nagaoka Univ. of Technology
GRIPS
Sophia University
University of Tokyo
Mie University
Prof. Shoji Fukuoka
Disaster Prevention Research Institute, Kyoto
University
Chuo University
Prof. Yasuharu Watanabe
Kitami Institute of Technology
Prof. Tetsuya Sumi
Prof. Katsuo Sasahara
Kyoto University
Kochi University
Private sectors, and others
Dr. Hiroshi Oyama
Mr. Masahiro Imbe
Institution For Transport Policy
Studies
Japan Aerospace Exploration Agency
(JAXA)
Japan Aerospace Exploration Agency
(JAXA)
Institute for International Development,
Disaster Prevention and Peace Inc.
Association for Rainwater Storage and Infiltration Technology
Prof. Shinji Egashira
NEWJEC Inc.
Dr. Tadahiko Sakamoto
Prof. Norihisa Matsumoto
Dr. Josuke Kashiwai
Dr. Hiroshi Ikeya
Japan Commission on Large
Dams
Japan Dam Engineering Center
Japan Dam Engineering Center
Sabo Technical Center
Dr. Yoshihumi Hara
Japan Sabo Asssociation
Dr. Kazuyuki Takanashi
Asia Air Survey Co., Ltd.
Dr. Ryosuke Tsunaki
Sabo Technical Center
Dr. Kazunori Fujisawa
Nippon Expressway Company
Dr. Misako Kachi
Dr. Takuji Kubota
Mr. Masayuki Watanabe
12
Lecture
Disaster Mitigation Policy
Disaster Mitigation Policy
Disaster Mitigation Policy
Disaster Risk Management
Hydraulics
Basic Concepts of IFRM
Urban Flood Management and Flood Hazard
Mapping
Urban Flood Management and Flood Hazard
Mapping
Flood Hydraulics and Sediment
Transport
Flood Hydraulics and Sediment
Transport
Sustainable Reservoir Development & Management
Control Measures for Landslide & Debris
Flow
Disaster Mitigation Policy
Basic Hydrology
Basic Hydrology
Basic Concepts of IFRM
Urban Flood Management and Flood Hazard
Mapping
Mechanics of Sediment Transportation and
River Changes
Sustainable Reservoir Development & Management
Sustainable Reservoir Development & Management
Sustainable Reservoir Development & Management
Control Measures for Landslide & Debris
Flow
Control Measures for Landslide & Debris
Flow
Control Measures for Landslide & Debris
Flow
Control Measures for Landslide & Debris
Flow
Control Measures for Landslide & Debris
Ms. Keiko Kita
GLM Institute
Ms. Fumiko Iseki
GLM Institute
Flow
Practice on Local Disaster Management
Plan
Practice on Local Disaster Management
Plan
Cabinet Office, NILIM, PWRI
Mr. Shigeo Ochi
Cabinet Office
Disaster Risk Management
Mr. Tomoya Nagai
Cabinet Office
Disaster Risk Management
Dr. Shigeki Unjo
National Institute for Land and
Disaster Mitigation Policy
Infrastructure Management (NILIM)
Dr. Kunihiko Amano
National Institute for Land and
Sustainable Reservoir Development & Management
Infrastructure Management (NILIM)
Dr. Nobutomo Osanai
Public Works research Institute
Control Measures for Landslide & Debris
(PWRI)
Flow
Prof. Yoshikazu Yamaguchi
Public Works research Institute
Sustainable Reservoir Development & Management
(PWRI)
Dr. Hitoshi Umino
Public Works research Institute
Sustainable Reservoir Development & Management
(PWRI)
ICHARM
Prof. Kuniyoshi Takeuchi
Basic Concepts of IFRM, Master’s Thesis
Prof. Shigenobu Tanaka
Urban Flood Management and Flood Hazard Mapping, Practice on Local Disaster
Management Plan, Master’s Thesis
Prof. Amithirigala
Basic Hydrology, Advanced Hydrology, Practice on Advanced Hydrology,
JAYAWARDENA
Master’s Thesis
Asso. Prof. Kazuhiko Fukami
Practice on Flood Hazard Modeling & Flood Forecasting,
Master’s Thesis
Mr. Minoru Kamoto
Master’s Thesis
Asso. Prof. Takahiro
Computer Programming, Practice on Flood Hazard Modeling &
Sayama
Flood Forecasting, Master’s Thesis
Mr. Seishi Nabesaka
Practice on Flood Hazard Modeling & Flood Forecasting,
Dr. Atsuhiro Yorozuya
Practice on Hydraulics, Master’s Thesis
Dr. Kwak Young Joo
Practice on Local Disaster Management Plan, Master’s Thesis
Dr. Akira Hasegawa
Computer Programming, Master’s Thesis
Dr. Tomoki Ushiyama
Computer Programming, Master’s Thesis
Dr. Ai Sugiura
Practice on Flood Hazard Modeling & Flood Forecasting,
Master’s Thesis
Dr. Mamoru Miyamoto
Practice on Flood Hazard Modeling & Flood Forecasting,
Master’s Thesis
Mr. Susumi Fujioka
Practice on Flood Hazard Modeling & Flood Forecasting
Dr. Megumi Sugimoto
Master’s Thesis
13
⾲ 2-5 どᐹ⟠ᡤ୍ぴ
᪥᫬
2011 ᖺ
10 ᭶
27 ᪥
ሙᡤ
Ⲩᕝୗὶᇦ
10 ᭶
28 ᪥
㛵ᮾᆅ᪉ᩚഛᒁ
㤳㒔ᅪእ㒌ᨺỈ㊰
11 ᭶
10 ᪥
11 ᭶
22 ᪥
12 ᭶
9᪥
2012 ᖺ
3᭶
14 ᪥
3᭶
15 ᪥
3᭶
16 ᪥
5᭶
18 ᪥
5᭶
19 ᪥
5᭶
21 ᪥
ෆᐜ
ேᕤᨺỈ㊰㸦㛤Ỉ㊰㸧
Ⲩᕝࣟࢵࢡࢤ࣮ࢺ㸦㛮㛛㸧
ࢫ࣮ࣃ࣮ሐ㜵
஦ົᡤ⅏ᐖᑐ⟇ᐊ
Ἑᕝᩜࡢ฼⏝
ᾋ㛫㜵⅏ࢫࢸ࣮ࢩࣙࣥ
ὥỈ᝟ሗఏ㐩ࢩࢫࢸ࣒ࡸὥỈணሗ࡟
ࡘ࠸࡚ࡢㅮ⩏
ὥỈணሗᐊどᐹ
ேᕤᨺỈ㊰㸦㛢Ỉ㊰㸧
฼᰿ᕝὶᇦ
㸦ஂ႐ᕷᰩᶫ㸧
ὥỈࣁࢨ࣮ࢻ࣐ࢵࣉ
ࡲࡿࡈ࡜ࡲࡕࡈ࡜ࣁࢨ࣮ࢻ࣐ࢵࣉ
ἙᕝỈ఩⾲♧ሪ
ᰩᶫ㥐࡟࠾ࡅࡿἙᕝ᝟ሗᥦ౪
࢝ࢫ࣮ࣜࣥྎ㢼Ỵቯᆅ
ΏⰋ℩ᕝୗὶᇦ
ΏⰋ℩㐟Ỉᆅ
ⓑᏊᕝὶᇦ
኱㒔ᕷࡢேཱྀ⛻ᐦ㒊࡟࠾ࡅࡿ୰ᑠἙ
▼⚄஭ᕝὶᇦ
ᕝࡢὥỈᑐ⟇
࣭ⓑᏊᕝㄪᩚụ⩌
࣭ⓑᏊᕝ࣭▼⚄஭ᕝἙᕝᨵಟ
㭯ぢᕝὶᇦ
㭯ぢᕝ㐟Ỉᆅ
㟝ࡀୣ㐟Ỉᆅ
ᜠᘔබᅬᆅୗㄪᩚụ
ಶேᏯ㈓␃ᾐ㏱᪋タ
ᩫఀᕝὶᇦ
኱ᶫᕝࢥ࣑ࣗࢽࢸ࢕ࢭࣥࢱ࣮
ᩫఀᕝᨺỈ㊰ᘓタ⌧ሙ
ᑿཎࢲ࣒
ኴ⏣ᕝୗὶᇦ
㧗℩ሖࠊ◁㜵᪋タࠊ♲ᅬỈ㛛ࠊ
ඖᏳᕝぶỈࢸࣛࢫ
㜰⚄࣭ῐ㊰኱㟈⅏グᛕ ⅏ᐖ᚟ᪧ࡜᚟⯆
ே࡜㜵⅏ᮍ᮶ࢭࣥࢱ࣮
኱࿴ᕝὶᇦ
டࡢ℩ᆅࡍ࡭ࡾ
Ẽ㇟ᗇ
฼᰿ᕝὶᇦ
㨣ᛣᕝୖὶᇦ
ΏⰋ℩ᕝୖὶᇦ
5᭶
22 ᪥
9᭶
6᪥
฼᰿ᕝὶᇦ
9᭶
7᪥
ᐑᕝୗὶᇦ
⇃㔝ᕝὶᇦ
༠ຊ஦ົᡤ
ᅜᅵ஺㏻┬
ⲨᕝୗὶἙᕝ஦ົᡤ
ᅜᅵ஺㏻┬
㛵ᮾᆅ᪉ᩚഛᒁ
Ἑᕝ㒊
ᅜᅵ஺㏻┬
ỤᡞᕝἙᕝ஦ົᡤ
ᅜᅵ஺㏻┬
฼᰿ᕝୖὶἙᕝ஦ົᡤ
ᮾி㒔ᘓタᒁ
ᅜᅵ஺㏻┬
ி὾Ἑᕝ஦ົᡤ
ᅜᅵ஺㏻┬
ฟ㞼Ἑᕝ஦ົᡤ
ᅜᅵ஺㏻┬
ኴ⏣ᕝἙᕝ஦ົᡤ
ᅜᅵ஺㏻┬
኱࿴ᕝἙᕝ஦ົᡤ
Ẽ㇟ᗇ
ㅮ⩏ࠕᡃࡀᅜࡢẼ㇟ணሗᴗົࠊ
ᣦᐃἙᕝ࡟࠾ࡅࡿὥỈணሗࠖ
ࠕ➨ 61 ᅇ฼᰿ᕝỈ⣔㐃ྜỈ㜵₇⩦ࠖ ᅜᅵ஺㏻┬
ぢᏛ
㛵ᮾᆅ᪉ᩚഛᒁ
ᕝ἞ࢲ࣒࣭஬༑㔛ࢲ࣒㐃ᦠ஦ᴗ
ᅜᅵ஺㏻┬
㨣ᛣᕝࢲ࣒⤫ྜ⟶⌮஦ົᡤ
㊊ᑿ◁㜵஦ᴗ
ᅜᅵ஺㏻┬
ΏⰋ℩ᕝἙᕝ஦ົᡤ
฼᰿኱ሖ
㸦⊂㸧Ỉ㈨※ᶵᵓ
฼᰿ᑟỈ⥲ྜ஦ົᡤ
⿕⅏⪅࡬ࡢᨭ᥼஦ᴗ
࿴ḷᒣ┴᪂ᐑᕷ
≉Ṧሐ㸦㍯୰㸧
ᅜᅵ஺㏻┬
⣖༡Ἑᕝᅜ㐨஦ົᡤ
ᆅᇦ㜵⅏ࡢྲྀࡾ⤌ࡳ
㸦㜵⅏࣐ࢵࣉ࡞࡝㸧
14
ఀໃᕷ኱‖᣺⯆఍
2.2.4 Ꮫ⩦࣭⏕ά⎔ቃ
⾲ 2-6 1 ᪥ࡢ᫬㛫๭
ᮏࢥ࣮ࢫ࡟࠾ࡅࡿᤵᴗ᫬㛫ࡣࠊ㏻ᖖࡢ኱Ꮫ➼࡜ྠ➼ࡢ 1 ࢥ
1st period
9:00-10:30
࣐ 90 ศ࡜ࡋࠊ1 ᪥ࡢ᫬㛫๭ࡣ⾲ 2-6 ࡢ㏻ࡾ࡛࠶ࡿࠋᏛ⏕ࡣࠊ
2nd period
10:45-12:15
JICA ⟃Ἴ㸦Ⲉᇛ┴ࡘࡃࡤᕷ㧗㔝ྎ㸧࡟ᅾࡋࠊJICA ࡀᡤ᭷
3rd period
13:15-14:45
ࡋ࡚࠸ࡿࣂࢫ࡟࡚ẖ᪥㏻Ꮫࡍࡿࠋ
4th period
15:00-16:30
ࡲࡓࠊ᫖ᖺᗘ࡜ྠᵝ࡟ࠊࢥ࣮ࢫ๓༙ࡢ 10 ᭶࠿ࡽ 3 ᭶ࡲ࡛
ࡣ᪥᭰ࢃࡾࡢ᪥┤ไᗘࢆタࡅ࡚ࠊḞᖍ⪅☜ㄆࡸㅮ⩏⤊஢ᚋࡢ࣍࣡࢖ࢺ࣮࣎ࢻᾘࡋࠊᡞ⥾ࡲࡾ࣭ᾘⅉࡢ☜ㄆ
࡞࡝ࢆ⾜ࢃࡏࠊ1 ᪥ࡢ⤖ᯝࢆ⡆༢࡟ࠕ᪥┤ࢩ࣮ࢺࠖ
㸦A4 1 ᯛ㸧࡟ࡲ࡜ࡵࡉࡏࡿࠋಶே◊✲ࡀ୰ᚰ࡜࡞ࡿࢥ࣮
ࢫᚋ༙ࡢ 4 ᭶࠿ࡽ 9 ᭶࡟ࡘ࠸࡚ࡣࠊ㐌᭰ࢃࡾ࡛Ḟᖍ⪅ࡢ☜ㄆࡸࡑࡢ㐌ࡢࡲ࡜ࡵ࡞࡝ࢆሗ࿌ࡉࡏࡿࠋ
2.3 ಟኈㄽᩥ
ᮏࢥ࣮ࢫࡣ๓㏙ࡢ㏻ࡾࠊࠕᢲࡋࡘࡅࡢ◊ಟ࡛ࠖࡣ࡞ࡃࠊࠕ⮬ࡽ⪃࠼ࠊㄢ㢟ࢆゎỴࡍࡿ◊ಟࠖࢆ┠ᣦࡋ
ࡓ”Problem Solving-Oriented” course 㸦ㄢ㢟ゎỴᆺ◊ಟ㸧ࢆ≉ᚩࡢ୍ࡘ࡜ࡋ࡚࠸ࡿࠋࡇࢀ࡟ᇶ࡙ࡁࠊᮏ
ࢥ࣮ࢫࡢಟኈㄽᩥ࡛ࡣࠊᏛ⏕ࡀ⮬ࡽ⮬ᅜࡢㄢ㢟ゎỴ࡟㛵ࢃࡿࢸ࣮࣐ࢆ◊✲ࡍࡿࡇ࡜࡟ࡋ࡚࠾ࡾࠊࡑࡢ⤖ᯝ
࡜ࡋ࡚ࠊ⥲ྜⓗ࡞Ỉ⅏ᐖ⿕ᐖ㍍ῶࡢ⥲ྜⓗィ⏬❧᱌ࡀྍ⬟࡞ேᮦ⫱ᡂࡀᅗࡽࢀࠊᖐᅜᚋࡢ⮬ᅜ࡛ࡢㄢ㢟ゎ
Ỵಁ㐍࡟ࡶᙺ❧ࡘࡇ࡜ࡀᮇᚅࡉࢀࡿࠋ
ࡑࡢࡓࡵࠊࡲࡎᮏࢥ࣮ࢫ㛤ጞ᪩ࠎ࡟ࠊ⮬ᅜࡀᢪ࠼ࡿỈ⅏ᐖ࡟㛵ࡍࡿㄢ㢟ࡸಟኈㄽᩥࡢᑐ㇟ணᐃ࡜ࡍࡿ
ࢱ࣮ࢤࢵࢺ࢚ࣜ࢔࡟㛵ࡍࡿ᝟ሗࠊࣉࣟࢪ࢙ࢡࢺᒚ⾜࡟㛵ࡍࡿᚲせ࡞⾜ື࡟ࡘ࠸࡚ྛᏛ⏕࠿ࡽ⤂௓ࡉࡏࡿሙ
࡜ࡋ࡚“Inception Report”Ⓨ⾲఍ࢆ㛤ദࡍࡿࠋࡑࡢᚋࠊICHARM ᣦᑟᩍᐁ࡜Ꮫ⏕ࡀࠊྲྀࡾ⤌ࡳࡓ࠸ࢸ࣮࣐
࡟ࡘ࠸࡚ヰࡋྜ࠸ࢆ⾜࠸ࠊㅮ⩏࣭₇⩦ࡀ࡯ࡰ⤊஢ࡋࡓ 2012 ᖺ 3 ᭶ୗ᪪࠿ࡽᮏ᱁ⓗ࡟ྛ⮬ࡢ◊✲ࢸ࣮࣐࡟
ྲྀࡾ⤌ࡲࡏࡿࠋㄽᩥᥦฟ⥾ࡵษࡾࡣ 2012 ᖺ 8 ᭶ୗ᪪࡛࠶ࡾࠊࡑࡢᚋ GRIPS ෆ࡛ྜྰᑂᰝ఍ࡀᐇ᪋ࡉࢀࠊ
ಟኈྕࡀᤵ୚ࡉࢀࡿ࠿ุ᩿ࡀ⾜ࢃࢀࡿࠋ
15
Chapter 3㸸 2011-2012 ᖺᗘάືሗ࿌
ᨻ⟇◊✲኱Ꮫ㝔኱Ꮫṇ㛛๓࡛㞟ྜ෗┿㸦2012 ᖺ 9 ᭶ 14 ᪥㸧
㸦ᮏ㈨ᩱ㞟ࡢෑ㢌࡟ࡲ࡜ࡵ࡚෗┿ࢆᥖ㍕ࡋ࡚࠸ࡿࡢ࡛ࠊ㐺ᐅཧ↷ࡢࡇ࡜㸧
ICHARM ࡣࠊ2011 ᖺ 10 ᭶ 2 ᪥࠿ࡽ 2012 ᖺ 9 ᭶ 15 ᪥ࡲ࡛⣙ 1 ᖺ㛫ࠊ
㸦⊂㸧ᅜ㝿༠ຊᶵᵓ㸦JICA㸧࠾
ࡼࡧᨻ⟇◊✲኱Ꮫ኱Ꮫ㝔኱Ꮫ㸦GRIPS㸧࡜㐃ᦠࡋࠊಟኈㄢ⛬ࠗ㜵⅏ᨻ⟇ࣉࣟࢢ࣒ࣛ Ỉ⅏ᐖࣜࢫࢡ࣐ࢿࢪ
࣓ࣥࢺࢥ࣮ࢫ࠘
㸦JICA ◊ಟྡࠕὥỈ㛵㐃⅏ᐖ㜵⅏ᑓ㛛ᐙ⫱ᡂࠖ
㸧ࢆᐇ᪋ࡋࡓࠋ
ᮏࢥ࣮ࢫࡢ┠ⓗࡣࠊ
ࠕᅜᐙࣞ࣋ࣝ࠿ࡽఫẸࡢࣞ࣋ࣝࡲ࡛ࡢ࠶ࡽࡺࡿࣞ࣋ࣝ࡟࠾࠸࡚ࠊ⤫ྜⓗ࡞Ἑᕝὶᇦ
࣐ࢿࢪ࣓ࣥࢺࡢᯟ⤌ࡳ࡛ࡢὥỈ࣐ࢿࢪ࣓ࣥࢺࡢィ⏬࡜ᐇ⾜࡟ᙺ❧ࡘࡇ࡜ࡀฟ᮶ࠊ☜ᅛࡓࡿ⌮ㄽ࡜ᢏ⾡࡟ᇶ
♏ࢆ⨨ࡃㄢ㢟ゎỴᆺᐇົ⪅ࢆ㣴ᡂࡍࡿࡇ࡜࡛ࠖ࠶ࡿࠋ
ᮏࢥ࣮ࢫࡢ≉ᚩ࡜ࡋ࡚ࡣࠊ1 ᖺ࡛ಟኈྕࢆྲྀᚓ࡛ࡁࡿࡇ࡜ࠊᏛ⏕ࡀ⮬ᅜ࡛ᐇ㝿࡟ᢪ࠼࡚࠸ࡿၥ㢟ࡢゎỴ
⟇ࢆᥦ᱌࡛ࡁࡿ⬟ຊࢆྥୖࡉࡏࡿࠗㄢ㢟ゎỴᆺ࠘ࡢ◊ಟ࡛࠶ࡿࡇ࡜ࠊཬࡧࠗ⌮ㄽࡼࡾᐇົ࠘ࢆ㔜どࡍࡿ◊
ಟ࡛࠶ࡿࡇ࡜࡞࡝ࡀᣲࡆࡽࢀࡿࠋ
ᮏᖺᗘࡢᏛ⏕ࡣࠊィ 19 ே㸦ࣂࣥࢢࣛࢹࢩࣗ 2 ྡࠊ୰ᅜ 2 ྡࠊࣇ࢕ࢪ࣮1 ྡࠊ࢖ࣥࢻࢿࢩ࢔ 2 ྡࠊࢿࣃ࣮
ࣝ 2 ྡࠊࣃ࢟ࢫࢱࣥ 6 ྡࠊࢫࣜࣛࣥ࢝ 1 ྡࠊࣇ࢕ࣜࣆࣥ 1 ྡࠊࢳࣗࢽࢪ࢔ 1 ྡࠊ࣋ࢺࢼ࣒ 1 ྡ㸧࡛࠶ࡗࡓࠋ
ࡇࢀࡽ 19 ྡࡣࠊ↓஦࡟ᑂᰝ࡟ྜ᱁ࡋ࡚ࠗಟኈ㸦㜵⅏ᨻ⟇㸧
࠘ࡢᏛ఩ࢆྲྀᚓࡋࠊᮏᅜ࡬ᖐᅜࡋࡓࠋ
2011 ᖺ 10 ᭶ 3 ᪥࡟ GRIPS ᰯ⯋㸦ᮾி࣭භᮏᮌ㸧࡟࡚ GRIPS ୺ദࡢධᏛᘧࡀ⾜ࢃࢀࠊᮏࢥ࣮ࢫࡣࢫ
ࢱ࣮ࢺࡋࡓࠋ
7 ᪥࡟ࡣᅵᮌ◊✲ᡤᖿ㒊㸦㨶ᮏ⌮஦㛗࣭኱▼⌮஦࣭⬥ᆏᆅ㉁┘㸧
ࠊICHARM 㛵ಀ⪅㸦➉ෆࢭࣥࢱ࣮㛗ࠊ
⏣୰ࢢ࣮ࣝࣉ㛗ࠊຍᮏୖᖍ◊✲ဨ㸧
ࠊJICA ⟃Ἴ㛵ಀ⪅㸦బ⸨ᡤ㛗ࠊ‫‮‬ὸ⫋ဨࠊⲨᮌ◊ಟ┘⌮ဨ㸧࠾ࡼࡧ
16
GRIPS ࠿ࡽᒸᓮᩍᤵࡀ⮫ᖍࡢࡶ࡜ࠊᅵᮌ◊✲ᡤ࡛㛤ㅮᘧࢆ⾜࠸ࠊ⚃㎡ࡀࡑࢀࡒࢀ࠿ࡽ㏙࡭ࡽࢀࡓᚋࠊᏛ
⏕ࢆ௦⾲ࡋ࡚ BARUN KUMAR KARNA Ặ㸦ࢿࣃ࣮ࣝ㸧ࡀࡇࡢࢥ࣮ࢫ࡬ࡢᢪ㈇ࢆ㏙࡭ࡓࠋ
ᮏࢥ࣮ࢫࡢᮇ㛫ࡣ⣙ 1 ᖺ㛫࡛࠶ࡿࡀࠊࢥ࣮ࢫ๓༙࡛ࡣỈ⅏ᐖ࡟㛵ಀࡍࡿㅮ⩏࣭₇⩦ࢆ㞟୰ⓗ࡟ᐇ᪋ࡋࠊ
ࢥ࣮ࢫᚋ༙ࡣಶே◊✲࡟ᑐࡍࡿ᫬㛫ࢆከࡃ඘࡚ࡓࠋࡲࡓࠊᅜෆࡢὥỈᑐ⟇࡟㛵ࡍࡿ⌧ሙ࡛ࡢ▱㆑ࢆᏛࡪࡓ
ࡵ࡟ࠊ㐺ᐅ⌧ᆅどᐹࢆᐇ᪋ࡋࡓࠋ
ࡲࡓࠊᮏࢥ࣮ࢫࡢㅮᖌ࡜ࡋ࡚ࡣࠊICHARM ࡢ◊✲ဨࡔࡅ࡛࡞ࡃࠊỈ⅏ᐖྛศ㔝ࡢ᭱ඛ➃ࡢ◊✲ࢆ⾜ࡗ
࡚࠸ࡿ◊✲⪅࡜ࡋ࡚ࠊᅵᮌ◊✲ᡤ࣭ᅜᅵᢏ⾡ᨻ⟇⥲ྜ◊✲ᡤ࠿ࡽࡔࡅ࡛࡞ࡃࠊᅜෆࡢྛ኱Ꮫ➼ࡢㅮᖌࡶᣍ
࠸࡚ࠊㅮ⩏ࢆ㡬࠸ࡓࠋ
㸺ㅮ⩏࣭₇⩦㸦10 ᭶㹼12 ᭶㸧㸼㸦ᙺ⫋ྡࡣᙜ᫬㸧
ࡲࡎࠊỈ⅏ᐖ࡬ࡢᑐฎࢆᏛࡪಟኈㄢ⛬࡜ࡋ࡚ᚲ㡲ࡢ▱㆑࡛࠶ࡿࠊὥỈ⅏ᐖ⟶⌮ࡸᆅ⌫ ᬮ໬࡟㛵ࡍࡿᇶ
ᮏⓗ࡞ᴫᛕࢆᏛࡤࡏࡿࡓࡵ࡟ࠊ➉ෆ㑥Ⰻ ᩍᤵ㸦ICHARM㸧
ࠊἈ኱ᖿ ᩍᤵ㸦ᮾி኱Ꮫ㸧
ࠊΏ㑓ṇᖾ ♫㛗㸦
㸦᭷㸧
ᅜ㝿♫఍㛤Ⓨ༠ຊ◊✲ᡤ㸧ࡽ࡟ࡼࡿࠕBasic Concepts of Integrated Flood Risk management (IFRM)ࠖࡢ
ㅮ⩏ࢆ⾜ࡗࡓࠋ
ᖹ⾜ࡋ࡚ࠊᮏࢥ࣮ࢫࡢᏛ⩦࡟Ḟ࠿ࡍࡇ࡜ࡢ࡛ࡁ࡞࠸▱㆑࡛࠶ࡿᚤ✚ศࢆ᚟⩦ࡍࡿࡓࡵ࡟ࠊⴙ▮ᩔၨ෸ᩍ
ᤵ㸦ICHARM㸧࡟ࡼࡿࠕPractices in Hydraulicsࠖࡢ₇⩦ࠊཬࡧỈ⌮Ꮫࡢᇶ♏ࢆ᚟⩦ࡍࡿࡓࡵࡢ㯤ග೧ ᩍ
ᤵ㸦ୖᬛ኱Ꮫ㸧࡟ࡼࡿࠕHydraulicsࠖࡢㅮ⩏ࢆᐇ᪋ࡋࡓࠋ
ࡲࡓࠊὥỈὶࡸᅵ◁㍺㏦࡟㛵ࡍࡿᇶ♏ཎ⌮ࢆᏛࡪࡓࡵ࡟ࠊ⚟ᒸᤩ஧ ᩍᤵ㸦୰ኸ኱Ꮫ㸧࡜Ώ㑔ᗣ⋞ ᩍᤵ
㸦໭ぢᕤᴗ኱Ꮫ㸧࡟ࡼࡿࠕFlood Hydraulics and Sediment Transportࠖࡢㅮ⩏ࡸࠊỤ㢌㐍἞ ᩍᤵ㸦
㸦ᰴ㸧
ࢽ࣮ࣗࢪ࢙ࢵࢡ㸧࡟ࡼࡿࠕMechanics of Sediment Transportation and River Changesࠖࡢㅮ⩏ࢆᐇ᪋ࡋ
ࡓࠋ
Jayawardena Amithirigala ᩍᤵ㸦ICHARM㸧࡟ࡼࡿࠕBasic Hydrologyࠖ
ࠕAdvanced Hydrologyࠖࡢ
ㅮ⩏࣭₇⩦ࡣࠊ10 ᭶࠿ࡽ 3 ᭶ୖ᪪࡟࠿ࡅ࡚ᐇ᪋ࡋࠊὥỈᑐ⟇ࡢᇶ♏ⓗࢹ࣮ࢱ࡜࡞ࡿྛ✀Ỉᩥࢹ࣮ࢱࡢᢅ࠸
࡟ࡘ࠸࡚ࠊ㉁࣭㔞࡜ࡶ࡟࠿࡞ࡾࡢෆᐜࢆᏛ⩦ࡉࡏࡓࠋࡲࡓࠊ㝆㞵ほ ࡟㛵ࡍࡿ᭱᪂ࡢ▱ぢࡢ⤂௓࡜ࡋ࡚ࠊ
῝ぢ࿴ᙪ෸ᩍᤵ㸦ICHARM㸧࠿ࡽࡣ࣮ࣜࣔࢺࢭࣥࢩࣥࢢ࡟㛵ࡍࡿㅮ⩏ࠊྍ▱⨾బᏊ ୺௵㛤Ⓨဨ࡜ஂಖ⏣
ᣅᚿ ◊✲ဨ㸦࡜ࡶ࡟㸦⊂㸧Ᏹᐂ⯟✵◊✲㛤Ⓨᶵᵓ㸦JAXA㸧Ᏹᐂ฼⏝࣑ࢵࢩࣙࣥᮏ㒊㸧࠿ࡽࡣ㝆㞵ࡢ⾨ᫍ
ほ ࡟㛵ࡍࡿㅮ⩏ࢆࡑࢀࡒࢀ㡬࠸ࡓࠋ
11 ᭶௨㝆ࡣࠊICHARM ◊✲ဨ࡟ࡼࡿྛ✀₇⩦ࢆ㛤ጞࡋࡓࠋ
ࠕPractice on Flood Hazard Modeling & Flood Forecastingࠖ₇⩦࡛ࡣࠊICHARM ࡀ㛤Ⓨࢆ㐍ࡵ࡚࠸
ࡿ Integrated Flood Analysis System (IFAS) ࡢά⏝ἲࢆᏛࡪࡓࡵ࡟ࠊ῝ぢ ࿴ᙪ ෸ᩍᤵࡀ୰ᚰ࡜࡞ࡾࠊ
㘠ᆏㄔᚿ ◊✲ဨࠊᮡᾆឡ ᑓ㛛◊✲ဨࠊᐑᮏᏲ ᑓ㛛◊✲ဨࠊ⸨ᒸዡ ஺ὶ◊✲ဨ࡟ࡼࡿ IFAS ₇⩦ࢆᐇ
᪋ࡋࡓࠋࡑࡢᚋࠊ㝆㞵~ỏ℃ࡢ௙⤌ࡳࢆࡼࡾ῝ࡃ⌮ゎࡍࡿࡓࡵ࡟ࠊబᒣᩗὒ ෸ᩍᤵ࡟ࡼࡿ㝆㞵ὶฟỏ℃ࣔ
ࢹࣝ(RRI ࣔࢹࣝ)ࡢㅮ⩏ࢆ⾜ࡗࡓࠋ
ࠕComputer Programmingࠖ₇⩦࡛ࡣࠊబᒣ ෸ᩍᤵࠊ∵ᒣ᭸౗ ᑓ㛛◊✲ဨࠊ㛗㇂ᕝ⪽ ᑓ㛛◊✲ဨࡀ
17
ᢸᙜࡋࠊࣇ࢛࣮ࢺࣛࣥ࡟ࡼࡿᩘ್ゎἲࢆᏛࢇࡔࠋ
㸺ㅮ⩏࣭₇⩦㸦1 ᭶㹼5 ᭶㸧㸼㸦ᙺ⫋ྡࡣᙜ᫬㸧
1 ᭶௨㝆ࡣࠊࡼࡾᛂ⏝ᐇ㊶ⓗ࡞ㅮ⩏࡜ࡋ࡚ࠊ
ࠕUrban Flood Management and Flood Hazard Mappingࠖ
ࡢㅮ⩏ࢆᐇ᪋ࡋࡓࠋᮏ⛉┠࡛ࡣࠊ⏣୰ⱱಙ ᩍᤵ㸦ICHARM㸧࡟ࡼࡿᡃࡀᅜࡢ㜵⅏ࢩࢫࢸ࣒ࡸἙᕝ᝟ሗࢩ
ࢫࢸ࣒࡟㛵ࡍࡿㅮ⩏ࠊ࠾ࡼࡧ⅏ᐖᚰ⌮Ꮫ࡟㛵ࡋ࡚ᯘ᫓⏨ ᩍᤵ㸦ி㒔኱Ꮫ㸧ࡸࠊὥỈࡢỏ℃ᇦࢆ▱ࡿୖ࡛㔜
せ࡞ᆅᙧᏛ࡟㛵ࡋ࡚᫓ᒣᡂᏊ ᩍᤵ㸦୕㔜኱Ꮫ㸧࡟ࡼࡿㅮ⩏ࢆࡑࢀࡒࢀ⾜ࡗࡓࠋ
ࠕPractice on Local Disaster Management Planࠖ₇⩦࡛ࡣࠊ㒌ᰤ⌔ ◊✲ဨ㸦ICHARM㸧࠿ࡽࠊGIS
ࢯࣇࢺࡢ౑࠸᪉ࢆᏛࢇࡔࠋ
ࡲࡓࠊ
1 ᭶ 23 ᪥࠿ࡽ 2 ᭶ 4 ᪥ࡢ 2 㐌㛫ࡣࠊ
GRIPS ᰯ⯋࡟࠾࠸࡚
ࠕDisaster Mitigation Policyࠖ
ࠕDisaster
ࠊ
Risk Managementࠖྛㅮ⩏ࢆ㞟୰ⓗ࡟ᐇ᪋ࡋࠊ᳃ᆅⱱ ᩍᤵ㸦GRIPS㸧ࡸᒸᓮ೺஧ ᩍᤵ㸦GRIPS㸧࠿
ࡽㅮ⩏ࢆ㡬࠸ࡓࠋࡲࡓࠊෆ㛶ᗓ࡟࠾ࡅࡿ≉ูㅮ⩏ࡸࠊ໭஑ᕞࡢ⌧ᆅどᐹࡶ⾜ࡗࡓࠋ
2 ᭶࠿ࡽ 3 ᭶࡟࠿ࡅ࡚ࡣࠊᡃࡀᅜࡢ௦⾲ⓗ࡞ᵓ㐀≀ᑐ⟇࡜ࡋ࡚ࡢࢲ࣒ࡸ◁㜵஦ᴗࡢᙺ๭ࢆ⌮ゎࡍࡿࡓࡵ
࡟ࠊ
ࠕSustainable Reservoir Development & Managementࠖ࡜ࠕControl Measures for Landslide &
Debris Flowࠖࡢㅮ⩏ࢆ⾜ࡗࡓࠋ
ࠕSustainable Reservoir Development & Management࡛ࠖࡣࠊᯇᮏᚨஂ
ᩍᤵ㸦
㸦㈈㸧ࢲ࣒ᢏ⾡ࢭࣥࢱ࣮㸧ࢆጞࡵࠊᆏᮏᛅᙪ ఍㛗㸦኱ࢲ࣒఍㆟㸧
ࠊ኱⏫㐩ኵ ⌮஦㛗㸦
㸦㈈㸧ࢲ࣒ᢏ
㸦㈈㸧ࢲ࣒ᢏ⾡
⾡ࢭࣥࢱ࣮㸧
ࠊゅဴஓ ᩍᤵ㸦ி㒔኱Ꮫ㸧
ࠊኳ㔝㑥ᙪ ᐊ㛗㸦ᅜ⥲◊㸧
ࠊ᯽஭᮲௓ 㤳ᖍ◊✲ဨ㸦
ࢭࣥࢱ࣮㸧
ࠊཬࡧᒣཱྀ჆୍ ᩍᤵࠊᾏ㔝ோ ୺௵◊✲ဨ㸦࠸ࡎࢀࡶ㸦⊂㸧ᅵᮌ◊✲ᡤ㸧ࡢⓙᵝ࠿ࡽࠊࢲ࣒࡟㛵
ࡍࡿ᭱᪂ࡢືྥࡸᢏ⾡࡟ࡘ࠸࡚ㅮ⩏ࢆ㡬࠸ࡓࠋ
ࠕControl Measures for Landslide & Debris Flow࡛ࠖࡣࠊụ㇂ᾈ ᩍᤵ㸦
㸦㈈㸧◁㜵࣭ᆅࡍ࡭ࡾᢏ⾡ࢭ
ࣥࢱ࣮ ⌮஦㛗㸧ࢆጞࡵࠊ➲ཎඞኵ ᩍᤵ㸦㧗▱኱Ꮫ㸧
ࠊཎ⩏ᩥ ᖖ௵ཧ୚㸦
㸦♫㸧඲ᅜ἞Ỉ◁㜵༠఍㸧
ࠊ⥘ᮌ
ு௓ 㒊㛗㸦
㸦㈈㸧◁㜵࣭ᆅࡍ࡭ࡾᢏ⾡ࢭࣥࢱ࣮㸧
ࠊ⸨⃝࿴⠊ 㒊㛗㸦
㸦ᰴ㸧㧗㏿㐨㊰⥲ྜᢏ⾡◊✲ᡤ㸧
ࠊ㧗᲍
࿴⾜ ㅮᖌ㸦࢔ࢪ࢔⯟ 㸦ᰴ㸧㢳ၥ㸧
ࠊᑠᒣෆಙᬛ ࢢ࣮ࣝࣉ㛗㸦ᅵᮌ◊✲ᡤ㸧࠿ࡽ◁㜵࡟㛵ࡍࡿ᭱᪂ࡢືྥ
ࡸᢏ⾡࡟ࡘ࠸࡚ㅮ⩏ࢆ㡬࠸ࡓࠋ
ࠕPractices in Hydraulics࡛ࠖࡣࠊỈ⌮Ꮫࡢᇶ♏ࢆᐇ㝿࡟┠࡛ぢ࡚Ꮫࡪࡓࡵ࡟ࠊ2 ᭶ 14 ᪥࡟ࠊࡘࡃࡤᕷ
ෆࡢỈ⌮ᐇ㦂᪋タ㸦ࣃࢩࣇ࢕ࢵࢡࢥࣥࢧࣝࢱࣥࢶᰴᘧ఍♫ ࡘࡃࡤᢏ⾡◊✲ࢭࣥࢱ࣮㸦ࡘࡃࡤᕷస㇂㸧
㸧࡟
࠾࠸࡚ࠊᏛ⏕ࡀࢢ࣮ࣝࣉ࡟ศ࠿ࢀ࡚ࡢỈ⌮ᐇ㦂ࢆᐇ᪋ࡋࡓࠋࡲࡓ 5 ᭶ 22 ᪥࡟ࡣࠊ฼᰿ᕝ኱ṇᶫ㸦⩌㤿┴
῰ᕝᕷ㸧࡟࡚ࠊᰴᘧ఍♫ Ỉᩥ⎔ቃࡢ༠ຊࡶ㡬ࡁ࡞ࡀࡽࠊADCP㸦Acoustic Doppler Current Profilers㸸
㉸㡢Ἴࢻࢵࣉ࣮ࣛከᒙὶྥὶ㏿ィ㸧ほ ᶵჾࢆ⏝࠸ࡓὶ㔞ほ ₇⩦ࢆᐇ᪋ࡋࡓࠋ
㸺⌧ᆅどᐹ࣭₇⩦㸼
ᮏࢥ࣮ࢫ࡛ࡣࠊᏛ⏕࡟ᑐࡋ࡚ྛᅜ࡟࠾ࡅࡿỈ⅏ᐖࡢㄢ㢟ゎỴࡢࣄࣥࢺࢆ୚࠼ࡿࡓࡵ࡟ࠊᅜᅵ஺㏻┬⌧ᆅ
஦ົᡤࡸྛᆅ᪉⮬἞య࡞࡝ࡢ༠ຊࡢୗࠊᡃࡀᅜࡢᵝࠎ࡞἞Ỉᑐ⟇᪋タࡢぢᏛࢆᐇ᪋ࡋࡓࠋ
ࡲࡎࠊ࠶ࡿ⛬ᗘ᪥ᮏࡢἙᕝ࡟ࡘ࠸࡚ㅮ⩏࡛Ꮫࢇࡔᚋࡢ 2011 ᖺ 10 ᭶ 27 ᪥࡟ࡣࠊ᪥ᮏࡢ㒔ᕷᇦࡢἙᕝࡢ
18
⟶⌮ࡢᐇ᝟ࢆぢࡿࡓࡵ࡟ࠊᅜᅵ஺㏻┬ ⲨᕝୗὶἙᕝ஦ົᡤࡢࡈ༠ຊࡢୗࠊⲨᕝୗὶᇦࢆゼၥࡋࡓࠋ஦ົᡤ
ᡤ᭷ࡢ⯪࡛Ⲩᕝ㛮㛛ࢆ⤒⏤ࡋ࡚ࠊ᪂⏣ᆅ༊ࡢࢫ࣮ࣃ࣮ሐ㜵ࢆどᐹࡋࠊⲨᕝ▱Ỉ㈨ᩱ㤋࡛ⲨᕝࡢᴫせࢆᏛࢇ
ࡔᚋࠊᾋ㛫㜵⅏ࢫࢸ࣮ࢩࣙࣥࡲ࡛ἙᕝᩜࢆṌࡁ࡞ࡀࡽࠊᖹᖖ᫬࠾ࡼࡧ⅏ᐖ᫬ࡢἙᕝ⟶⌮࡟ࡘ࠸࡚ㄝ᫂ࢆཷ
ࡅࡓࠋ
⩣ 28 ᪥࡟ࡣࠊ㛵ᮾᆅ᪉ᩚഛᒁἙᕝ㒊⅏ᐖᑐ⟇ᐊࢆゼၥࡋࠊᗈᇦ࡛ࡢỈᩥ࣭Ẽ㇟ࢹ࣮ࢱ⟶⌮ࡢᐇ᝟࡟ࡘ
࠸࡚ㅮ⩏ࢆཷࡅࡓᚋࠊ㤳㒔ᅪእ㒌ᨺỈ㊰࡟⛣ືࡋࠊỤᡞᕝἙᕝ஦ົᡤࡢࡈ༠ຊࡢࡶ࡜ࠊㄪᅽỈᵴࡢෆ㒊ࢆ
ゼၥࡋࡓࠋᏛ⏕ࡣࠊࡑࡢᕧ኱ࡉ࡟㦫ࡃ࡜࡜ࡶ࡟ࠊタ⨨㈝⏝࣭⥔ᣢ⟶⌮㈝⏝࡜ࡑࡢຠᯝࡢࣂࣛࣥࢫࢆ࠸࠿࡟
࡜ࡿ࠿ࢆᏛࢇࡔࠋ
11 ᭶ 10 ᪥࡟ࡣࠊ
ᅜᅵ஺㏻┬ࡢὥỈ᫬ࡢᑐᛂࢆᏛࡪࡓࡵ࡟ࠊ
ᅜᅵ஺㏻┬ ฼᰿ᕝୖὶἙᕝ஦ົᡤࢆゼၥࡋࠊ
ࣁࢨ࣮ࢻ࣐ࢵࣉࡸἙᕝᇶ‽Ỉ఩ࡢࡈㅮ⩏ࢆཷࡅࡓᚋࠊᰩᶫᆅ༊ෆ࡟࠶ࡿࠕࡲࡿࡈ࡜ࡲࡕࡈ࡜ࣁࢨ࣮ࢻ࣐ࢵ
ࣉࠖࡸஂ႐ᕷᰩᶫᨭᡤ࡟タ⨨ࡉࢀ࡚࠸ࡿ฼᰿ᕝỈ఩⾲♧ሪࠊᰩᶫ㥐࡟タ⨨ࡉࢀ࡚࠸ࡿ฼᰿ᕝ᝟ሗ┙࡞࡝ࢆ
どᐹࡋࡓࠋ
ࠕࡲࡿࡈ࡜ࡲࡕࡈ࡜ࣁࢨ࣮ࢻ࣐ࢵࣉࠖࡣࠊ࢝ࢫ࣮ࣜࣥྎ㢼࡟ࡼࡿᐇ⦼ὥỈᾐỈ῝ࡀ㟁ᰕ࡟♧ࡉࢀ
࡚࠸ࡿࡶࡢ࡛࠶ࡾࠊ⏫ෆࡢ୺せ㐨㊰ἢ࠸࡟タ⨨ࡉࢀ࡚࠸ࡿࠋࡇࢀ࡟ࡼࡾࠊὥỈ࡟ᑐࡍࡿࣜࢫࢡࢆ⏫Ẹࡀᐜ
᫆࡟▱ࡿࡇ࡜ࡀฟ᮶ࠊ㈝⏝ࡀ࠿࠿ࡽ࡞࠸᪋⟇࡛࠶ࡿࡓࡵࠊ㏵ୖᅜ࡟ࡶ༑ศ㐺⏝࡛ࡁࡿࡶࡢ࡜ᛮࢃࢀࡿࠋ༗
ᚋ࡟ࡣࠊΏⰋ℩㐟Ỉᆅ࡟⛣ືࡋࠊ㐟Ỉᆅෆࡢᒎᮃࢱ࣮࣡࠿ࡽ㐟ỈᆅෆࢆどᐹࡋࡓࠋᏛ⏕ࡣ≉࡟ࠊỈ㉁ί໬
࡞࡝ࡢ㐟Ỉᆅ࡟࠾ࡅࡿ⎔ቃᑐ⟇࡟ࡶ⯆࿡ࢆᣢࡗࡓࠋ
11 ᭶ 22 ᪥࡟ࡣࠊᮾி㒔ᘓタᒁࡢࡈ༠ຊࡢୗࠊ⏝ᆅ࡟వ⿱ࡢ࡞࠸㒔ᕷෆ࡛ࡢὥỈᑐ⟇ࡢᐇ౛࡜ࡋ࡚ࠊⓑ
Ꮚᕝㄪᩚụ⩌࡜▼⚄஭ᕝࡢἙᕝᨵಟ஦ᴗࡢ⌧ᆅࢆどᐹࡋࡓࠋ
ⓑᏊᕝㄪᩚụ⩌࡛ࡣㄪᩚỈᵴࡢ୰ࡸࠊ
኱Ἠࢪࣕ
ࣥࢡࢩࣙࣥෆࡢ⏝ᆅࢆ࠺ࡲࡃ฼⏝ࡋ࡚ᘓタࡉࢀ࡚࠸ࡿ❧ᆙࢆどᐹࡍࡿࡇ࡜ࡀฟ᮶ࠊࡉࡽ࡟▼⚄஭ᕝ࡛ࡣࠊ
㒔ᚰࡢఫᏯ⾤ࢆὶࢀࡿἙᕝࡢᨵಟ⌧ሙ࡛ࡢ㦁㡢ᑐ⟇ࡸỈ㉁ở⃮࡟ࡘ࠸࡚ࡢᕤኵⅬࢆᢸᙜ⪅࠿ࡽ࠺࠿ࡀ࠺ࡇ
࡜ࡀฟ᮶ࡓࠋ
12 ᭶ 9 ᪥࡟ࡣࠊ㒔ᕷἙᕝὶᇦ࡛ࡢ⥲ྜⓗ࡞἞Ỉᑐ⟇ࡢどᐹ࡜ࡋ࡚ࠊᚷ㒊ṇ༤ ෸ᩍᤵ㸦
㸦♫㸧㞵Ỉ㈓␃ᾐ
㏱ᢏ⾡༠఍ ᖖົ⌮஦㸧࡜ᅜᅵ஺㏻┬ ி὾Ἑᕝ஦ົᡤࡢࡈᣦᑟ࣭ࡈ༠ຊࡢࡶ࡜ࠊ㭯ぢᕝ㐟Ỉᆅ࡜㟝ࣨୣ㐟
Ỉᆅࠊ࠾ࡼࡧᐙᗞᩜᆅෆ࡟ᾐ㏱᪋タࢆタࡅ࡚࠸ࡿ࠾Ꮿࢆゼၥࡋࡓࠋ㭯ぢᕝὶᇦࡣᡓᚋᛴ㏿࡟ᕷ⾤໬ࡀ㐍ࢇ
ࡔᆅᇦ࡛࠶ࡾࠊࡑࢀࡽࡢὥỈᑐ⟇ࢆᏛࡪࡇ࡜ࡣࠊேཱྀ⭾ᙇࡀ⥆ࡃ࢔ࢪ࢔኱㒔ᕷ࡛ࡢὥỈᑐ⟇࡟ࡶᙺ࡟❧ࡘ
㒊ศࡀ࠶ࡿ࡜ᛮࢃࢀࡿࠋ
3 ᭶ 14 ᪥࠿ࡽ 16 ᪥࡟࠿ࡅ࡚ࡣࠊᅜᅵ஺㏻┬ ฟ㞼Ἑᕝ஦ົᡤࠊኴ⏣ᕝἙᕝ஦ົᡤࠊ኱࿴ᕝἙᕝ஦ົᡤ
ࡢࡈ༠ຊࡢୗࠊ୰ᅜᆅ᪉࣭㏆␥ᆅ᪉ࢆゼၥࡋࡓࠋࡲࡎᯇỤᕷෆࡢ኱ᶫᕝࢥ࣑ࣗࢽࢸ࢕ࢭࣥࢱ࣮࡛ࠊᩫఀᕝ
ࡢὥỈᑐ⟇ࠕ୕Ⅼࢭࢵࢺࠖ඲యࡢㄝ᫂ࢆཷࡅࡓᚋࠊᩫఀᕝᨺỈ㊰࡜ 3 ᭶ 3 ᪥࡟ึ‶Ỉࢆ㏄࠼ࡓࡤ࠿ࡾࡢᑿ
ཎࢲ࣒ࡢぢᏛࢆ⾜ࡗࡓࠋᩫఀᕝࡣᡃࡀᅜ࡟࠾ࡅࡿ௦⾲ⓗ࡞ኳ஭ᕝ࡛࠶ࡾࠊὶᇦࡣྂࡃ࠿ࡽὥỈ࡟ⱞࡋࡵࡽ
ࢀ࡚ࡁࡓࡀࠊἙ㐨᥀๐ࠊࢲ࣒ᘓタࡸᨺỈ㊰࡞࡝኱つᶍ࡞ὥỈᑐ⟇ࡢ⤌ࡳྜࢃࡏ࡟ࡼࡗ࡚ὥỈ⿕ᐖࢆ㍍ῶࡋ
ࡼ࠺࡜ࡋ࡚࠸ࡿࡇ࡜࡟ࠊᏛ⏕ࡣᵓ㐀≀ᑐ⟇ࡢ㔜せᛶࢆ࠶ࡽࡓࡵ࡚⌮ゎࡋࡓࡼ࠺࡛࠶ࡗࡓࠋ15 ᪥࡟ࡣᗈᓥᕷ
ෆ࡟࠾࠸࡚ࠊኴ⏣ᕝࡢ἞Ỉィ⏬ࡸἙᕝ฼⏝࡟ࡘ࠸࡚♲ᅬỈ㛛ࡸඖᏳᕝࢸࣛࢫࢆぢ࡞ࡀࡽㄝ᫂ࢆཷࡅࡓࠋ16
᪥࡟ࡣࠕே࡜㜵⅏ᮍ᮶ࢭࣥࢱ࣮ࠖ
㸦⚄ᡞᕷ㸧ࡢぢᏛࢆ⾜ࡗࡓࡢࡕࠊᡃࡀᅜ᭱኱ࡢつᶍ࡛࠶ࡿடࡢ℩ᆅࡍ࡭ࡾ
ᆅᖏࡢᑐ⟇᪋タࡢぢᏛࢆ⾜ࡗࡓࠋ
19
5 ᭶ 19 ᪥࡟ࡣࠊ฼᰿ᕝᰩᶫᆅ༊࡛⾜ࢃࢀࡓࠕ➨ 61 ᅇ฼᰿ᕝỈ⣔㐃ྜỈ㜵₇⩦ࠖࢆほぴࡋࠊከࡃࡢỈ㜵
ᅋࡀཧຍࡋ࡚኱つᶍ࡞₇⩦ࡀẖᖺ⾜ࢃࢀ࡚࠸ࡿࡇ࡜࡟Ꮫ⏕ࡣ㦫࠸࡚࠸ࡓࠋ
5 ᭶ 21 ᪥࠿ࡽ 22 ᪥࡟࠿ࡅ࡚ࡣࠊᅜᅵ஺㏻┬ 㨣ᛣᕝࢲ࣒⤫ྜ⟶⌮஦ົᡤࠊΏⰋ℩ᕝἙᕝ஦ົᡤࡢࡈ༠
ຊࡢୗࠊ㛵ᮾᆅ᪉࡟࠾ࡅࡿࢲ࣒ࡢຠᯝⓗ࡞㐠⏝ࡸ◁㜵஦ᴗࡢどᐹࢆ⾜ࡗࡓࠋᕝ἞ࢲ࣒࡜஬༑㔛ࢲ࣒࡟࠾࠸
࡚ࡣࠊ୧ࢲ࣒ࡢ㐃ᦠࡢ௙᪉࡟ࡘ࠸࡚Ꮫࢇࡔᚋࠊ㐃⤖ࢺࣥࢿࣝࡢどᐹࡶ⾜ࡗࡓࠋࡲࡓࠊ◁㜵஦ᴗ࡟㛵ࡋ࡚ࡣ
㖡ぶỈබᅬࢆゼၥࡋࠊᶍᆺࢆ⏝࠸࡚ㄝ᫂ࢆཷࡅࡓᚋࠊᒣࢆⓏࡗ࡚◁㜵஦ᴗ㸦ᯇᮌᒣ⭡ᕤ㸧ࡢどᐹࢆ⾜࠸ࠊ
◁㜵஦ᴗࡢ㔜せᛶࢆ࠶ࡽࡓࡵ࡚ᐇឤࡍࡿࡇ࡜ࡀฟ᮶ࡓࠋ
⩣ 22 ᪥࡟ࡣࠊ
㸦⊂㸧Ỉ㈨※ᶵᵓ฼᰿ᑟỈ⥲ྜ஦ົᡤࡢࡈ༠ຊࡢࡶ࡜ࠊ㛵ᮾᖹ㔝ࡢ℺₅࡟㔜せ࡞ᙺ๭ࢆᣢ
ࡘ฼᰿ᑟỈࡢどᐹࢆ⾜ࡗࡓࠋ༗ᚋ࡟ࡣࠊ⩌㤿┴῰ᕝᕷࡢ฼᰿ᕝ࡟࠿࠿ࡿ኱ṇᶫ࡟࠾࠸࡚ࠊⴙ▮෸ᩍᤵࡢᣦ
ᑟࡢࡶ࡜ࠊADCP ࡢᐇ⩦ࢆ⾜ࡗࡓࠋ
9 ᭶ 7 ᪥࠿ࡽ 8 ᪥࡟࠿ࡅ࡚ࡣࠊ᫖ᖺࡢ㇦㞵࡟ࡼࡗ࡚⏒኱࡞ὥỈ⿕ᐖࢆཷࡅࡓ࿴ḷᒣ┴᪂ᐑᕷࢆゼၥࡋࠊ
⿕ᐖࡢ≧ἣࢆどᐹࡍࡿ࡜ࡶ࡟ࠊ⿕⅏⪅࡬ࡢᑐ⟇࡟ࡘ࠸࡚ࡶㅮ⩏ࢆཷࡅࡿࡇ࡜ࡀฟ᮶ࡓࠋࡲࡓࠊఀໃᕷ኱‖
ᆅ༊ࢆゼၥࡋࠊࢥ࣑ࣗࢽࢸ࢕㜵⅏ࡢ࠶ࡾ᪉࡟ࡘ࠸࡚኱‖᣺⯆఍㛗࠿ࡽ࠾ヰࢆఛ࠺ࡇ࡜ࡀฟ᮶ࡓࠋ኱‖ᆅ༊
ࡣࠊᐑᕝࡢἙཱྀ࡟఩⨨ࡋࠊὥỈࡢ༴㝤ࡶࡉࡿࡇ࡜࡞ࡀࡽࠊὠἼࡢ༴㝤ᛶ࡟ࡘ࠸࡚ࡶᙉࡃㄆ㆑ࡉࢀ࡚࠸ࡿᆅ
ᇦ࡛࠶ࡿࠋᏛ⏕ࡣࠊ᣺⯆఍ࡀࡇࢀࡲ࡛࡟⾜ࡗ࡚ࡁࡓྲྀࡾ⤌ࡳࢆ⪺ࡁࠊᆅ༊ࢆᣲࡆ࡚㜵⅏࡟ྲྀࡾ⤌ࡴࡇ࡜ࡢ
㔜せᛶࢆ⌮ゎࡍࡿࡇ࡜ࡀ࡛ࡁࡓࠋ
㸺ಟኈㄽᩥ㸼
ಟኈㄽᩥసᡂ࡟㛵ࡋ࡚ࡣࠊྛᏛ⏕ࡀࡑࢀࡒࢀࡢᅜ࡛ࡢỈ⅏ᐖ࡟㛵ࡍࡿㄢ㢟ゎỴ࡟㈨ࡍࡿࡓࡵ࡟◊✲ࡋࡓ
࠸ෆᐜࢆᑛ㔜ࡋ࡞ࡀࡽࠊICHARM ◊✲ဨࡀಶู࡟㠃ㄯࢆ⾜࠸◊✲ෆᐜࡢࢧ࣏࣮ࢺࢆ㐺ᐅ⾜ࡗࡓࠋࡲࡎࠊ
10 ᭶ 11 ᪥࡜ 13 ᪥࡟ ICHARM ◊✲άືෆᐜࢆྛ◊✲ဨ࠿ࡽ⤂௓ࡍࡿሙࢆタࡅࡓࠋࡑࡢᚋࠊ18 ᪥࡟ࡣ࢖
ࣥࢭࣉࢩ࣏࣮ࣙࣥࣞࢺࡢⓎ⾲ࢆ⾜ࡗ࡚ࠊྛᏛ⏕ࡀ⯆࿡ࢆᣢࡘศ㔝ࢆᢕᥱࡋࠊ࡝ࡢ ICHARM ◊✲ဨ࡟ࡘ࠸
࡚ಟኈㄽᩥ◊✲ࢆ⾜࠺࠿ࠊᏛ⏕࡜◊✲ဨࡀヰࡋྜ࠸࡞ࡀࡽࠊࢸ࣮࣐ࢆ⤠ࡗ࡚࠸ࡗࡓࠋ
1 ᭶ 10 ᪥࠿ࡽ 12 ᪥ࡲ࡛ࡢ 3 ᪥㛫ࡣࠊᏛ⏕ࡀᢪ࠼ࡿ⮬ᅜࡢㄢ㢟ࢆᐈほⓗ࡟ศᯒࡋࠊㄽᩥࡢ᪉ྥᛶࢆタᐃ
ࡍࡿࡢ࡟኱ኚ᭷⏝࡞₇⩦࡜ࡋ࡚ࠊ≉ᐃ㠀Ⴀ฼άືἲே ࢪ࣮࢚࢚࣒࣭ࣝ࢖ࣥࢫࢸ࢕ࢳ࣮ࣗࢺ࠿ࡽ႐ከ᱇ᏊẶࠊ
஭㛵ࡩࡳᏊẶࢆᣍࡁࠊ
ࠕProject Cycle Managementࠖ₇⩦ࢆᐇ᪋ࡋࡓࠋ
ࡑࡢᚋࠊ1 ᭶ 16 ᪥ࡢ➨ 1 ᅇࢆ⓶ษࡾ࡟ࠊ3 ᭶ 9 ᪥ࠊ4 ᭶ 24 ᪥ࠊ6 ᭶ 1 ᪥࠾ࡼࡧ 7 ᭶ 10 ᪥ࡢྜィ 5 ᅇࠊ
Ꮫ⏕࡟ࡼࡿㄽᩥ୰㛫Ⓨ⾲఍ࢆ⾜ࡗࡓࠋࡇࢀ࡟ࡼࡾࠊྛᏛ⏕ࡣ ICHARM ◊✲ဨ࠿ࡽࡢ࢔ࢻࣂ࢖ࢫࢆཷࡅࡽ
ࢀࡿࡔࡅ࡛࡞ࡃࠊ
௚ே࡜ẚ࡭࡚ࡢ⮬ࡽࡢ㐍ᤖᗘྜ࠸ࢆ☜ㄆࡍࡿࡇ࡜ࡀฟ᮶ࠊ
ㄽᩥసᡂࡢືᶵ௜ࡅ࡟ࡶ⧅ࡀࡗ
ࡓ࡜ᛮࢃࢀࡿࠋ8 ᭶ 10 ᪥ࡢ᭱⤊Ⓨ⾲఍࡟࠾࠸࡚ࡣࠊᒸᓮᩍᤵ㸦GRIPS㸧ࡶཧຍࡋࠊ1 ᖺ㛫ࡢᡂᯝࢆྛ⮬
ᢨ㟢ࡋࡓࠋ
ࡲࡓᮏࢥ࣮ࢫ࡛ࡣࠊ᪥ᮏࡢᏛ఍࡬ࡢㄽᩥᢞ✏ࢆ✚ᴟⓗ࡟່ࡵ࡚࠾ࡾࠊ௒ᖺᗘࡢࢥ࣮ࢫ࡟࠾࠸࡚ࡣࠊ9 ᭶
6 ᪥࡟⾜ࢃࢀࡓࠕ➨ 14 ᅇ ᅵᮌᏛ఍ᅜ㝿ࢧ࣐࣮ࢩ࣏ࣥࢪ࣒࢘ࠖ
㸦ྡྂᒇ኱Ꮫ㸧࡟࠾࠸࡚ࠊ࢜ࣈࢨ࣮ࣂ࣮ཧ
ຍ࡛࠶ࡗࡓࡶࡢࡢࠊ
MUHAMMAD ALEEM UL HASSAN RAMAY Ặ
㸦ࣃ࢟ࢫࢱࣥ㸧
࡜ AYMEN LAZRAK
20
Ặ㸦ࢳࣗࢽࢪ࢔㸧ࡢ 2 ྡࡀཱྀ㢌Ⓨ⾲ࢆࡍࡿࡇ࡜ࡀฟ᮶ࡓࠋࡇࡢࡼ࠺࡞Ꮫ⏕ࡢⓎ⾲ࡢሙࢆᙼࡽ࡬ᥦ౪ࡋࠊࡼ
ࡾࡼ࠸ಟኈㄽᩥసᡂ࡬ࡢືᶵ௜ࡅࢆ⾜࠺ࡇ࡜ࡣ௒ᚋࡶ✚ᴟⓗ࡟⾜ࡗ࡚࠸ࡁࡓ࠸࡜⪃࠼࡚࠸ࡿࠋ
㸺ࡑࡢ௚㸼
ICHARM ࡀỈ⅏ᐖ㛵ಀࡢᑓ㛛ᐙࢆᣍ࠸࡚㛤ദࡍࡿࠕICHARM R&D Seminarࠖ࡟✚ᴟⓗ࡟ཧຍࡉࡏࠊ
ᡃࡀᅜࡸୡ⏺ࡢỈ⅏ᐖ࡟㛵ࡍࡿ᭱᪂ࡢືྥ࣭▱ぢࢆᏛࡪᶵ఍ࢆᩘከࡃ୚࠼ࡓࠋ
4 ᭶ 15 ᪥࡟ࡣࠊ᪥ᮏᩥ໬࡟ゐࢀࡿࡓࡵ࡟ࠊᅵᮌ◊✲ᡤ⌮஦㛗࣭ICHARM ࢭࣥࢱ࣮㛗ඹദࡢࡶ࡜ࠊ
ࠕ࠾
Ⲕ఍ࠖࢆ ICHARM ᩍᐊ࡛ᐇ᪋ࡋࡓࠋICHARM ࡢዪᛶ⫋ဨࡀⲔ㐨ࡢ⢭⚄ࢆㄝ᫂ࡋࡓᚋࠊ࠾ⲔࡢⅬ࡚᪉ࡸ
࠾ⳫᏊࡢ㡬ࡁ᪉ࠊ࠾Ⲕࡢ㣧ࡳ᪉ࢆᐇ₇ࡋࠊᏛ⏕ࡣ័ࢀ࡞࠸ᡭࡘࡁ࡛࠾Ⲕ࡜࠾ⳫᏊࢆᴦࡋࢇ࡛࠸ࡓࠋ
9 ᭶ 12 ᪥࡟ࡣࠊᖐᅜᚋ࡟◊ಟࡢᡂᯝࢆ࡝ࡢࡼ࠺࡟ά࠿ࡋࠊ࡝ࡢࡼ࠺࡞άືࢆ⾜࠺࠿࡟ࡘ࠸࡚ሗ࿌ࡍࡿ
ࠕAction PlanࠖࡢⓎ⾲఍ࢆ⾜ࡗࡓࠋࡑࡢᚋࠊᏛ⏕୺ദ࡛ㅰᜠ఍ࢆ⾜ࡗࡓࠋ
9᭶13᪥࡟ࡣJICA⟃Ἴ࡟࡚JICA◊ಟ࡜ࡋ࡚ࡢ㛢ㅮᘧࡀ⾜ࢃࢀࡓࠋᘧ࡟࠾࠸࡚ࡣࠊJICA⟃Ἴ ᮌ㑦ᡤ㛗ࠊ
ICHARM ➉ෆࢭࣥࢱ࣮㛗ࡑࢀࡒࢀ࠿ࡽ⚃㎡ࡢᚋࠊJICA࠿ࡽ◊ಟಟ஢ドࡀ୚࠼ࡽࢀࡓࠋࡲࡓࠊGRIPS࣭
ᅵᮌ◊✲ᡤࡢ㐃ྡ࡛ඃࢀࡓಟኈㄽᩥࢆసᡂࡋࡓ⪅࡟㉗ࡽࢀࡿ“Best Research Award”ࡣࠊ
ZHU BINGẶ
㸦୰
ᅜ㸧࡜ARSLAN USMANẶ㸦ࣃ࢟ࢫࢱࣥ㸧୧ྡ࡟ᤵ୚ࡉࢀࡓࠋࡉࡽ࡟ࠊICHARM࠿ࡽࠊᏛ⏕඲ဨࡢᢞ⚊
࡟ࡼࡗ࡚ᮏࢥ࣮ࢫࡢ㐠Ⴀ࡟᭱ࡶ༠ຊࡋࡓ⪅࡟㏦ࡽࢀࡿ“ICHARM Sontoku Award” ࡣࠊMUHAMMAD
ALEEM UL HASSAN RAMAYẶ㸦ࣃ࢟ࢫࢱࣥ㸧Ặ࡟ᤵ୚ࡉࢀࡓࠋᏛ⏕ࢆ௦⾲ࡋ࡚ࠊHASSANẶࡀ࠾♩
ࡢゝⴥࢆ㏙࡭ࠊᘧࡣ⤊஢ࡋࡓࠋ
9 ᭶ 14 ᪥࡟ࡣࠊGRIPS ࡟࡚Ꮫ఩ᤵ୚ᘧࡀ⾜ࢃࢀࡓࠋᒸᓮᩍᤵࡀᏛ⏕ྡࢆ୍ேࡎࡘㄞࡳୖࡆࠊቭୖ࡟࡚
GRIPS Ꮫ㛗࠿ࡽᏛ఩ドࡀᡭΏࡉࢀࠊ⥆࠸࡚Ꮫ⏕࡜➉ෆᩍᤵࡀሀ࠸ᥱᡭࢆࡑࢀࡒࢀ஺ࢃࡋࡓࠋᏛ⏕ࡣࠊ1 ᖺ
㛫ࡢᏛ⩦ࡢᡂᯝ࡜ࡋ࡚Ꮫ఩ドࢆཷࡅྲྀࡾࠊࡑࢀࡒࢀࡀ㠀ᖖ࡟‶㊊ࡋࡓ⾲᝟࡛࠶ࡗࡓࠋ
⩣ 15 ᪥ࠊᏛ⏕㐩ࡣࡑࢀࡒࢀ⮬ᅜ࡬ࡢᖐ㊰࡟ࡘ࠸ࡓࠋ
21
Chapter 4: ಟኈㄽᩥ
๓❶࡛ࡶ㏙࡭ࡓࡀࠊ௒ᖺᗘࡢಟኈㄽᩥ࡟㛵ࡍࡿ୺ࡓࡿࢫࢣࢪ࣮ࣗࣝࢆࠊ⾲ 4-1 ࡟♧ࡍࠋ
⾲ 4-1 ಟኈㄽᩥ࡟㛵ࡍࡿࢫࢣࢪ࣮ࣗࣝ
2011
18th October
Presentation on Inception Report
2012
10th – 12th , January
Project Cycle Management exercise
16th , January
1st Interim Presentation
9th , March
2nd Interim Presentation
24th , April
3rd Interim Presentation
1st , June
4th Interim Presentation
6th , July
Deadline of submission of the 1st draft thesis
10th ,July
5th Interim Presentation
27th , July
Deadline of submission of the 2nd draft thesis
10th, August
Final Presentation
27th ,August
Submission to GRIPS
๓㏙ࡢ㏻ࡾࠊᮏࢥ࣮ࢫࡣ 1 ᖺ㛫ࡢಟኈㄢ⛬࡛࠶ࡿࡇ࡜ࢆ㋃ࡲ࠼ࠊಟኈㄽᩥࡢࢸ࣮࣐タᐃࡣㅮ⩏ࡸ₇⩦ࡢ
⤊஢ࢆᚅࡓࡎ࡟ࠊ᮶᪥┤ᚋࡢ 10 ᭶࠿ࡽ 11 ᭶࡟࠿ࡅ࡚⾜ࡗ࡚࠸ࡿࠋ௒ᖺᗘࡣࠊᏛ⏕ᩘࡀከ࠸ࡓࡵࠊICHARM
ᑓ㛛◊✲ဨࡢ◊✲㡿ᇦࢆ㋃ࡲ࠼࡞ࡀࡽࠊ᫬㛫ࢆ࠿ࡅ࡚ྛே࡟㐺ษ࡞ ICHARM ᩍᐁࢫࢱࢵࣇࢆ๭ࡾᙜ࡚࡚
࠸ࡃᙧࢆ࡜ࡗࡓࠋ
ࡑࡢᚋࡢㄽᩥసᡂࡣࠊ
ᇶᮏⓗ࡟Ꮫ⏕࡜ࡑࡢᣦᑟᩍᐁ࡜ࡢಶู┦ㄯࢆ⾜࠸࡞ࡀࡽ㐍ࡵ࡚࠸ࡗ
ࡓࠋ࡞࠾ࠊMd. SIRAJUL ISLAM Ặ㸦ࣂࣥࢢࣛࢹࢩࣗ㸧࡜ KRISHNA PRASAD RAJBANSHI Ặ㸦ࢿࣃ࣮
ࣝ㸧ࡣࠊỤ㢌ᩍᤵ࡟୺ᰝ࡟࡞ࡗ࡚㡬࠸࡚࠸ࡓࡓࡵࠊ4 ᅇ࡯࡝኱㜰࡟㉱ࡁᣦᑟࢆཷࡅࡓࠋ
ࡲࡓ᫖ᖺᗘ࡜ྠᵝ࡟ࠊᮏᖺᗘࡶ Interim Presentation ࢆ 5 ᅇᐇ᪋ࡋࠊ⮬ࡽࡢ◊✲ෆᐜ࡟ࡘ࠸࡚㐺ᐅⓎ⾲
ࡉࡏ࡚ ICHARM ࢫࢱࢵࣇࡸ௚ࡢᏛ⏕࠿ࡽ࢔ࢻࣂ࢖ࢫࢆཷࡅࡿ࡜࡜ࡶ࡟ࠊ௚Ꮫ⏕ࡢ㐍ࡳලྜࡶᢕᥱࡉࡏࠊ
⥭ᙇឤࢆᣢࡓࡏࡿࡼ࠺࡟ࡋࡓࠋࡲࡓࠊே๓࡛ከࡃⓎ⾲ࡉࡏࡿࡇ࡜࡟ࡼࡾᏛ⏕ࡢⓎ⾲⬟ຊࡢྥୖࡶᅗࡗࡓࠋ
8 ᭶ 27 ᪥࡟ࡣ୺ᰝ࣭๪ᰝ࡟ಟኈㄽᩥࢆᥦฟࡋࠊᑂᰝࡉࢀࡓ⤖ᯝࠊ19 ྡ඲ဨࡀ↓஦࡟ࠕ㜵⅏ᨻ⟇ࠖࡢಟ
ኈྕࢆᤵ୚ࡉࢀࡓࠋ
ྛᏛ⏕ࡢಟኈㄽᩥࢱ࢖ࢺࣝ࡜ࡑࢀࡒࢀࡢ୺ᰝ࣭๪ᰝࢆ⾲ 4-2 ࡟♧ࡍࠋ࡞࠾ྛㄽᩥࡢࢩࣀࣉࢩࢫࡣࠊู㏵
ู෉࡟࡚ྲྀࡾࡲ࡜ࡵࡽࢀࡿணᐃ࡛࠶ࡿࠋ
ㄽᩥసᡂࢆ㏻ࡌ࡚ࠊᏛ⏕ࡢ▱㆑ࡀ㇏ᐩ࡟࡞ࡿࡤ࠿ࡾ࡛࡞ࡃࠊICHARM ࡜Ꮫ⏕࡜ࡢ㛵ಀࡀ῝ࡃ࡞ࡗࡓ⤖
ᯝࠊICHARM ࡢ◊✲άື࡟㛵ࡋ࡚Ꮫ⏕ࡢᡤᒓᶵ㛵࡜ࡢࢥ࣑ࣗࢽࢣ࣮ࢩࣙࣥࡀ෇⁥࡟ᅗࡽࢀࡓࡾࠊ◊✲ࢹ࣮
ࢱࡀධᡭࡋࡸࡍࡃ࡞ࡿ࡞࡝ࡢ฼Ⅼࡶ࠶ࡿࠋᏛ⏕ࢆ㏻ࡌࡓࡇࡢࡼ࠺࡞ᅜ㝿ⓗ࡞ࢿࢵࢺ࣮࣡ࢡᙧᡂࡣࠊ௒ᚋࡢ
ICHARM ࡢάື࡟ࡶ኱࠸࡟ᙺ❧ࡘࡶࡢ࡜ᛮࢃࢀࡿࠋ
22
⾲ 4-2 ಟኈㄽᩥࣜࢫࢺ
No.
Country
MEE11625
1
Name
MD. MAJADUR RAHMAN
Bangladesh
䠄䝞䞁䜾䝷䝕䝅䝳䠅 䝷䝣䝬䞁
MEE11626
2
Thesis Title
Assessment of Precipitation and River Runoff Change on the Ganges,
Brahmaputra and Meghna River Basins due to Climate Change and
Adaptation Measures by Structural Means
Supervisor
Tanaka
MD. SIRAJUL ISLAM
Influence of Jamuna Bridge on River Morphological Changes
Bangladesh
Egashira
䠄䝞䞁䜾䝷䝕䝅䝳䠅 䜲䝇䝷䝮
MEE11627
3
ZHANG HANG-HUI
China
Study on Potential Contributions of the Proposed Huangpu Gate to Flood
Control in Taihu Lake Basin
Pat
Hydrological Forecasting based on T-S-K Fuzzy Logic System in Fu River
Basin
Jaya
APPLICATION OF FUZZY LOGIC FOR THE EARLY WARNING SYSTEM
ON THE REWA RIVER DOWNSTREAM
Jayawardena
Amithirigala
䠄୰⳹ேẸඹ࿴ᅜ䠅 䝝䞁䝣䜲
MEE11628
4
ZHU BING
China
䠄୰⳹ேẸඹ࿴ᅜ䠅 䝡䞁
MEE11629
5
䠄䝣䜱䝆䞊䠅
MEE11630
6
VILIAME VEREIVALU
Fiji
䞂䜱䝷䝯
LINA FITRIANI
Indonesia
A CASE STUDY OF URBAN FLOOD RISK ASSESSMENT FOR CILIWUNG
RIVER BASIN, JAKARTA, INDONESIA
Tanaka
Development of Flood Warning System in Small Scale Urbanized Basin –
Study Case: Upper Citarum River Basin
Sayama
THE EFFECT OF RAINFALL INPUT TO DISTRIBUTED HYDROLOGICAL
MODEL ON FLOOD RUNOFF SIMULATIONS IN POORLY RAIN GAUGED
RIVER BASIN
Fukami
PREDICTION OF INUNDATION PROCESSES OF NARAYANI RIVER WITH
BED DEFORMATION
Yorozuya
FLOOD RISK MAPPING AND DAMAGE ASSESSMENT OF MIANWALI
DISTRICT, INDUS RIVER BASIN, PAKISTAN
Takeuchi
䠄䜲䞁䝗䝛䝅䜰䠅 䝸䞊䝘
MEE11631 ANDI WILDANIAH
7
Indonesia
䠄䜲䞁䝗䝛䝅䜰䠅 䜰䞁䝕䜱
MEE11632 BARUN KUMAR KARNA
8
Nepal
䠄䝛䝟䞊䝹䠅
MEE11633
9
Nepal
䠄䝛䝟䞊䝹䠅
MEE11634
10
MEE11637
15
Pakistan
䠄䝟䜻䝇䝍䞁䠅
MEE11640
16
Philippines
䠄䝣䜱䝸䝢䞁䠅
MEE11641
17
Sri Lanka
䠄䝇䝸䝷䞁䜹䠅
MEE11642
18
MEE11643
19
䜰䝔䜱䝣
MUHAMMAD ALEEM UL
HASSAN RAMAY
䝝䝑䝃䞁
GRECILE CHRISTOPHER
R. DAMO
䝖䝖䠄 TOTO)
JAGATH DEHSAPRIYA
AMARASEKARA
Rainfall-Runoff-Inundation Modeling for the Lower Indus River Basin
Sayama
Analysis of Quantitative Precipitation Forecast (QPF) for Floods in Pakistan
using WRF Model
Sayama
Rainfall-Runoff-Inundation Modeling for the Indus River Basin in Pakistan
considering the Evapotranspiration Effect
Sayama
FLOOD HAZARD AND RISK ASSESSMENT OF LOWER DIPOLOG RIVER,
MINDANAO ISLAND, PHILIPPINES
Yorozuya
Development of a Flood Forecasting Model for Gin River and Kelani River
Basins in Sri Lanka using Fuzzy Logic Approach
Jaya
APPLICATION OF SUPPORT VECTOR MACHINES FOR REAL TIME
FLOOD STAGE FORECASTING IN A SEMI-ARID WATERSHED
Jaya
䝆䝱䜺䝑䝖
AYMEN LAZRAK
䜰䜲䝯䞁
PHAM DOAN KHANH
A study on necessary actions for better integration of disaster risk
management into socio-economic development in Vietnam
Viet Nam
䠄䝧䝖䝘䝮䠅
Takeuchi
䜾䝹
RANA MUHAMMAD ATIF
Tunisia
䠄䝏䝳䝙䝆䜰䠅
On the root causes of Indus 2010 flood through examination of the cases
sent to the Supreme Court
䝷䝅䝑䝗
Mr. Ahmad Ali Gul
Pakistan
䠄䝟䜻䝇䝍䞁䠅
MEE11639
Fukami
䜰䝹䝇䝷䞁
RASHID KARIM
Pakistan
䠄䝟䜻䝇䝍䞁䠅
MEE11638
14
Verification of Satellite based rainfall estimates GSMaP and development of
a correction method for Indus river basin
Pakistan
䠄䝟䜻䝇䝍䞁䠅
13
䜲䝹䝅䝱䝗
ARSLAN USMAN
Pakistan
䠄䝟䜻䝇䝍䞁䠅
MEE11636
12
䜿䞊䝢䞊䠄 KP)
ATIF IRSHAD
Pakistan
䠄䝟䜻䝇䝍䞁䠅
MEE11635
11
䝞䞊䝹䞊䞁
KRISHNA PRASAD
RAJBANSHI
䝝䞁
23
Takeuchi
Chapter 5: ࢥ࣮ࢫホ౯࡜௒ᚋࡢㄢ㢟
5.1 ࢥ࣮ࢫホ౯
ᮏ㡯࡛ࡣࠊ
㹙ࢥ࣮ࢫࢹࢨ࢖ࣥ㹛
ࠊ
㹙༢ඖ┠ᶆ㸦࢔࢘ࢺࣉࢵࢺ㸧
㹛࡜㹙ㅮ⩏࣭₇⩦㹛ࡑࢀࡒࢀ࡟ࡘ࠸࡚ࠊ࢔ࣥ
ࢣ࣮ࢺ⤖ᯝ࠿ࡽᨵၿⅬ࡞࡝ࢆศᯒࡍࡿࠋ
㹙ࢥ࣮ࢫࢹࢨ࢖ࣥ㹛
ࠊ
㹙༢ඖ┠ᶆ㸦࢔࢘ࢺࣉࢵࢺ㸧
㹛࡟ࡘ࠸࡚ࡣࠊࢥ࣮ࢫ᭱⤊᪥ࡢ JICA ホ౯఍࡟࠾࠸࡚Ꮫ
⏕࡟ᑐࡋ࡚⾜ࡗࡓ࢔ࣥࢣ࣮ࢺ⤖ᯝ࠿ࡽࠊ
㹙ㅮ⩏࣭₇⩦㹛࡟ࡘ࠸࡚ࡣࠊ༙ᖺࡈ࡜࡟ GRIPS ࡀ⾜ࡗࡓ࢔ࣥࢣ࣮
ࢺ⤖ᯝ࠿ࡽࠊࡑࢀࡒࢀศᯒࢆ⾜࠺ࠋ
5.1.1 ࢥ࣮ࢫࢹࢨ࢖ࣥ࡟ࡘ࠸࡚
ᮏࢥ࣮ࢫ඲యࡢࢹࢨ࢖ࣥ࡜ࢥ࣮ࢫᮇ㛫࡟ࡘ࠸࡚ࡣ᫖ᖺᗘ࡜ẚ㍑ࡋ࡚௨ୗ⾲ 5-1ࠊ5-2 ࠾ࡼࡧ 5-3 ࡢࡼ࠺࡞
⤖ᯝࡀᚓࡽࢀ࡚࠸ࡿࠋ
⾲ 5-1 ࢥ࣮ࢫࢹࢨ࢖ࣥ࡟ᑐࡍࡿホ౯㸦19 ྡ୰ 17 ྡ࡟ࡼࡿホ౯㸧
łłYes, appropriate No, inappropriateńń
Do you find the design of the program
appropriate for you (your organization) to
achieve the Program Objective?
ࠕ࠶࡞ࡓࡶࡋࡃࡣᡤᒓ⤌⧊ࡀ᱌௳┠ᶆࢆ㐩ᡂࡍ
ࡿୖ࡛ࠊࣉࣟࢢ࣒ࣛࡢࢹࢨ࢖ࣥࡣ㐺ษ࡜ᛮ࠸ࡲ
ࡍ࠿㸽ࠖ
௒ᖺᗘ
㸦ཧ⪃㸧
᫖ᖺᗘ
㸷
㸶
㸮
㸮
㸷
㸱
㸮
㸮
⾲ 5-2 ࣉࣟࢢ࣒ࣛᮇ㛫࡟ᑐࡍࡿホ౯㸦19 ྡ୰ 17 ྡ࡟ࡼࡿホ౯㸧
Do you find the period of the program
appropriate?
ࠕࣉࣟࢢ࣒ࣛᮇ㛫ࡣ㐺ษ࡛ࡋࡓ࠿㸽ࠖ
௒ᖺᗘ
㸦ཧ⪃㸧
᫖ᖺᗘ
Long
Appropriate
Short
㸮
㸯㸯
㸴
㸯
㸴
㸳
⾲ 5-3 ࣉࣟࢢ࣒ࣛཧຍேᩘ࡟ᑐࡍࡿホ౯㸦19 ྡ୰ 17 ྡ࡟ࡼࡿホ౯㸧
Do you find the number of participants in the
program appropriate?
ࠕࣉࣟࢢ࣒ࣛཧຍேᩘࡣ㐺ษ࡛ࡋࡓ࠿㸽ࠖ
௒ᖺᗘ
㸦ཧ⪃㸧
᫖ᖺᗘ
Too many
Appropriate
Too few
㸳
㸯㸰
㸮
㸮
㸯㸰
㸮
⾲ 5-1 ࠿ࡽࡣࠊ᫖ᖺᗘ࡜ྠᵝࠊࣉࣟࢢ࣒ࣛ඲యࡢࢹࢨ࢖ࣥࡣ࠾࠾ࡴࡡ㐺ษ࡛࠶ࡾࠊࡲࡓ⾲ 5-2 ࠿ࡽࡣࣉ
ࣟࢢ࣒ࣛᮇ㛫ࡶጇᙜ࡛࠶ࡿ࡜ᅇ⟅ࡋࡓᏛ⏕ࡀከ࠿ࡗࡓࡇ࡜ࡀࢃ࠿ࡿࠋࣉࣟࢢ࣒ࣛᮇ㛫ࡀ▷࠿ࡗࡓ࡜ᅇ⟅ࡍ
ࡿ⪅ࡶ࠸ࡓࡀࠊࣉࣟࢢ࣒ࣛ⮬యࡀ඘ᐇࡋ࡚࠸ࡓࡓࡵࠊࡼࡾ㛗࠸ᮇ㛫Ꮫ⩦ࡋࡓ࠿ࡗࡓ࡜ࡶཷࡅྲྀࢀࡿ⤖ᯝ࡜
࡞ࡗ࡚࠸ࡿࠋ
୍᪉ࠊ⾲ 5-3 ࠿ࡽࡣࠊ᫖ᖺᗘ࡜ࡣ␗࡞ࡾࠊཧຍேᩘࡀከࡍࡂࡿ࡜ࡢᅇ⟅ࡀ⣙ 3 ศࡢ 1 ࢆ༨ࡵࡿ⤖ᯝ࡜࡞ࡗ
24
ࡓࠋ௒ᖺᗘࡢᏛ⏕ᩘࡣ᫖ᖺᗘࡢ 12 ྡ࠿ࡽ 19 ྡ࡜ᛴቑࡋ࡚࠾ࡾࠊḟᖺᗘࡢᨵၿⅬࡢ୍ࡘ࡟ᣲࡆࡽࢀࡿ࡜ᛮ
ࢃࢀࡿࠋ
5.1.2 ༢ඖ┠ᶆ㸦࢔࢘ࢺࣉࢵࢺ㸧࡟ࡘ࠸࡚
2 ࡘࡢ㉁ၥࠕ3 ࡘࡢ༢ඖ┠ᶆ㸦࢔࢘ࢺࣉࢵࢺ㸧ࡣࢥ࣮ࢫ┠ᶆࢆ㐩ᡂࡍࡿୖ࡛㔜せࡔ࡜⪃࠼ࡿ࠿ࠖ
ࠊࡲࡓࠕ࠶
࡞ࡓࡣ 3 ࡘࡢ༢ඖ┠ᶆ㸦࢔࢘ࢺࣉࢵࢺ㸧ࢆ㐩ᡂࡋࡓ࠿ࠖ࡟ࡘ࠸࡚⮬ᕫホ౯ࢆࡋ࡚ࡶࡽࡗ࡚࠸ࡿࠋ⤖ᯝࡣ⾲
5-4 ࡟♧ࡍࠋ⾲ 5-4 ࠿ࡽࡣࠊྛ༢ඖ┠ᶆࡢタᐃ࡟ࡘ࠸࡚ࠊᏛ⏕࠿ࡽࡣ࠾࠾ࡴࡡ㧗࠸ホ౯ࡀᚓࡽࢀ࡚࠾ࡾࠊ
ࢥ࣮ࢫ┠ᶆ࡟ᑐࡍࡿ࢔࢘ࢺࣉࢵࢺࡢタᐃࡣ㐺ษ࡛࠶ࡗࡓ࡜⪃࠼ࡽࢀࡿࠋࡲࡓࠊྠࡌࡃ⾲ 5-4 ࠿ࡽࡣࠊ⮬ᕫ
ホ౯࡛ࡣ࠶ࡿࡀࠊ࠾࠾ࡴࡡྛᏛ⏕ࡣ༢ඖ┠ᶆࢆ㐩ࡍࡿࡇ࡜ࡀฟ᮶ࡓ࡜ࡢ⤖ᯝࡀᚓࡽࢀ࡚࠸ࡿࠋ
⾲ 5-4 ༢ඖ┠ᶆ㸦࢔࢘ࢺࣉࢵࢺ㸧࡟ᑐࡍࡿホ౯㸦19 ྡ୰ 17 ྡ࡟ࡼࡿホ౯㸧
ྛ༢ඖࡣࢥ࣮ࢫ┠ᶆࢆ㐩ᡂࡍࡿ
ୖ࡛㔜せࡔ࡜⪃࠼ࡿ࠿㸽
łł
Very important
1) To be able to explain basic concept and
theory on generation process of water-related
disasters, water-related hazard risk evaluation,
disaster risk management policy and
technologies.
2) To be able to explain basic concept and
theory on flood countermeasures including
landslide and debris flow.
ńń
łł
Not important
4
3
2
௒ᖺᗘ
10
6
1
㸦ཧ⪃㸧
3
10
7
8
4
7
5
9
8
4
13
10
2
7
5
௒ᖺᗘ
10
7
8
9
㸦ཧ⪃㸧
9
3
8
3
᫖ᖺᗘ
௒ᖺᗘ
᫖ᖺᗘ
᫖ᖺᗘ
1
ńń
Fully Achieved Unachieved
4
㸦ཧ⪃㸧
3) To formulate the countermeasures to
solve the problems and issues concerning
water-related disasters in their countries by
applying techniques and knowledge acquired
through the program.
⮬ᕫホ౯࡟ࡼࡿྛ༢ඖ┠ᶆࡢ㐩
ᡂᗘ
2
1
1
5.1.3 ㅮ⩏࣭₇⩦࡟ࡘ࠸࡚
GRIPS ࡛ࡣࠊྛ⛉┠࡟ࡘ࠸࡚ࠊ⾲ 5-5 ࡟ᣲࡆࡿ 14 ࡘࡢ㉁ၥ㡯┠࠿ࡽ࡞ࡿ↓グྡࡢ࢔ࣥࢣ࣮ࢺࢆᐇ᪋ࡋ
࡚࠸ࡿࠋྛ㉁ၥ࡟ᑐࡋ࡚ࠊ5:Strongly Agree ࠿ࡽ 1:Strongly disagree ࡢ 5 ẁ㝵࡛ホ౯ࡋ࡚࠸ࡿࠋ࢔ࣥࢣ࣮
ࢺ⤖ᯝࢆ⛉┠ࡈ࡜࡟ᖹᆒ໬ࡋࡓࡶࡢࡀᅗ 5-1ࠊ㉁ၥࡈ࡜࡟ᖹᆒ໬ࡋࡓࡶࡢࡀᅗ 5-2 ࡛࠶ࡿࠋ
ᅗ 5-1 ࠿ࡽࡣࠊ
Ꮫ⏕࠿ࡽࡢホ౯ࡀẚ㍑ⓗ㧗࠸
㸦ᖹᆒ್ 4.5 ௨ୖ㸧
⛉┠࡜ࡋ࡚ࠊ
Basic Concepts of Integrated
Flood Risk Management(IFRM)ࠊFlood Hydraulics & Sediment TransportࠊMechanics of Sediment
Transportation & Channel ChangesࠊComputer ProgrammingࠊIndividual Study ࡀᣲࡆࡽࢀࡿࠋࡣࡌ
ࡵ 3 ࡘࡢ⛉┠࡟ඹ㏻ࡋ࡚࠸ࡿࡢࡣࠊ኱Ꮫᩍᤵࡢ⤒㦂ࡢ࠶ࡿㅮᖌࡀࠊ୍ே࡞࠸ࡋࡣ஧ே࡛ྛ⛉┠ࡢෆᐜࢆศ
ᢸࡋ࡚࠸ࡿࡇ࡜࡛࠶ࡿࠋ
኱Ꮫ࡛ࡢ⤒㦂ୖࠊ
Ꮫ⏕ࡢࡸࡿẼࡸ㞟୰ຊࢆᘬࡁฟࡍࡇ࡜࡟㛗ࡌ࡚࠸ࡿࡇ࡜࡟ຍ࠼ࠊ
25
」ᩘᅇࡢࢥ࣐ࢆᢸᙜࡍࡿࡇ࡜࡛Ꮫ⏕࠿ࡽヰࡸ㉁ၥࡶࡋࡸࡍࡃ࡞ࡾࡓࡵࠊ⤖ᯝⓗ࡟㧗ホ౯࡟ࡘ࡞ࡀࡗ࡚࠸ࡿ
࡜ᛮࢃࢀࡿࠋComputer Programming ࡣࠊFortran ࣉࣟࢢ࣑ࣛࣥࢢ࡟ࡘ࠸࡚ ICHARM ࡢ 3 ྡࡢ◊✲ဨ
࡛ศᢸࡋ࡚࠸ࡿ₇⩦⛉┠࡛࠶ࡿࡀࠊᐇົ࡟ࡶ㐺⏝࡛ࡁࡿ▱㆑ࡀᚓࡽࢀࡿࡓࡵࠊ㧗ホ౯࡜࡞ࡗ࡚࠸ࡿ࡜ᛮࢃ
ࢀࡿࠋIndividual Study ࡣಟኈㄽᩥసᡂ࡟㛵ಀࡍࡿ⛉┠࡛࠶ࡿࡀࠊ㧗ホ౯࡛࠶ࡾࠊಟኈㄽᩥࡢᣦᑟ᪉ἲࡸ
㐍ࡵ᪉࡟ࡘ࠸࡚ࡣࠊ࠾࠾ࡴࡡホ౯ࡀᚓࡽࢀࡓࡶࡢ࡜⪃࠼ࡽࢀࡿࠋ
ᅗ 5-2 ࠿ࡽࡣࠊྛ⛉┠ࢆ㏻ࡌ࡚ホ౯ࡀẚ㍑ⓗ㧗࠸㸦ᖹᆒ್ 4.4 ௨ୖ㸧㡯┠࡜ࡋ࡚ࠊ
ࠕQ4 I would like to
recommend this course to other students.ࠖ
ࠊ
ࠕQ5 The issues and the topics discussed during the class
were appropriate and relevant to the goal of the courseࠖ
ࠊ
ࠕQ7 What I learned in the course will be
useful for my future professional activities.ࠖ
ࠊ
ࠕQ13 The instructor was well prepared for each class.ࠖ
ࠊ
ࠕQ14 As an overall evaluation, the course was useful and meaningful.ࠖࡀᣲࡆࡽࢀࠊྛ⛉┠ࡣᏛ⏕࡟
࡜ࡗ࡚᭷┈࡛࠶ࡾࠊ࠿ࡘᮏࢥ࣮ࢫࡢ┠ᶆ㐩ᡂ࡟࡜ࡗ࡚ࡶ㐺ษ࡛࠶ࡗࡓࡇ࡜ࡀఛࢃࢀࡿࠋ㏫࡟ࠊẚ㍑ⓗホ౯
ࡀప࠸
㸦ᖹᆒ್ 4.3 ௨ୗ㸧
㡯┠࡜ࡋ࡚ࠊ
ࠕQ2 The level (difficulty) of this course was appropriate.ࠖ
ࠊ
ࠕQ6 The
course was intellectually stimulating. ࠖࠊࠕ Q9 The examination(s) and grading method were
appropriate for the class.ࠖ࡞࡝ࡀᣲࡆࡽࢀࠊ⛉┠ࡢ㔜せᛶࡣ⌮ゎࡋ࡚࠸ࡿࡶࡢࡢࠊෆᐜ࡟ࡣ࡞࠿࡞࠿ࡘ࠸
࡚࠸ࡅ࡞࠿ࡗࡓᏛ⏕ࡶᑡ࡞࠿ࡽࡎ࠸ࡓࡇ࡜ࡀఛ࠼ࡿ⤖ᯝ࡜࡞ࡗ࡚࠸ࡿࠋ
⾲ 5-5 GRIPS ࢔ࣥࢣ࣮ࢺ࡟࠾ࡅࡿ㉁ၥ㡯┠
Q1
The course was well-designed in order to provide students with good understanding of the
content.
Q2
The level (difficulty) of this course was appropriate.
Q3
The course helped me think logically.
Q4
I would like to recommend this course to other students.
Q5
The issues and the topics discussed during the class were appropriate and relevant to the
goal of the course
Q6
The course was intellectually stimulating.
Q7
What I learned in the course will be useful for my future professional activities.
Q8
The quantity, content, and level of assignments were adequate.
Q9
The examination(s) and grading method were appropriate for the class.
Q10
The instructor taught this course according to the syllabus.
Q11
The instructor presented ideas clearly and logically.
Q12
The instructor provided useful study materials.
Q13
The instructor was well prepared for each class.
Q14
As an overall evaluation, the course was useful and meaningful.
26
ᅗ 5-1 ྛ⛉┠ࡢᖹᆒⅬ
ᅗ 5-2 ྛ㉁ၥ㡯┠ࡢᖹᆒⅬ
27
5.1.4 ࢔ࣥࢣ࣮ࢺ࡟࠾ࡅࡿ⮬⏤ᅇ⟅ពぢ
ᮏࢥ࣮ࢫ࡟࠾࠸࡚ࡣࠊୖグ࢔ࣥࢣ࣮ࢺࢆྵࡵᩘᅇ࢔ࣥࢣ࣮ࢺࢆᐇ᪋ࡋ࡚࠸ࡿࠋࡑࢀࡽࡢ୰࡟ࡣ⮬⏤グධ
࡟ࡼࡿᅇ⟅ࡶྵࡲࢀ࡚࠾ࡾࠊ
๓⠇ࡲ࡛ࡢࡼ࠺࡟ᩘ್໬ࡍࡿࡇ࡜ࡣ㞴ࡋ࠸ࡀࠊ
㈗㔜࡞ពぢࡀከ࠸࡜ᛮࢃࢀࡿࠋ
ࡇࢀࡽ࢔ࣥࢣ࣮ࢺ࡛ࡢ⮬⏤ᅇ⟅࡛ࡢពぢࢆࠊA ࠿ࡽ I ࡟࢝ࢸࢦ࣮ࣜ໬ࡋ࡚ࡲ࡜ࡵࡓࡢࡀࠊཧ⪃㈨ᩱ 5-1 ࡛
࠶ࡿࠋ኱ูࡋ࡚࠾ࡼࡑ 40 ࡢពぢࢆᚓ࡚࠾ࡾࠊࡑࢀࡽ࡟ᑐࡍࡿᑐᛂ㸦᱌㸧ࡶグ㍕ࡋ࡚࠸ࡿࠋ
≉࡟ࠊಟኈㄽᩥࡢࢸ࣮࣐タᐃ࡟ࡘ࠸࡚ࡣࠊẖᖺᝎࡲࡋ࠸ၥ㢟࡛࠶ࡿࠋ᪤࡟ࠊᏛ⏕⮬ࡽࡀྲྀࡾ⤌ࡴ࡭ࡁㄢ㢟
ࢆ᫂☜࡟ࡋ࡚࠸ࡿሙྜࡣ࡜ࡶ࠿ࡃࠊㄢ㢟ࡀⲉ₍࡜ࡋ࡚࠸ࡿᏛ⏕ࡢࢸ࣮࣐タᐃࡣ㞴ࡋࡃࠊ࠿ࡘᮏேࡢࡸࡿẼ
ࢆᘬࡁฟࡍࡇ࡜࡟ᕤኵࡀᚲせ࡛࠶ࡿࠋẖᖺࡢᏛ⏕ࡢࣞ࣋ࣝࡸࣂࢵࢡࢢࣛ࢘ࣥࢻࡀ␗࡞ࡾࠊ࠿ࡘ ICHARM
ᩍ⫱ࢫࢱࢵࣇࡢ≧ἣ࡞࡝ࡶኚ໬ࡍࡿࡓࡵࠊẖᖺヨ⾜㘒ㄗࢆ㔜ࡡ࡞ࡀࡽ⾜ࡗ࡚࠸ࡿࡢࡀ⌧≧࡛࠶ࡿࠋ
࡞࠾ࠊẖᖺ ICHARM ࡢ⏕ά㠃ࡢᨵၿ࡟ດࡵ࡚ࡁࡓ࠾࠿ࡆ࡞ࡢ࠿ࠊ⏕ά㠃࡟࠾ࡅࡿពぢࡣ࠶ࡲࡾ⪺࠿ࢀ
࡞࠿ࡗࡓࠋ
5.2 ௒ᚋࡢㄢ㢟
௒ᖺᗘࡢࢥ࣮ࢫ࡛ࡢㄢ㢟ࡣ௨ୗࡢ࡜࠾ࡾ࡛࠶ࡾࠊྍ⬟࡞㝈ࡾḟᖺᗘࡢࢥ࣮ࢫ࠿ࡽᨵၿࢆᅗࡿࡇ࡜࡜ࡋࡓ
࠸ࠋ
㸺⛉┠ᩘࡢ๐ῶ㸼
ẖᖺᏛ⏕࠿ࡽࡣࠊ⛉┠ࡀከ࠸ࠊࢫࢣࢪ࣮ࣗࣝࡀࢱ࢖ࢺ࡛࠶ࡿ࡞࡝ࡢពぢࡀᒆࡃࠋࢥ࣮ࢫ┠ⓗࢆ㐙⾜ࡍ
ࡿࡓࡵࡢᚲせ࡞⛉┠ࢆṧࡍࡢࡣᙜ↛࡛࠶ࡿࡀࠊ⌮ㄽ㠃࡛ࡣ࡞ࡃᐇົ㠃ࢆ㔜どࡍࡿ◊ಟ࡛࠶ࡿࡓࡵࠊḟᖺ
ᗘ௨㝆ࡣࢯࣇࢺ࢙࢘࢔ࡢά⏝ἲ࡞࡝࡟㔜Ⅼࢆ⨨ࡃ᪉㔪࡜ࡋࡓ࠸ࠋࡇࡢࡓࡵࠊḟᖺᗘ࠿ࡽࡣࠕPractice on
Advanced Hydrologyࠖࡢ⛉┠ࢆ๐ῶࡍࡿணᐃ࡛࠶ࡿࠋ
㸺Ꮫ⏕ᩘࡢࣂࣛࣥࢫ㸼
௒ᖺᗘࡢ◊ಟ⏕ᩘࡣ 19 ྡ࡛࠶ࡾࠊࡇࢀࡣ 5 ᖺ๓ࡢᮏࢥ࣮ࢫ㛤ㅮ௨᮶᭱㧗ࡢேᩘ࡛࠶ࡗࡓࠋICHARM
ࡣᖺࠎᩍ⫱ࢫࢱࢵࣇࢆ඘ᐇࡉࡏࡘࡘ࠶ࡿࡀࠊࡑࢀࡼࡾቑࡋ࡚Ꮫ⏕ᩘࡀᛴቑࡋࡓࡓࡵ࡟ࠊᏛ⏕ࡀᣦᑟᩍᐁ
࡜఍ࡗ࡚ᣦᑟࢆཷࡅࡓ࠸㝿࡟୙ᅾ࡛࠶ࡗࡓࡾࡍࡿ࡞࡝ࠊ㐺ษ࡟ᣦᑟ࡛ࡁ࡞࠸஦ែࡀⓎ⏕ࡋࡓࠋḟᖺᗘࡣࠊ
Ꮫ⏕ᩘࢆ⤠ࡾ㎸ࡳࠊᩍ⫱యไ࡟ぢྜࡗࡓᩘ࡜ࡋࡓ࠸ࠋ
ࡲࡓࠊ19 ྡ୰ 6 ྡࡀࣃ࢟ࢫࢱࣥ࠿ࡽࡢཧຍ⪅࡛࠶ࡾࠊᅜ㛫࡛ⴭࡋࡃࣂࣛࣥࢫࢆḞࡃ⤖ᯝ࡜࡞ࡗࡓࠋḟ
ᖺᗘ࡟࠾࠸࡚ࡣࠊ1 ࠿ᅜ࠿ࡽࡢཧຍࡣࡏ࠸ࡐ࠸᭱኱ 2 ྡ࡜ࡋࠊࣂࣛࣥࢫࡢ࡜ࢀࡓᅜᵓᡂ࡜ࡋࡓ࠸ࠋ
㸺⌧ᆅどᐹ࡛ࡢᑐᛂ㸼
ୖ㏙ࡢ㏻ࡾࠊᏛ⏕ᩘࡀ 19 ྡ࡜࡞ࡗࡓࡇ࡜࡛ࠊ⌧ᆅどᐹࡢ㝿㸦≉࡟⌧ሙ࡛ࡢㄝ᫂ࡢ㝿㸧
ࠊㄝ᫂⪅ࡢኌࡀ
༑ศ࡟඲ဨ࡟ᒆ࠿࡞࠸ࡓࡵ࡟ࠊ㞟୰ຊࢆษࡽࡋࡓࡾࠊ㣬ࡁࡓࡾࡍࡿ⪅ࡀᩓぢࡉࢀࡓࠋᅗ 5-1 ࠿ࡽࡶఛ࠼
ࡿࡼ࠺࡟ࠊ⌧ᆅどᐹ⛉┠࡛࠶ࡿࠕSite Visit of Water-related Disaster Management Practice in Japanࠖ
ࡢホ౯ࡣ࠶ࡲࡾ㧗ࡃ࡞࠸ࠋどᐹ࡟࠾࠸࡚ࡣࠊࢫࣆ࣮࣮࢝ࡶ౑⏝ࡋ࡚࠸ࡓࡀࠊㄝ᫂ࡀ⪺ࡇ࠼࡞࠸ࡇ࡜ࡼࡾ
ࡶࠊ⮬ศ࠿ࡽㄝ᫂⪅ࡀぢ࠼࡙ࡽ࠸㸦ㄝ᫂⪅࠿ࡽࡶぢ࠼࡟ࡃ࠸㸧ࡇ࡜ࡀࠊ㞟୰ຊࢆษࡽࡏࡿࡇ࡜࡟࡞ࡗࡓ
ࡢ࡛ࡣ࡞࠸࠿࡜ᛮ៖ࡋ࡚࠸ࡿࠋ୍ேࡇࡢࡼ࠺࡞⪅ࡀฟ⌧ࡍࡿ࡜ࠊ࿘ᅖࡢ⪅ࡶࡘࡽࢀ࡚ྠࡌࡼ࠺࡞≧ែ࡟
28
࡞ࡗ࡚ࡋࡲ࠺ࡓࡵࠊ㠀ᖖ࡟ᝏᚠ⎔࡞≧ἣ࡛࠶ࡗࡓࠋࡲࡓࠊ㉁ၥࡋࡼ࠺࡜ࡍࡿ⪅ࡀ࠸࡚ࡶࠊᏛ⏕ᩘࡀከ࠸
ࡓࡵࠊ༑ศ࡞㉁␲ᛂ⟅ࡀฟ᮶ࡎࠊ⌧ᆅどᐹ࡟ᑐࡋ࡚⇕ពࢆᣢࡘ⪅࡟࡜ࡗ࡚ࡶࢫࢺࣞࢫࡀࡓࡲࡿ⤖ᯝ࡜
࡞ࡗ࡚࠸ࡓ࡜ᛮࢃࢀࡿࠋḟᖺᗘࢥ࣮ࢫ࡛ࡣࠊᏛ⏕ᩘࢆῶࡽࡋࠊ⥭ᙇឤࡢ࠶ࡿ⌧ᆅどᐹ࡜࡞ࡿࡼ࠺࡟ࡋࡓ
࠸ࠋ
㸺ಟኈㄽᩥ㸼
ẖᖺࡢࡇ࡜࡛࠶ࡿࡀࠊಟኈㄽᩥࡢࢸ࣮࣐ࡀ 5 ᭶ࡸ 6 ᭶㡭࡟࡞ࡗ࡚ࡶ࡞࠿࡞࠿Ỵࡲࡽࡎࠊㄽᩥసᡂ࡬ࡢ
ពḧࢆኻ࠸࠿ࡅࡿᏛ⏕ࡀ 2㸪3 ྡ఩ぢཷࡅࡽࢀࡓࠋᏛ⏕࡟ࡣࠊᅔࡗࡓࡽ࠸ࡘ࡛ࡶ ICHARM ᩍᐁࢫࢱࢵ
ࣇࡢ࡜ࡇࢁ࡟┦ㄯ࡟᮶ࡿࡼ࠺࡟ኌࢆ࠿ࡅ࡚ࡣ࠸ࡿࡶࡢࡢࠊ⤖ᯝⓗ࡟ᮏேࡀືࡁฟࡍࡢࢆᚅࡗ࡚ࡋࡲࡗ࡚
࠸ࡿࡇ࡜ࡀከࡃࠊ࡞࠿࡞࠿࠺ࡲࡃ࠸࠿࡞࠿ࡗࡓࠋ
ḟᖺᗘ࡛ࡣࠊୗグ࡟ࡶグ㍕ࡍࡿࢳ࣮ࣗࢱ࣮ไᗘࢆά⏝ࡋࠊ✚ᴟⓗ࡟Ꮫ⏕ࡢ⏕ά㠃ࡸᏛᴗ㠃ࡢࢧ࣏࣮ࢺ
ࢆ⾜࠼ࡿయไ࡜ࡋࡓ࠸ࠋ
㸺⏕ά㠃࡛ࡢ࢔ࢻࣂ࢖ࢫࢆཷࡅࡿࡇ࡜ࡢ࡛ࡁࡿࢳ࣮ࣗࢱ࣮ࡢタ⨨㸼
ᮏࢥ࣮ࢫࡣࠊ1 ᖺ㛫࡜࠸࠺㛗୎ሙ࡛࠶ࡾࠊ࠿ࡘᮏᅜ࡟ᇶᮏⓗ࡟ᖐᅜ࡛ࡁ࡞࠸ࡓࡵࠊᏛᴗ㠃ࡔࡅ࡛ࡣ࡞
ࡃࠊ⏕ά㠃࡛ࡶᵝࠎ࡞ᝎࡳࢆᢪ࠼࡚࠸ࡿᏛ⏕ࡀከ࠸࡜ࠊᏛ⏕ࡓࡕ࠿ࡽ⪺ࡃሙ㠃ࡀ࠶ࡗࡓࠋࡇࡢࡓࡵࠊ
ICHARM ᑓ㛛◊✲ဨ㸦⏨ዪ୍ྡࡎࡘ㸧ࢆࢳ࣮ࣗࢱ࣮࡜ࡋ࡚ᣦྡࡋࠊᏛ⏕ࡢ୙Ᏻࢆ࿴ࡽࡆ࡚෇⁥࡞◊ಟ
ᐇ᪋࡟㈨ࡍࡿࡇ࡜࡜ࡋࡓ࠸ࠋ
㸺࢔ࢡࢩࣙࣥࣉࣛࣥ࡟ࡘ࠸࡚㸼
࢔ࢡࢩࣙࣥࣉࣛࣥ࡟ࡘ࠸࡚ࡣࠊಟኈㄽᩥᥦฟᚋ࡟ᮏ᱁ⓗ࡟╔ᡭࡋࡓࡓࡵࠊᖐᅜ᪥ࡲ࡛࡟࠶ࡲࡾ᫬㛫ࡀ
࡞ࡃࠊసᡂ࡟᫬㛫ࡀ๭ࡅ࡞࠿ࡗࡓࠋࡲࡓࠊ࢔ࢡࢩࣙࣥࣉࣛࣥ࡟ྵࡴ࡭ࡁෆᐜ࡜ࡋ࡚஦๓࡟ㄝ᫂ࢆࡋࡓࡘ
ࡶࡾ࡛࠶ࡗࡓࡀࠊࡏࡗ࠿ࡃ᫬㛫ࢆ࠿ࡅ࡚సᡂࡋࡓಟኈㄽᩥࡢෆᐜ࡜ࡘ࡞ࡀࡾࡢ࡞࠸࢔ࢡࢩࣙࣥࣉࣛࣥࢆ
సᡂࡋࡓ⪅ࡀ」ᩘ࠾ࡾࠊḟᖺᗘ௨㝆ࡣ Individual Study ࡢ୍⎔࡟⤌ࡳ㎸ࡴ࡞࡝ࠊᑐ⟇ࡀᚲせ࡛࠶ࡿࠋ
29
Chapter 6: ⤊ࢃࡾ࡟
ICHARM ࡛ࡣࠕ◊ಟάືࠖࡣࠊ
ࠕ◊✲άືࠖ
࣭
ࠕ᝟ሗࢿࢵࢺ࣮࣡ࢡάືࠖ࡜୪ࡪ୕ᮏᰕࡢ୍ࡘ࡟఩⨨࡙ࡅ
࡚࠸ࡿࠋ
ࡇࡢࡓࡧࠊᮏࢥ࣮ࢫ 5 ᮇ┠ࢆ↓஦࡟⤊஢ࡋࡓࡇ࡜࡛ࠊICHARM ࡟◊ಟ௻⏬࣭㐠Ⴀࡢࣀ࢘ࣁ࢘ࡀࡉࡽ࡟
⵳✚ࡉࢀࡓࡇ࡜ࡣࡶࡕࢁࢇࠊᏛ⏕ࡢಟኈㄽᩥసᡂࢆ㏻ࡌ࡚ᑐ㇟ᅜࡢỈ㛵㐃ၥ㢟ࡢゎỴ࡟ࡶ㈨ࡍࡿࡇ࡜࡟࡞
ࡾࠊICHARM ࡀάືࡢ࣮࣮࢟࣡ࢻ࡜ࡋ࡚࠸ࡿ”Localism”࡬ࡢዎᶵ࡜࡞ࡗ࡚࠸ࡿࠋ
ࡲࡓࠊᮏࢥ࣮ࢫࡣࠊ
ࠕ᝟ሗࢿࢵࢺ࣮࣡ࢡάືࠖ࡟ࡶ኱ࡁࡃᐤ୚ࡋ࡚࠸ࡿࠋࡍ࡞ࢃࡕࠊᏛ⏕ࡢᡤᒓࡍࡿ⤌
⧊࡜ࡢࡘ࡞ࡀࡾࡀẖᖺኴࡃ࡞ࡾࠊᵝࠎ࡞㠃࡛⌧ᆅࡢ≧ἣࡀぢ࠼ࡿࡼ࠺࡟࡞ࡗ࡚ࡁࡓࠋᏛ⏕ࢆ㏻ࡌࡓࡇࡢࡼ
࠺࡞ᅜ㝿ⓗ࡞ࢿࢵࢺ࣮࣡ࢡᙧᡂάືࡣࠊICHARM ࡀᐇ᪋ࡋ࡚࠸ࡿ௚ࡢάື࡟ᑐࡋ࡚ࡶ኱࠸࡟ᙺ❧ࡗ࡚࠾
ࡾࠊ◊ಟ⤊஢ᚋࡶᐦ࡟㐃⤡ࢆྲྀࢀࡿయไࢆ⥅⥆ࡍࡿࡇ࡜ࡀồࡵࡽࢀࡿࠋ
1 ᖺ㛫ࡣ㛗ࡃ࡚▷࠸ࡼ࠺࡞ᮇ㛫࡛࠶ࡿࡀࠊᙼࡽࡀࡇࡢ 1 ᖺ㛫ࡢಟኈㄢ⛬࡛Ꮫࢇࡔෆᐜࡢᑡࡋ࡛ࡶࠊ⮬ࡽ
ࡢᴗົ࡟ᙺ❧࡚ࡿࡇ࡜ࡀฟ᮶ࢀࡤࠊᘬ࠸࡚ࡣᙼࡽࡢᅜࡢỈ⅏ᐖ⿕ᐖ㍍ῶ࡟ࡶ㈉⊩ࡍࡿࡇ࡜ࡀฟ᮶ࡿࠋࡇࢀ
࠿ࡽᩘᖺࠊ࠶ࡿ࠸ࡣᩘ༑ᖺ࡜᫬㛫ࡣࡲࡔࡲࡔ࠿࠿ࡿ࠿ࡶ▱ࢀ࡞࠸ࡀࠊᮏࢥ࣮ࢫࡢᐇ᪋࡟ࡼࡗ࡚ࠊ╔ᐇ࡟ᙼ
ࡽࡢᅜࡢỈ⅏ᐖ⿕ᐖ㍍ῶ࡟㈉⊩࡛ࡁࡿࡇ࡜ࢆᮇᚅࡍࡿࠋ
30
㹼ㅰ㎡㹼
ᮏࢥ࣮ࢫࡣ 5 ᖺࢆ⤊࠼ࠊ㐣ཤࡢ཯┬ࢆ㋃ࡲ࠼࡚඲యࢫࢣࢪ࣮ࣗࣝࡸ࣒࢝ࣜ࢟ࣗࣛࡢぢ┤ࡋࢆ⾜࠸ࠊᏛ⏕
ࡢᏛ⩦ෆᐜ࠾ࡼࡧᏛ⩦⎔ቃ࡟ࡘ࠸࡚ࡶࠊࡼࡾ඘ᐇࢆᅗࡗ࡚ࡲ࠸ࡾࡲࡋࡓࠋࡋ࠿ࡋ࡞ࡀࡽࠊࡲࡔࡲࡔᨵၿࡍ
࡭ࡁⅬࡣከࡃṧࡉࢀ࡚࠾ࡾࠊⓙᵝࡢࡈពぢࢆ㡬ࡅࢀࡤᖾ࠸࡛ࡍࠋ
᭱ᚋ࡟࡞ࡾࡲࡋࡓࡀࠊᮏࢥ࣮ࢫࢆᐇ᪋ࡍࡿ࡟࠶ࡓࡾࠊከᛁ࡞୰ㅮ⩏ࡸ₇⩦ࢆ⾜ࡗ࡚㡬࠸ࡓㅮᖌࡢⓙᵝࡸ
⾜ᨻ㛵ಀ⪅ࡢ᪉ࠎࠊ⌧ᆅどᐹࢆᛌࡃᘬࡁཷࡅ࡚㡬࠸ࡓᅜᅵ஺㏻┬஦ົᡤ࡞ࡽࡧ࡟ᕷ⏫ᮧࡢ᪉ࠎࡸఫẸࡢ
᪉ࠎ࡟ཌࡃ࠾♩⏦ࡋୖࡆࡲࡍࠋ
31
LIST OF PARTICIPANTS IN "Water-related Disaster Management Program" JFY 2011
2011ᖺᗘ䚷䛂㜵⅏ᨻ⟇䝥䝻䜾䝷䝮䚷Ỉ⅏ᐖ䝸䝇䜽䝬䝛䝆䝯䞁䝖䝁䞊䝇䛃Ꮫ⏕䝸䝇䝖
No.
1
Photo
ID Number
Country
Name
Position
MEE11625 MD. MAJADUR RAHMAN
Bangladesh
Assistant Engineer, Design Circle-4/Bangladesh Water Development Board
(BWDB), M/o Water Resources
䝷䝣䝬䞁
MEE11626 Md. SIRAJUL ISLAM
Bangladesh
䝞䞁䜾䝷䝕䝅䝳Ỉ㛤Ⓨබ♫䚷Design Circle-4䚷ᢏᖌ⿵
䜲䝇䝷䝮
MEE11627 ZHANG HANG-HUI
China
䝞䞁䜾䝷䝕䝅䝳Ỉ㛤Ⓨබ♫䚷Design Circle-5䚷๪ᢏᖌ
䠄䝞䞁䜾䝷䝕䝅䝳䠅
2
Sub-Divisional Engineer, Design Circle-5/Bangladesh Water Development Board
(BWDB), M/o Water Resources
䠄䝞䞁䜾䝷䝕䝅䝳䠅
3
Senior Engineer of Development Research center/Taihu Basin Authority of ministry
of Water Resources
䠄୰⳹ேẸඹ࿴
ᅜ䠅
4
䝝䞁䝣䜲
MEE11628 ZHU BING
China
୰ᅜỈ㈨※┬䚷ኴ†ὶᇦ⟶⌮ᒁ䚷㛤Ⓨ◊✲ᡤ䚷ୖ⣭ᢏᐁ
Assistant Engineer/ Bureau of Hydrology, Ministry of Water Resources of China
䠄୰⳹ேẸඹ࿴
ᅜ䠅
୰ᅜỈ㈨※┬䚷Ỉᩥᒁ䚷ᢏᖌ⿵
5
䝡䞁
MEE11629 VILIAME VEREIVALU
Fiji
䝣䜱䝆䞊Ỉබ♫䚷Ỉᩥ㒊䚷ᢏᖌ⿵
6
䠄䝣䜱䝆䞊䠅 䞂䜱䝷䝯
MEE11630 LINA FITRIANI
Indonesia
Technical Assistant/Hydrology Division, Water Authority of Fiji
Chief of Water Rescources Implementation / Ciliwung Cisadane Major River Basin
Board, DG of Water Resources, Ministry of Public Works
බඹ஦ᴗ┬䚷Ỉ㈨※⥲ᒁ䚷䝏䝸䜴䞁-䝏䝃䝎䝛୺せἙᕝὶᇦ㛤Ⓨ㒊䚷Ỉ㈨※ᐇ᪋୺௵
7
䠄䜲䞁䝗䝛䝅䜰䠅 䝸䞊䝘
MEE11631 ANDI WILDANIAH
Indonesia
බඹ஦ᴗ┬䚷Ỉ㈨※⥲ᒁ䚷௻⏬䞉ィ⏬ᮏ㒊䚷⫋ဨ
8
䠄䜲䞁䝗䝛䝅䜰䠅 䜰䞁䝕䜱
MEE11632 BARUN KUMAR KARNA
Nepal
9
10
Staff / Directorate of Planning and Programming, DG of Water Resources, Ministry
of Public Works
䠄䝛䝟䞊䝹䠅 䝞䞊䝹䞊䞁
MEE11633 KRISHNA PRASAD
RAJBANSHI
Nepal
䠄䝛䝟䞊䝹䠅 䜿䞊䝢䞊䠄KP)
MEE11634 ATIF IRSHAD
Civil Engineer/Water Induced Disaster Prevention Office/Janakpur under Ministry of
Irrigation
℺₅┬䚷Ỉᐖ㜵⅏஦ົᡤ䠄䝆䝱䝘䜽䝥䝹䠅䚷ᅵᮌᢏᖌ
Engineer/People's Embankment Program/Field Office, Chitwan/Department of
Water Induced DisaterPrevention under the Ministry of Irrigation
℺₅┬ Ỉᐖ㜵⅏ᒁ䚷䝏䝖䝽䞁⌧ᆅ஦ົᡤ䚷ఫẸ୺య䛾ㆤᓊ䝥䝻䜾䝷䝮䚷ᢏᖌ
Meteorologist / Flood Forecasting Division, Pakistan Meteorological Department
Pakistan
䝟䜻䝇䝍䞁Ẽ㇟ᒁ䚷ὥỈணሗㄢ䚷Ẽ㇟ᑓ㛛ᐙ
11
䠄䝟䜻䝇䝍䞁䠅 䜲䝹䝅䝱䝗
MEE11635 ARSLAN USMAN
Pakistan
䝟䜻䝇䝍䞁Ẽ㇟ᒁ䚷ὥỈணሗㄢ䚷Ẽ㇟ᑓ㛛ᐙ
12
䠄䝟䜻䝇䝍䞁䠅 䜰䝹䝇䝷䞁
MEE11636 RASHID KARIM
Pakistan
℺₅䞉㟁ຊᒁ䚷䝞䝻䝏䝇䝍䞁℺₅ㄢ䚷ᢏᖌ⿵
13
䠄䝟䜻䝇䝍䞁䠅 䝷䝅䝑䝗
MEE11637 AHMAD ALI GUL
Pakistan
䝟䜻䝇䝍䞁Ᏹᐂ㧗ᒙ኱Ẽ◊✲ጤဨ఍䚷䜰䝅䝇䝍䞁䝖䝬䝛䞊䝆䝱䞊
14
䠄䝟䜻䝇䝍䞁䠅 䜾䝹
MEE11638 RANA MUHAMMAD ATIF
Pakistan
ᅜ㜵┬䚷䝟䜻䝇䝍䞁Ẽ㇟ᒁ䚷Ẽ㇟ᑓ㛛ᐙ
15
䠄䝟䜻䝇䝍䞁䠅 䜰䝔䜱䝣
MEE11639 MUHAMMAD ALEEM UL
HASSAN RAMAY
Pakistan
䝟䜻䝇䝍䞁Ẽ㇟ᒁ䚷ㄢ㛗⿵బ
17
䠄䝟䜻䝇䝍䞁䠅 䝝䝑䝃䞁
MEE11640 GRECILE
Philippines CHRISTOPHER
R DAMO
䠄䝣䜱䝸䝢䞁䠅 䝖䝖䠄TOTO)
MEE11641 JAGATH DEHSAPRIYA
Sri Lanka AMARASEKARA
℺₅ᒁ䚷℺₅ᢏᖌ
18
䠄䝇䝸䝷䞁䜹䠅 䝆䝱䜺䝑䝖
MEE11642 AYMEN LAZRAK
Tunisia
㎰ᴗ⎔ቃ┬䚷Ỉ㈨※⥲ᒁ䚷ᢏᖌ
19
䠄䝏䝳䝙䝆䜰䠅 䜰䜲䝯䞁
MEE11643 PHAM DOAN KHANH
Viet Nam
16
䠄䝧䝖䝘䝮䠅
䝝䞁
Meteorologist / Flood Forecasting Division, Pakistan Meteorologist Department
Assistant Engineer / Irrigation Division Patfeeder, Naseerabad/ Irrigation & Power
Department
Assistant Manager / Pakistan Space & Upper Atmosphere Research Commission
Meterologist / Defence Division, Pakistan Meteorological Department
Deputy Director / Hydrologist in Charge FFWS / Pakistan Meteorological
Department
Engineer III / Department of Public Works and Highways
බඹ஦ᴗ䞉㧗㏿㐨㊰┬䚷ᢏᖌ䊢
Irrigation Engineer, Department of Irrigation
Engineer/ General Directorate of Water Resources, Ministry of Agriculture and
Environment
Official / Disaster Management Center, Ministry of Agriculture and Rural
Developmnent
㎰ᴗ㎰ᮧ㛤Ⓨ┬䚷⅏ᐖ⟶⌮䝉䞁䝍䞊䚷⫋ဨ
Annex 1
Annex 2
October
9:0010:30
10:4512:15
13:1514:45
15:0016:30
9:0010:30
10:4512:15
13:1514:45
15:0016:30
9:0010:30
10:4512:15
13:1514:45
15:0016:30
9:0010:30
10:4512:15
13:1514:45
15:0016:30
1st
period
2nd
period
3rd
period
4th
period
1st
period
2nd
period
3rd
period
4th
period
1st
period
2nd
period
3rd
period
4th
period
1st
period
2nd
period
3rd
period
4th
period
23
16
9
Sun.
10/2
Excercise䠄Lecturer䠅
Lecture䠄Lecturer䠅
17
IFRM and traditional FRM
Disaster management cycle
Prof.
Takeuchi
(ICHARM)
Prof.
Takeuchi
(ICHARM)
Asso. Prof.
Prof. Jaya
(ICHARM)
Self Study
(ICHARM)
Review of Mathematics
Yorozuya
(Ordinary differential equation)
Basic concepts of the
Hydrological Cycle
Self Study
24
14:00-15:30 36th ICHARM R&D
Seminar
(2)P-1
(1)-1
(3)-7
(3)-6
10
Entrance Ceremony at GRIPS
11
PAR Model (1)
Introduction: What is natural
disaster? Overview of the
course
Prof. Takeuchi
(ICHARM)
18
Concept of IWRM (2)
Concept of IWRM (1)
(1)-3
(1)-2
Prof. Jaya
(ICHARM)
Prof. Jaya
(ICHARM)
(3)-14
(6)-8
(6)-7
Prof. Takeuchi
(6)-4
(ICHARM)
Consultation with supervisors
Extreme weather
Precipitation
Self Study
25
Introduction of Risk, Hazard
and Vulnerability
12
(Guidance by JICA)
Prof.
Takeuchi
(ICHARM)
Thesis Work
Future Issues of IFRM
To derive a relationship between stable
dimensionless width, depth and
discharge in natural rivers - learning
from natural rivers
Unsteady quasi-twodimensional analysis of flood
flows (2)
26
Thesis Work
Self Study
Prediction method of flow resistance in
rivers with compound channels and
application to river course design (2)
13
ACCESS Model
PAR Model (2)
(Guidance by JICA)
Prof.
Takeuchi
(ICHARM)
Prof.
Takeuchi
(ICHARM)
Prof.
Fukuoka
(Chuo Univ.)
Prof.
Fukuoka
(Chuo Univ.)
Prof.
Takeuchi
(4)-5
(ICHARM)
Prof.
Takeuchi
(ICHARM)
Prof.
Takeuchi
(ICHARM)
River management during
normal time
Stay in Tokyo
Site Visit (1)
River in Japan (Ara River)
27
Self Study
Self Study
Japanese experiences (2)
Japanese experiences (1)
20
13:15-15:15
Introduction of ICHARM research activities (2)
(3)-5
(3)-4
Prof.
Fukuoka
(3)-10
(Chuo Univ.)
Prof.
Steady quasi-two dimensional
Fukuoka
(3)-11
analysis of flood flows (1)
(Chuo Univ.)
19
Lecture at Building Research Institute
Move to Building Research Institute
Lunch at PWRI
Site visit of PWRI experimental facilities
Prof. Takeuchi
(6)-3
(ICHARM)
13:00-16:30
Presentation of Inception Report
(1 student * 10 min)
(3)-9
(3)-8
13:15-14:15
Introduction of ICHARM research activities (1)
(Director: 15min, Mr. Fukami:30min,
Mr. Okazumi: 15min)
12:10-12:50 Welcome party (Ph.D & M.Sc)
(3)-3
(3)-1
(Guidance at JICA)
Thu.
6
(3)P Practice on Local Disaster Management Plan
Wed.
5
(6)P䚷Practice on floodcountermeasure in Japan (Field trips)
(2)P䚷Practices in Hydraulics
Mon.
3
(4)P䚷Practice on Advanced Hydrology
(5)P䚷Practice on Flood Hazard Modeling & Flood Forecasting
(1)P Computer Programming
Prof. Takeuchi
(3)-2
(ICHARM)
(10)䚷Disaster Mitigation Policy
(5)䚷Advanced Hydrology
Tue.
4
(9)䚷Control Measures for Landslide & Debris Flow
(4)䚷Urban Flood Management and Flood Hazard Mapping
(11)䚷Disaster Risk Management
(7)䚷Mechanics of Sediment Transportation and River Changes
(8)䚷Sustainable Reservoir Development & Management
(3)䚷Basic Concepts of Integrated Flood Risk management (IFRM)
(6)䚷Flood Hydraulics and Sediment Transport
(2)䚷Hydraulics
(1)䚷Basic Hydrology
2011-2012 Water-related Disaster Management Course Time Table
14
How do we make a river crosssection harmonizing flood control
and river environment
28
Self Study
Self Study
Unsteady quasi-two-dimensional
analysis of flood flows (1)
Steady quasi-two dimensional
analysis of flood flows (2)
21
Introduction of IFAS
(Integrated Flood Analysis
System)
Introduction of GFAS (Global
Flood Alert System)
Prediction method of flow resistance in
rivers with compound channels and
application to river course design (1)
Characteristics and river
management of Japanese rivers
Prof.
Fukuoka
(Chuo Univ.)
Prof.
Fukuoka
(Chuo Univ.)
Prof.
Fukuoka
(Chuo Univ.)
Asso. Prof.
Fukami
(ICHARM)
Mr.
Nabesaka
(ICHARM)
Prof.
Fukuoka
(Chuo Univ.)
Prof.
Fukuoka
(Chuo Univ.)
(4)-6
15:30-17:00 Metropolitan Area
Outer Underground Discharge
Channel
13:00-14:30
River management during
flooding
Site Visit (2)
Flood Information (MLIT Kanto)
Metropolitan Area Outer Underground Discharge
(6)-9
(6)-6
(6)-5
(5)P-9
(5)P-8
(6)-2
(6)-1
10:50-11:10 Joint Entrance Ceremony at
ICHARM (Ph.D & M.Sc)
11:00-12:00 Course Orientation(Ph.D & M.Sc)
9:00-9:45 Tour of PWRI & ICHARM (M.Sc)
10:00-10:40 Opening Ceremony at PWRI
(M.Sc)
Fri.
7
29
22
15
Sat.
8
Annex 3
November
10:4512:15
13:1514:45
15:0016:30
9:0010:30
10:4512:15
13:1514:45
15:0016:30
3rd
period
4th
period
1st
period
2nd
period
3rd
period
4th
period
15:0016:30
4th
period
2nd
period
13:1514:45
3rd
period
9:0010:30
10:4512:15
2nd
period
1st
period
9:0010:30
1st
period
15:0016:30
15:0016:30
4th
period
4th
period
13:1514:45
3rd
period
13:1514:45
10:4512:15
2nd
period
3rd
period
9:0010:30
1st
period
10:4512:15
15:0016:30
4th
period
2nd
period
13:1514:45
3rd
period
9:0010:30
10:4512:15
2nd
period
1st
period
9:0010:30
1st
period
4
27
20
13
6
30
31
11/1
(2)P-2
(1)-9
(1)-5
2
(1)-12
(2)P-3
Asso. Prof.
Yorozuya
(ICHARM)
Prof. Jaya
(ICHARM)
Runoff analysis with IFAS (6)
Application to actual basins
29
Site Visit (4)
River improvement in urban area
(Tokyo Shirako River)
22
(4)P-2
Mr. Nabesaka
(5)P
(ICHARM)
Consultation with supervisors
(4)P-1
(5)P
Mr. Nabesaka
(5)P
(ICHARM)
(1)P-1
30
23
Thesis Work
Runoff analysis with IFAS (8)
Application to actual basins
Runoff analysis with IFAS (7)
Application to actual basins
Introduction of Computer
Programming with Fortran90
16
Asso. Prof.
Sayama
(ICHARM)
Mr.
Nabesaka
(ICHARM)
Mr.
Nabesaka
(ICHARM)
(4)P-3
(1)P-4
(3)-13
(1)P-2
Conceptual models of IUH
2-D bed deformation, sand
waves and bars, meandering
Prof. Jaya
(ICHARM)
(1)P-7
Self Study
I/O Statement
Introduction to Flood Hazard
Modeling
Self Study
Asso.Prof.
Sayama
(ICHARM)
(4)P-5
(1)P-9
Dr. Hasegawa
(1)P-8
(ICHARM)
Quiz(1)
Hydrologic Application
Exercise (1)
Exercises on IUH application
Thesis Work
7
1-D bed deformation,
computing model
6
Asso. Prof.
Sayama
(ICHARM)
Dr.
Hasegawa
(ICHARM)
Prof. Jaya
(ICHARM)
Dr.
Program Structure (if, do loop) Hasegawa
(ICHARM)
Self Study
Synthetic Unit Hydrograph
Self Study
8
Self Study
Dr.
Ushiyama
(ICHARM)
Prof. Jaya
(ICHARM)
Dr.
Program Structure (if, do loop) Hasegawa
(ICHARM)
Unit Prof. Jaya
(ICHARM)
Impulse and
Prof. Jaya
Response
(ICHARM)
Instantaneous
Hydrograph (IUH)
Exercises on
Frequency
Functions
(1)P-10 Arrays
(6)-6
(1)P-6
Systems theory approach II –
Prof. Jaya
Non-linear systems, multi(ICHARM)
linear systems
5
(5)P-1
(6)-3
(6)-4
Exercises on least squares Prof. Jaya
estimation
(ICHARM)
Self Study
Self Study
Systems theory approach I –
Prof. Jaya
Linear theory; Time domain
(ICHARM)
analysis; Frequency domain
Thesis Work
Self Study
Prof.
Watanabe
(Kitami Institute
of Technology)
Prof.
Watanabe
(Kitami Institute
of Technology)
(6)-2
Exercises on System function Prof. Jaya
estimation
(ICHARM)
Self Study
Consultation with supervisors
(6)-5
(6)-11
(6)-10
(1)P-5
Dr.
Program Structure (if, do loop) Hasegawa
(ICHARM)
Hydrological modelling – basic Prof. Jaya
concepts and approaches
(ICHARM)
Self Study
(7)-1
Asso. Prof.
Sayama
(ICHARM)
(1)-13
(7)-2
(2)-10
Prof. Jaya
(ICHARM)
(2)-9
(2)P-5
(2)-6
(4)-12
(7)-4
(7)-3
(4)P-4
Global trends (2) International Prof. Oki
(1)-14
actions
(Tokyo Univ.)
Self Study
24
Self Study
Variables
Probability and statistics in
hydrology I
Self Study
17
13:30-15:00
Watarase Retarding Basin
Site Visit (3)
9:30-12:00
Kurihashi Town,
12/1
Asso. Prof.
Sayama
(ICHARM)
Prof. HUANG
(Sophia Univ)
Prof. HUANG
(Sophia Univ)
Prof. HUANG
(Sophia Univ)
Prof. HUANG
(Sophia Univ)
Prof. Oki
Runoff analysis with IFAS (5)
(5)P-15 Application to actual basins
(Tokyo Univ.)
Self Study
15
(5)P-11 Data import, Model building
Runoff analysis using IFAS (3) Mr.
Runoff analysis using IFAS (1) Mr. Nabesaka
Nabesaka
(5)P-13 Validation of calculated
(ICHARM)
(ICHARM)
discharge
Mr.
Runoff analysis using IFAS (2) Mr. Nabesaka
Runoff analysis using IFAS (4)
Nabesaka
(5)P-12 Parameter estimation
(5)P-14
(ICHARM)
Application to actual basins
(ICHARM)
Fundamentals of Fluid Flow
Asso. Prof.
(2)P-4 (Energy equation, Bernoulli’s Yorozuya
Thesis Work
(ICHARM)
equation)
Unit Hydrograph Methods II
Self Study
Arithmetic Calculation
The Preissmann scheme
Method of characteristics
21
The kinematic wave model
Hydraulic jump
Global trends (1) Impact of
climatic change
Self Study
14
Medical Checkup by JICA
Unit Hydrograph Methods I
Correction and Validation of
(5)P-10 Satellite-Based Rainfall
28
(6)-1
4
Fundamentals of Fluid Flow
(Equation of continuity)
Steady uniform flow in
prismatic channels
Flow resistance calculation in
engineering practice
Asso. Prof.
Yorozuya
(ICHARM)
Prof. HUANG
(Sophia Univ)
Prof. HUANG
(Sophia Univ)
25
on
Prof.
Egashira
(Newjec)
Prof.
Egashira
(Newjec)
IUH Prof. Jaya
(ICHARM)
Prof. Jaya
(ICHARM)
Prof. Jaya
(ICHARM)
Prof.
Egashira
(Newjec)
Prof.
Egashira
(Newjec)
Prof. HUANG
(Sophia Univ)
Prof. HUANG
(Sophia Univ)
Asso. Prof.
Yorozuya
(ICHARM)
Case study of integrated flood Mr. Imbe
management -Tsurumi river- (ARSIT)
Site Visit (5)
Integrated flood management
(Tsurumi River)
9
Mechanics of sediment
transportation (2)
Mechanics of sediment
transportation (1)
Exercises
determination
Self Study
2
Thesis Work
Self Study
Basic concepts of Stochastic
Hydrology
Probability and statistics in
hydrology II
Introduction (2)
Introduction (1)
The dynamic wave model
The diffusive wave model
18
Self Study
Flow in closed conduits
(Reynolds number, Friction
factor)
Numerical solution of the
Prof. HUANG
gradually-varied flow equation (Sophia Univ)
Steady gradually-varied flow – Prof. HUANG
(Sophia Univ)
backwater surface profiles
11
(2)-5
(2)-4
Asso.Prof.
Fukami
(ICHARM)
Prof. Jaya
(ICHARM)
(2)-3
10
3
Prof. Jaya
(ICHARM)
Self Study
Review of Mathematics
(Partial differential equations)
Remote sensing in Hydrology
Peak discharge estimation
9
Mr. Nabesaka
(1)-8
(ICHARM)
Dr. Kachi,
Dr. Kubota
(JAXA)
Thesis Work
8
11:00-12:30 Satellite
observation of rainfall (2)
9:30-11:00 Satellite
observation of rainfall (1)
14:00- Tour of JAXA
(1)-11
(1)-10
7
Prof. Jaya
(ICHARM)
Prof. Jaya
(ICHARM)
Prof. HUANG
(Sophia Univ)
Prof. HUANG
(Sophia Univ)
Self Study
Concept of rainfall excess
Runoff
Flow resistance in open
channel
Introduction & Fundamental
equations
Consultation with supervisors
(1)P-3
(2)-12
(2)-11
(2)-8
(2)-7
(3)-12
(1)-7
(1)-6
(1)-4
(2)-2
(2)-1
10
3
26
19
12
5
Annex 4
December
January
15:0016:30
9:0010:30
10:4512:15
13:1514:45
15:0016:30
1st
period
2nd
period
3rd
period
4th
period
13:1514:45
3rd
period
4th
period
10:4512:15
15:0016:30
4th
period
2nd
period
13:1514:45
3rd
period
9:0010:30
10:4512:15
2nd
period
1st
period
9:0010:30
1st
period
15:0016:30
15:0016:30
4th
period
4th
period
13:1514:45
3rd
period
13:1514:45
10:4512:15
2nd
period
3rd
period
9:0010:30
1st
period
10:4512:15
15:0016:30
4th
period
2nd
period
13:1514:45
3rd
period
9:0010:30
10:4512:15
2nd
period
1st
period
9:0010:30
1st
period
15
8
1/1
25
18
11
12
13
Application of Sabo Works
and landslide
countermeasures to overseas
16
9
2
Mechanics of sediment
transportation (6)
Prof.
Egashira
(Newjec)
Prof.
Egashira
(Newjec)
Exercises on a typical rainfall- Prof. Jaya
runoff model II
(ICHARM)
Self Study
1st Interim Presentation
(4)P-7
(7)-8
(7)-7
Mechanics of sediment
transportation (5)
Consultation with supervisors
Dr. Ushiyama
(ICHARM)
(6)-7
(4)P-6
(5)P-3
(5)P-5
(5)P-4
(4)-10
(4)-9
(3)P-2
(3)P-1
10
3
Self Study
Ms. Kita, Ms.
Iseki (GLM
Institute)
Ms. Kita, Ms.
Iseki (GLM
Institute)
Dr. Ushiyama
(ICHARM)
Prof.
Geomorphology around rivers
Haruyama
and alluvial plain (1)
(Mie Univ.)
Prof.
Geomorphology around rivers
Haruyama
and alluvial plain (2)
(Mie Univ.)
Asso.Prof.
Finite Difference Method for
Sayama
ODE with Fortran Exercise
(ICHARM)
Asso.Prof.
Fundamentals of Physically
Sayama
based Rainfall-Runoff Models
(ICHARM)
17
Project Cycle Management
(PCM) (2)
Project Cycle Management
(PCM) (1)
(1)P-15 Quiz(2)
Hydrologic Application
(1)P-14 Exercise (2)
Self Study
Asso. Prof.
Sayama
(ICHARM)
Rainfall-runoff modelling I – Prof. Jaya
Conceptual type
(ICHARM)
Exercises on a typical rainfall- Prof. Jaya
runoff model I
(ICHARM)
Asso.Prof.
Finite Difference Method for
Sayama
Ordinary Differential Equations
(ICHARM)
20
ICHARM R&D Seminar by Prof. Asaeda
(1)P-11 Arrays
27
Self Study
Mr. Watanabe
ICHARM R&D Seminar by Prof. Koike
(3)-15
Self Study
Prof. Jaya
(ICHARM)
Prof.
Watanabe
(Kitami Institute
of Technology)
Prof.
Watanabe
(Kitami Institute
of Technology)
Prof. HUANG
(Sophia Univ)
Prof.
Watanabe
(Kitami Institute
of Technology)
Prof.
Watanabe
(Kitami Institute
of Technology)
Prof. HUANG
(Sophia Univ)
26
Examination
Bank erosion and drift woods
Re-meandering project for
river restoration
19
Calculation of backwater
profiles for levee design
Explicit Forward-TimeCentre-Space scheme
River restoration based on
sediment transport and
vegetation on stabilized bars
Vegetations, flows in
vegetated zone
Consultation with supervisors
(1)-15
(6)-15
(6)-14
(2)-14
(2)-13
(6)-13
(6)-12
(5)P-7
(5)P-6
(3)P-4
(3)P-3
(3)P-9
(3)P-8
(4)-13
14
15
Dr.
Ushiyama
(ICHARM)
Procedures and Structured
(3)
Finite Difference Method for
PDE with Fortran Exercise
Finite Difference Method for
Partial Differential Equations
Thesis Work
Thesis Work
18
Project Cycle Management
(PCM) (4)
Project Cycle Management
(PCM) (3)
11
Thesis Work
Thesis Work
Thesis Work
Thesis Work
4
Thesis Work
Thesis Work
Thesis Work
Thesis Work
28
Geographic Information
System (GIS) (2)
Geographic Information
System (GIS) (1)
Asso.Prof.
Sayama
(ICHARM)
Asso.Prof.
Sayama
(ICHARM)
Ms. Kita, Ms.
Iseki (GLM
Institute)
Geographic Information
(3)P-13 System (GIS) (6)
Geographic Information
Self Study
䠄䠒䠅
Dr. Kwak
(ICHARM)
Dr. Kwak
(ICHARM)
16
Examination
Mechanics of sediment
transportation (4)
Mechanics of sediment
transportation (3)
6
30
23
Supplimentary lecture
Supplimentary lecture
Supplimentary lecture
Self Study
Prof.
Egashira
(Newjec)
Prof.
Egashira
(Newjec)
Prof.
Fukuoka
(Chuo Univ.)
Prof.
Takeuchi
(ICHARM)
Prof.
Takeuchi
(ICHARM)
Prof.
Takeuchi
(ICHARM)
Prof.
Egashira
(Newjec)
Prof.
Egashira
(Newjec)
Exercises on flood routing
Prof. Jaya
(ICHARM)
Prof.
Bed forms and flow resistance
Egashira
(1)
(Newjec)
Prof.
Bed forms and flow resistance
Egashira
(2)
(Newjec)
20
Mechanics of debris flow (2)
Mechanics of debris flow (1)
Prof. HUANG
Consultation with supervisors
(4)P-8
(7)-12
(7)-11
(7)-10
(7)-9
13
Self Study
Examination
Consultation with supervisors
(7)-6
(7)-5
(3)
(3)
(3)
Ms. Kita, Ms. (2)
Iseki (GLM
Institute)
Dr. Kwak
(ICHARM)
Dr. Kwak
(ICHARM)
Rainfall-runoff modelling II – Prof. Jaya
Physics-based type
(ICHARM)
(3)P-12 System (GIS) (5)
(6)-8
19
Thesis Work
Thesis Work
Project Cycle Management
(PCM) (5)
12
Geographic Information
(3)P-11 System (GIS) (4)
Geographic Information
Thesis Work
Thesis Work
5
29
Self Study
Self Study
(3)P-10 System (GIS) (3)
Ms. Kita, Ms.
Iseki (GLM
(3)P-5
Institute)
Dr. Kwak
(ICHARM)
Dr. Kwak
(ICHARM)
Developments in social
Procedures and Structured
Prof. Hayashi
sciences on people’s reactions
(1)P-13 Programming (subroutine,
(Kyoto Univ.)
and responses to disasters
function)
Examination
22
Thesis Work
Self Study
21
function)
Prof.
Takeuchi
(ICHARM)
Dr.
Ushiyama
(ICHARM)
Prof. HUANG
(Sophia Univ)
Asso.Prof.
Sayama
(ICHARM)
Design of weirs and
spillways
Fundamentals of Conceptual
Rainfall-Runoff Models
(1)P-12 Programming (subroutine,
(2)-15
(5)P-2
Thesis Work
Thesis Work
Thesis Work
Thesis Work
21
14
7
31
24
17
Annex 5
February
13:1514:45
15:0016:30
9:0010:30
10:4512:15
13:1514:45
15:0016:30
9:0010:30
10:4512:15
13:1514:45
3rd
period
4th
period
1st
period
2nd
period
3rd
period
4th
period
1st
period
2nd
period
3rd
period
9:0010:30
10:4512:15
13:1514:45
15:0016:30
9:0010:30
10:4512:15
13:1514:45
15:0016:30
9:0010:30
10:4512:15
13:1514:45
15:0016:30
1st
period
2nd
period
3rd
period
4th
period
1st
period
2nd
period
3rd
period
4th
period
1st
period
2nd
period
3rd
period
4th
period
15:0016:30
10:4512:15
2nd
period
4th
period
9:0010:30
1st
period
26
19
12
5
29
22
(2)P7,8,9
(9)-8
Dr.
Sakamoto
(JCOLD)
(8)-7
(8)-6
(8)-5
27
Self Study
Sediment Management in
Reservoirs (2)
Sediment Management in
Reservoirs (1)
Environmental Impact of
Dams (2)
Prof. Sumi
(Kyoto Uni.)
(8)-9
(8)-8
Asso. Prof.
Yorozuya
(ICHARM)
Exercises
28
(9)-11
(8)-3
(9)-10
on
Engineering
Dam Construction (2)
Thesis Work
Thesis Work
Prof.
Yamaguchi
(PWRI)
Dr. Kashiwai
(Dam Center)
Thesis Work
Thesis Work
29
Survey and emergency
response for landslides
Introduction of landslides
Earthquake
Dams
Thesis Work
22
Dr. Hara
Prof. Jaya
(ICHARM)
for
Dr. Fujisawa
(NEXCO)
Dr. Tsunaki
(STC)
Dr. Omachi
(Dam
Center)
Dr. Kwak
(ICHARM)
Frequency Prof. Jaya
(ICHARM)
Frequency Prof. Jaya
(ICHARM)
Dam Construction (1)
on
Self Study
Exercises
Warning and evacuation
system for sediment-related
disasters
Thesis Work
15
Self Study
Kalman Filtering
Flood routing – Muskingam
Prof. Jaya
method;
Muskingam-Cunge
(ICHARM)
method
Geographic Information
(3)P-15 System (GIS) (8)
Countermeasures for
earthquake-induced natural
Dams
Dr. Osanai
(PWRI)
8
Self Study
(4)P-11 analysis I
(9)-4
(6)-11
(6)-10
Sabo Works in arid area and Prof. Ikeya
reforestation of degraded land (STC)
Planning and Operation of Dr. Umino
Flood Control
(PWRI)
Self Study
21
Flume experiments of open
channel flow
(4)P-13 analysis III
(9)-9
(8)-2
Frequency Prof. Jaya
(ICHARM)
Outline of Dam Engineering
on
Dr. Kwak
(ICHARM)
Prof.
Sasahara
(Kochi Univ.)
Consultation with supervisors
(8)-1
Exercises
(4)P-12 analysis II
Self Study
20
Thesis Work
Geographic Information
Design of Sabo dam
(3)P-14 System (GIS) (7)
(9)-3
Sabo planning
14
(9)-2
13
Thesis Work
Thesis Work
Thesis Work
7
DisasterMitigationPolicy(Prof.Morichi)
Thesis Work
Prof. Jaya
(ICHARM)
to Prof. Jaya
(ICHARM)
Exercises on Kalman filtering I
Introduction
Hydroinformatics
2/1
(6)-14
(8)-10
(6)-12
(8)-4
(9)-7
(9)-6
(9)-5
DisasterRiskManagement(Prof.Okazaki)
DisasterMitigationPolicy(Prof.Morichi)
25
DisasterRiskManagement(Prof.Okazaki)
31
24
Consultation with supervisors
(4)P-9
(6)-9
Self Study
6
30
23
Impact
Self Study
Error analysis
Dam Management
Self Study
3/1
Self Study
Frequency analysis
Environmental
Dams (1)
Self Study
23
Prof. Jaya
(ICHARM)
Prof.
Yamaguchi
(PWRI)
Prof. Jaya
(ICHARM)
of Dr. Amano
(NILIM)
Hazard mapping for sedimentrelated disasters
Dr.
Takanashi
Training of hazard mapping for
(Asia Air
sediment-related disasters (1)
Survey
Co.,LTD.)
Training of hazard mapping for
sediment-related disasters (2)
Self Study
16
Self Study
Self Study
Self Study
Self Study
9
2
26
17
Pre Meeting of Flume
experiments of open channel
flow
Outline of sediment-related
disasters and Sabo projects
Prof. Ikeya
(STC)
Asso. Prof.
Yorozuya
(ICHARM)
(8)-12
(8)-11
(7)-15
(9)-13
(9)-12
(6)-13
Prof.
Egashira
(Newjec)
Dr. Fujisawa
(NEXCO)
Dr. Tsunaki
(STC)
Prof. Jaya
(ICHARM)
Self Study
Effective Use of Existing Dams Prof.
Matsumoto
(Dam
Roles of Dams in the 21st
Center)
Century
Method to predict sediment
transport process in drainage
basins
2
Case study of landslide
Permanent measures for
landslide damage reduction
Parameter estimation
Self Study
24
Self Study
Prof.
Prediction of channel changes
Egashira
(1)
(Newjec)
Prof.
Prediction of channel changes
Egashira
(7)-14 (2)
(Newjec)
Post Meeting of Flume
Asso. Prof.
(2)P-10 experiments of open channel Yorozuya
(ICHARM)
flow
(7)-13
(2)P-6
(9)-1
10
Self Study
Exercises on Kalman filtering Prof. Jaya
(ICHARM)
(4)P-10 II
Site Visit (6)
Kyusyu Region
(By GRIPS)
3
27
3
25
18
11
4
28
March
April
May
Annex 6
5
PM
20
22
ADCP exercise in Tone River
21
Site visit (9) Dam & Sabo project
in Kanto Region
Thesis Work
15
14
Consultation with supervisors
8
Thesis Work
7
Thesis Work
Consultation with supervisors
Thesis Work
23
Thesis Work
16
Thesis Work
9
Thesis Work
2
1
Thesis Work
30
Thesis Work
24
Thesis Work
17
Thesis Work
10
3
Thesis Work
26
25
Thesis Work
24
3rd Interim Presentation
Thesis Work
23
Thesis Work
Consultation with supervisors
19
Thesis Work
12
Thesis Work
5
Thesis Work
Examination
Thesis Work
29
Thesis Work
Levee structure (2) (tentative)
Levee structure (1) (tentative)
Thesis Work
18
(4)-15
(4)-4
(4)-3
Thesis Work
ICHARM
Prof. Jaya
(ICHARM)
22
Thesis Work
17
Thesis Work
11
Thesis Work
4
Thesis Work
28
Thesis Work
Early evacuation of residents
Examination
15
Thesis Work
Thesis Work
Thesis Work
ICHARM
9
Self Study
Thesis Work
25
Lecture at Japan Meteorological Agency
18
Thesis Work
11
4
Thesis Work
27
Thesis Work
20
Thesis Work
13
Thesis Work
6
Thesis Work
30
Thesis Work
23
16
Self Study
2nd Interim Presentation
Site visit (7) Chugoku and Kinki Region
(Hii River, Ota River, Kamenose Landslice, etc.)
Prof. Jaya
(ICHARM)
Thesis Work
(4)-14
(6)-15
Thesis Work
21
14
Self Study
Self Study
(4)P-15 Exercises on error analysis
8
Thesis Work
16
PM
AM
7
Self Study
Thesis Work
Consultation with supervisors
10
Thesis Work
9
Thesis Work
Consultation with supervisors
3
Thesis Work
2
Thesis Work
Thesis Work
Consultation with supervisors
Thesis Work
Consultation with supervisors
Thesis Work
26
27
20
Thesis Work
Prof. Tanaka
(ICHARM)
Prof. Egashira
(Newjec)
Outline of flood hazard map
Prof. Tanaka
and evacuation plan and local
(ICHARM)
disaster management plan
Discussion on urban flood
management
Examination
13
Thesis Work
(4)-8
(4)-7
Prof. Tanaka
(ICHARM)
Application of Sabo/landslide Prof. Ikeya,
projects to overseas countries Dr. Osanai
River planning in Japan
19
Prof. Matsumoto,
Prof. Yamaguchi
Prof. Matsumoto,
Prof. Yamaguchi
(9)-15
6
Self Study
Self Study
Presentation of report (2)
Presentation of report (1)
Self Study
12
(4)-2
Prof. Tanaka
(9)-14
(ICHARM)
parameter Prof. Jaya
(ICHARM)
Self Study
River law in Japan
on
Consultation with supervisors
(8)-15
(8)-14
(4)-1
Exercises
(4)P-14 estimation
Consultation with supervisors
Thesis Work
13
6
29
22
15
8
4/1
25
18
11
4
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
15:0016:30
15:0016:30
4th
period
4th
period
13:1514:45
3rd
period
13:1514:45
10:4512:15
2nd
period
3rd
period
9:0010:30
1st
period
10:4512:15
15:0016:30
4th
period
2nd
period
13:1514:45
3rd
period
9:0010:30
10:4512:15
2nd
period
1st
period
9:0010:30
1st
period
13:1514:45
3rd
period
15:0016:30
10:4512:15
2nd
period
4th
period
9:0010:30
1st
period
26
Site visit (8)
Flood Fighting
Drill
19
12
5
28
21
14
7
31
24
17
10
June
July
August
September
Annex 7
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
PM
AM
9
2
26
19
12
5
29
22
15
8
7/1
24
13
5th Interim Presentation
Thesis Work
17
Thesis Work
Consultation with supervisors
16
21
15
27
22
Makig Action Plan
12
Presentation on Action Plan
Makig Action Plan
11
ICHARM R&D Seminar
Makig Action Plan
5
Makig Action Plan
29
Thesis Work
23
24
13
Closing Ceremony at JICA
Graduation Ceremony at GRIPS
14
Site visit (10)
Shingu City, Ise City
7
6
Presentation
at JSCE annual meeting
Makig Action Plan
31
Thesis Work
Makig Action Plan
30
Thesis Work
Thesis Work
17
Thesis Work
16
Thesis Work
15
10
Final Presentation
9
3
Thesis Work
Thesis Work
2
Deadline of submission of 2nd draft
thesis
26
Thesis Work
Thesis Work
20
Thesis Work
13
Deadline of submission of the 1st draft
thesis
6
Thesis Work
29
Thesis Work
22
Thesis Work
Thesis Work
19
Thesis Work
12
Thesis Work
5
Thesis Work
28
Thesis Work
8
Thesis Work
Thesis Work
10
Makig Action Plan
14
Thesis Work
6/1
4th Interim Presentation
Thesis Work
Thesis Work
8
Thesis Work
8/1
Thesis Work
25
Thesis Work
Makig Action Plan
4
3
28
Makig Action Plan
27
Submission of Master Thesis to GRIPS
21
Thesis Work
20
Thesis Work
Consultation with supervisors
14
Thesis Work
13
Thesis Work
Consultation with supervisors
7
Thesis Work
6
Thesis Work
Consultation with supervisors
31
Thesis Work
30
Thesis Work
Consultation with supervisors
24
Thesis Work
23
Thesis Work
Consultation with supervisors
Thesis Work
Thesis Work
10
9
18
11
Thesis Work
Thesis Work
Thesis Work
4
3
2
27
Thesis Work
26
Thesis Work
25
Thesis Work
Consultation with supervisors
20
Thesis Work
19
Thesis Work
18
Thesis Work
Thesis Work
7
Thesis Work
6
31
Thesis Work
30
Thesis Work
Thesis Work
Consultation with supervisors
Consultation with supervisors
17
PM
12
11
Thesis Work
5
Thesis Work
4
Thesis Work
Consultation with supervisors
29
Thesis Work
28
Thesis Work
Consultation with supervisors
ICHARM R&D Seminar
10
3
27
AM
PM
AM
PM
AM
15
8
9/1
25
18
11
4
28
21
14
7
30
23
16
9
2
Curriculum䚷(Recommended course)
Lecture
Disaster Mitigation Policy
Disaster Risk Management
Basic Hydrology
Number
DMP200E
DMP201E
DMP280E
Instructor
Prof. Shigeru MORICHI
Prof. Kenji OKAZAKI
Prof. Amithirigala Widhanelage
JAYAWARDENA
Period
Winter
Winter
Fall through Winter
1
Lecture
Introduction: Coverage of this
class
Disaster mitigation policy
Lecturer
Prof. Morichi,
GRIPS
Lecture
Introduction: Disasters in the
world
Lecturer
Prof. Okazaki,
GRIPS
Lecture
Lecturer
Basic
concepts
of
the Prof.
Hydrological Cycle; Processes in Jayawardena,
ICHARM
the Hydrological Cycle
2
Social systems against disaster
Prof. Morichi,
GRIPS
International activities for
disaster mitigation
Prof. Okazaki,
GRIPS
Precipitation
–
Types, Prof.
measurement and presentation Jayawardena,
of data
ICHARM
3
Education on basic knowledge for Prof. Morichi,
disasters (1)
GRIPS
Japan’s policy making
Prof. Okazaki,
GRIPS
Extreme weather – cyclones, Prof.
typhoons, hurricanes
Jayawardena,
Evaporation
and
evapo- ICHARM
transpiration; Infiltration
4
Education on basic knowledge for Prof. Morichi,
disasters (2)
GRIPS
Basics of Disaster Risk
Management
Prof. Okazaki,
GRIPS
Runoff
–
Components, Prof.
measurement and estimation of Jayawardena,
runoff
ICHARM
5
Lessons from tragedies
Prof. Hitoshi
IEDA,The
University of
Tokyo
Disaster risk management
policies in Japan -1
Prof. Okazaki,
GRIPS
Peak
discharge
estimation; Prof.
Rational
Method,
Baseflow Jayawardena,
Separation
ICHARM
6
Reliability analysis of
transportation network
Prof. Morichi,
GRIPS
Disaster risk management
policies in Japan -2
Prof. Okazaki,
GRIPS
Concept of rainfall excess; Role Prof.
of infiltration and evaporation
Jayawardena,
ICHARM
7
Policy for Transportation
Infrastructure
Prof. Morichi,
GRIPS
Lessons from Hanshin-Awaji
Earthquake Disaster
Prof. Okazaki,
GRIPS
Unit Hydrograph Methods I
Prof.
Jayawardena,
ICHARM
8
Policy for road infrastructure
Prof. Morichi,
GRIPS
Building regulation
Prof. Okazaki,
GRIPS
Unit Hydrograph Methods II
Prof.
Jayawardena,
ICHARM
9
Policy for port infrastructure
Prof. Morichi,
GRIPS
Housing safety
Prof. Okazaki,
GRIPS
Remote sensing in Hydrology
Ass. Prof.
Fukami,
ICHARM
10
Policy for airport infrastructure
Prof. Morichi,
GRIPS
Issues of disaster management
Prof. Okazaki,
GRIPS
Satellite observation of rainfall Dr. Kachi, Dr.
(1)
Kubota, Japan
Aerospace
Exploration
Agency (JAXA)
11
Policy for airport infrastructure
Prof. Morichi,
GRIPS
Urban development and disaster Prof. Okazaki,
management
GRIPS
Satellite observation of rainfall Dr. Kachi, Dr.
(2)
Kubota, Japan
Aerospace
Exploration
Agency (JAXA)
12
Land use and regulations
Prof. Morichi,
GRIPS
Community based disaster risk
management
Prof. Okazaki,
GRIPS
Probability and statistics
hydrology I; IDF curves
13
Policy Making Process
Prof. Morichi,
GRIPS
Practical risk assessment I
Prof. Okazaki,
GRIPS
Probability and statistics in Prof.
hydrology II; Extreme value Jayawardena,
distribution
ICHARM
14
Presentation by students and
discussion (1)
Prof. Morichi,
GRIPS
Practical risk assessment II
Prof. Okazaki,
GRIPS
Basic concepts
Hydrology
15
Presentation by students and
discussion (2)
Prof. Morichi,
GRIPS
Special lecture
Annex 8
Examination
of
in Prof.
Jayawardena,
ICHARM
Stochastic Prof.
Jayawardena,
ICHARM
Basic Concepts of Integrated Flood Risk
management (IFRM)
Hydraulics
Lecture
Urban Flood Management and Flood Hazard
Mapping
Number
DMP281E
DMP282E
DMP287E
Instructor
Prof. Guangwei HUANG
Prof. Kuniyoshi TAKEUCHI
Prof. Shigenobu TANAKA
Fall through Winter
Fall through Spring
Period
Fall through Winter
1
Lecture
Lecturer
Introduction & Fundamental Prof. Huang,
equations
ICHARM
Lecture
Lecturer
Lecture
Introduction: What is natural Prof. Takeuchi, River law in Japan
disaster? Overview of the class ICHARM
Lecturer
Dr. Tanaka,
ICHARM
2
Flow resistance in open channel Prof. Huang,
ICHARM
Introduction of Risk, Hazard Prof. Takeuchi, River planning in Japan
and Vulnerability
ICHARM
Dr. Tanaka,
ICHARM
3
Flow resistance calculation in Prof. Huang,
engineering practice
ICHARM
PAR Model (1)
Prof. Takeuchi, Levee structure (1)
Root causes, progress of dynamic ICHARM
pressure and unsafe conditions
ICHARM
4
Steady
uniform
prismatic channels
PAR Model (2)
Concrete examples
Prof. Takeuchi, Levee structure (2)
ICHARM
ICHARM
5
Steady gradually-varied flow – Prof. Huang,
backwater surface profiles
ICHARM
ACCESS Model
Prof. Takeuchi, River
management
ICHARM
normal time
during Ara River MLIT
Office
6
Numerical solution of the Prof. Huang,
gradually-varied flow equation ICHARM
Disaster management cycle; Prof. Takeuchi, River
management
Hyogo Framework for Action
ICHARM
flooding
during Tone
River
MLIT Office
7
Hydraulic jump
Prof. Huang,
ICHARM
IFRM and traditional FRM;
IFRM as part of IWRM
Prof. Takeuchi, Discussion on
ICHARM
management
8
The kinematic wave model
Prof. Huang,
ICHARM
Concept of IWRM (1):
Agenda 21, Global Water
Partnership
Prof. Takeuchi, Outline of flood hazard map and Dr. Tanaka,
ICHARM
evacuation plan and local ICHARM
disaster management plan
9
The diffusive wave model
Prof. Huang,
ICHARM
Prof. Takeuchi, Geomorphology around rivers Prof.
Concept of IWRM (2):
and alluvial plain (1)
Haruyama,
Guideline for IWRM at basin ICHARM
Mie Univ.
scale
10
The dynamic wave model
Prof. Huang,
ICHARM
Japanese experiences (1)
Prof. Takeuchi, Geomorphology around rivers Prof.
Flood damages and flood control ICHARM
and alluvial plain (2)
Haruyama,
investment
Mie Univ.
11
Method of characteristics
Prof. Huang,
ICHARM
Japanese experiences (2)
Ground subsidence control
Prof. Takeuchi, Disaster
ICHARM
(DIG)
12
The Preissmann scheme
Prof. Huang,
ICHARM
Global trends (1)
Impact of climatic change
Prof. Oki,
Tokyo Univ.
Case study of integrated flood Mr. Imbe,
Association
management -Tsurumi river-
13
Explicit Forward-Time-Centre- Prof. Huang,
Space scheme
ICHARM
Global trends (2)
International actions
Prof. Oki,
Tokyo Univ.
Developments in social sciences Prof. Hayashi,
on people ’ s reactions and Kyoto Univ.
responses to disasters
14
Calculation
of
backwater Prof. Huang,
profiles for levee design
ICHARM
Future
Issues
of
IFRM: Prof. Takeuchi, Early evacuation of residents
Adaptation;
Aging
society; ICHARM
Depopulation; Social Capital;
ICHARM
15
Design of weirs and spillways
Application of Sabo Works and Mr. Watanabe
landslide countermeasures to
overseas countries
ICHARM
flow
in Prof. Huang,
ICHARM
Prof. Huang,
ICHARM
Annex 9
urban
imagination
flood Dr. Tanaka,
ICHARM
game ICHARM
for
Rainwater Storage
and
Infiltration
Technology
Examination
Advanced Hydrology
Lecture
Flood Hydraulics and Sediment Transport
Mechanics of Sediment Transportation and
River Changes
Number
DMP380E
DMP381E
DMP382E
Instructor
Prof. Amithirigala Widhanelage
JAYAWARDENA
Prof. Shoji FUKUOKA
Prof. Shinji EGASHIRA
Fall through Winter
Period
Fall through Winter
Fall through Winter
Lecture
Lecturer
Hydrological modelling – basic Prof.
concepts and approaches
Jayawardena,
ICHARM
Lecture
Lecturer
Characteristics
and
river Prof. Fukuoka,
management of Japanese rivers Chuo Univ.
2
Systems theory approach I – Prof.
Linear theory; Time domain Jayawardena,
analysis; Frequency domain ICHARM
analysis
Prediction method of flow Prof. Fukuoka,
resistance
in
rivers
with Chuo Univ.
compound
channels
and
application to river course
design (1)
Introduction (2)
Prof. Egashira,
- Sediment transportation and Newjec
corresponding channel changes
- Methods to evaluate channel
changes
3
Systems theory approach II – Prof.
Non-linear systems, multi-linear Jayawardena,
systems
ICHARM
Prediction method of flow Prof. Fukuoka,
resistance
in
rivers
with Chuo Univ.
compound
channels
and
application to river course
design (2)
Mechanics
of
sediment Prof. Egashira,
transportation (1)
Newjec
- Parameters associated with
sediment transportation
4
Instantaneous Unit Hydrograph Prof.
(IUH)
Jayawardena,
ICHARM
Steady quasi-two dimensional Prof. Fukuoka,
analysis of flood flows (1)
Chuo Univ.
Mechanics
of
sediment Prof. Egashira,
transportation (2)
Newjec
- Critical condition for initiating
bed load
5
Conceptual models of IUH
Prof.
Jayawardena,
ICHARM
Steady quasi-two dimensional Prof. Fukuoka,
analysis of flood flows (2)
Chuo Univ.
Mechanics
of
transportation (3)
- Bed load formulas
6
Synthetic Unit Hydrograph
Prof.
Jayawardena,
ICHARM
Unsteady
quasi-two- Prof. Fukuoka,
dimensional analysis of flood Chuo Univ.
flows (1)
Mechanics of sediment
transportation (4)
- Bed load formulas
7
Rainfall-runoff modelling I – Prof.
Conceptual type
Jayawardena,
ICHARM
Unsteady
quasi-two- Prof. Fukuoka,
dimensional analysis of flood Chuo Univ.
flows (2)
Mechanics
of
sediment Prof. Egashira,
transportation (5)
Newjec
- Extension of bed load formula to
non-uniform sediment
8
Rainfall-runoff modelling II – Prof.
Physics-based type
Jayawardena,
ICHARM
To
derive
a
relationship Prof. Fukuoka,
between stable dimensionless Chuo Univ.
width, depth and discharge in
natural rivers - learning from
natural rivers
Mechanics
of
transportation (6)
- Suspended load
9
Introduction
Hydroinformatics
How do we make a river cross- Prof. Fukuoka,
section
harmonizing
flood Chuo Univ.
control and river environment
Mechanics of debris flow (1)
Prof. Egashira,
- Constitutive equations
Newjec
- Debris flow characteristics over
erodible beds
1
to Prof.
Jayawardena,
ICHARM
Lecture
Lecturer
Prof. Egashira,
Newjec
Introduction (1)
- Characteristics of sediment
sediment Prof. Egashira,
Newjec
Prof. Egashira,
Newjec
sediment Prof. Egashira,
Newjec
10
Flood routing – Muskingam Prof.
method;
Muskingam-Cunge Jayawardena,
method
ICHARM
1-D bed deformation, computing Prof. Watanabe, Mechanics of debris flow (2)
Prof. Egashira,
model
Kitami Institute - A bed load formula derived from Newjec
constitutive equations
of Technology
11
Kalman Filtering
Prof.
Jayawardena,
ICHARM
2-D bed deformation, sand Prof. Watanabe, Bed forms and flow resistance (1)
Prof. Egashira,
waves and bars, meandering
Kitami Institute - Geometric characteristics of bed Newjec
forms
of Technology
- Formative domain of bed forms
12
Frequency analysis
Prof.
Jayawardena,
ICHARM
Vegetations, flows in vegetated Prof. Watanabe, Bed forms and flow resistance (2)
zone
Kitami Institute - Flow resistance
of Technology
13
Parameter estimation
Prof.
Jayawardena,
ICHARM
River restoration based on Prof. Watanabe, Prediction of channel changes (1)
Prof. Egashira,
sediment
transport
and Kitami Institute - Governing equations employed in Newjec
steep areas
vegetation on stabilized bars
of Technology
Prof.
Jayawardena,
ICHARM
Re-meandering project for river Prof. Watanabe, Prediction of channel changes (2)
Prof. Egashira,
restoration
Kitami Institute - Governing equations employed in Newjec
alluvial reaches
of Technology
14
15
Errors in frequency analysis
Examination
Prof. Egashira,
Newjec
- Topographic change in steep areas
- Topographic change in alluvial
reaches
Bank erosion and drift woods
Prof. Watanabe, Method to predict
Kitami Institute transport process in
basins
of Technology
Sediment
drainage basin
Annex 10
sediment Prof. Egashira,
drainage Newjec
management
in
Lecture
Sustainable Reservoir Development &
Management
Control Measures for Landslide & Debris Flow
Number
DMP383E
DMP384E
Instructor
Prof. Norihisa MATSUMOTO
Prof. Hiroshi IKEYA
Fall through Winter
Fall through Winter
Period
1
Lecture
Outline of Dam Engineering
Lecture
Lecturer
Dr. Sakamoto, Outline of sediment-related
Japan
disasters and Sabo projects
Commission on
Large Dams
Operation
2
Planning and
Flood Control
3
Earthquake
Dams
4
Environmental Impact of Dams Dr. Amano,
(1)
NILIM
Warning and evacuation system Dr. Hara, Sabo
for sediment-related disasters
Technical
Center
5
Environmental Impact of Dams Prof.Sumi,
(2)
Kyoto Univ.
Hazard mapping for sediment- Dr. Takanashi,
related disasters
Asia Air Survey
CO.,LTD
6
Sediment
Management
Reservoirs (1)
in Prof.Sumi,
Kyoto Univ.
Training of hazard mapping for Dr. Takanashi,
sediment-related disasters (1)
Asia Air Survey
CO.,LTD
7
Sediment
Management
Reservoirs (2)
in Prof.Sumi,
Kyoto Univ.
Training of hazard mapping for Dr. Takanashi,
sediment-related disasters (2)
Asia Air Survey
CO.,LTD
8
Dam Construction (1)
Prof.
Yamaguchi,
PWRI
Sabo Works in arid area and
reforestation of degraded land
9
Dam Construction (2)
Dr. Kashiwai,
Japan Dam
Engineering
Center
Countermeasures
earthquake-induced
Dams
10
Dam Management
Prof.
Yamaguchi,
PWRI
Introduction of landslides
11
Effective Use of Existing Dams
Prof.
Matsumoto,
Japan Dam
Engineering
Center
Survey and emergency response Dr. Fujisawa,
for landslide
NEXCO
12
Roles of Dams in 21st Century
Prof.
Matsumoto,
Japan Dam
Engineering
Center
Permanent measures for
landslide damage reduction
Dr. Tsunaki,
SABO
Technical
Center
13
Practice on Dam Planning (1)
-Presentation-
Prof.
Matsumoto,
Prof.
Yamaguchi
Case study of landslide
Dr. Fujisawa,
NEXCO
14
Practice on Dam Planning (2)
-Presentation-
Prof.
Matsumoto,
Prof.
Yamaguchi
Application of Sabo/landslide
Prof. Ikeya,
projects to overseas countries (1) Dr. Osanai
-Presentation-
15
Tour of Dam Laboratory of
PWRI
Mr. Umino,
PWRI
Application of Sabo/landslide
Prof. Ikeya,
projects to overseas countries (2) Dr. Osanai
-Presentation-
Engineering
of Mr. Umino,
PWRI
Lecturer
Prof. Ikeya,
SABO
Technical
Center
for Dr. Omachi
Japan Dam
Engineering
Center
Sabo planning
Prof. Sasahara,
Kochi Univ.
Design of Sabo dam
Prof. Sasahara,
Kochi Univ.
Annex 11
Prof. Ikeya,
SABO
Technical
Center
for Dr. Osanai,
natural PWRI
Dr. Tsunaki,
SABO
Technical
Center
Curriculum䚷䠄Elective course)
Computer Programming
Lecture
Practices in Hydraulics
Practice on Local Disaster Management Plan
Number
DMP180E
DMP288E
DMP286E
Instructor
Asso. Prof. Takahiro SAYAMA
Asso. Prof. Atsuhiro YOROZUYA
Prof. Shigenobu TANAKA
Fall through Winter
Period
Fall through Spring
Fall through Spring
1
Lecture
Introduction of Computer
Programming with Fortran90
Lecturer
Asso. Prof.
Sayama,
ICHARM
Lecture
Mathematic 1 (Ordinary
Differential equations)
Lecturer
Dr. Yorozuya,
ICHARM
Lecture
Project Cycle Management
(PCM) (1)
Lecturer
Ms. Kita, Ms
Iseki,
GLM Institute
2
Variables
Asso. Prof.
Sayama,
ICHARM
Mathematic 2 (Partial
Differential equations)
Dr. Yorozuya,
ICHARM
Project Cycle Management
(PCM) (2)
Ms. Kita, Ms
Iseki,
GLM Institute
3
Arithmetic Calculation
Asso. Prof.
Sayama,
ICHARM
Review of Advection and
Diffusion
Dr. Yorozuya,
ICHARM
Project Cycle Management
(PCM) (3)
Ms. Kita, Ms
Iseki,
GLM Institute
4
Program Structure (if, do loop)
Dr. Hasegawa, Review of General transport
ICHARM
equations
Dr. Yorozuya,
ICHARM
Project Cycle Management
(PCM) (4)
Ms. Kita, Ms
Iseki,
GLM Institute
5
Program Structure (if, do loop)
Dr. Hasegawa, Discussion about Quiz-1
ICHARM
Dr. Yorozuya,
ICHARM
Project Cycle Management
(PCM) (5)
Ms. Kita, Ms
Iseki,
GLM Institute
6
Program Structure (if, do loop)
Dr. Hasegawa, Review of One dimensional
ICHARM
energy equation
Dr. Yorozuya,
ICHARM
Flood Fighting Drill
ICHARM
7
I/O Statement
Dr. Hasegawa, Review of Specific energy
ICHARM
Dr. Yorozuya,
ICHARM
Town Watching (Field survey)
ICHARM
8
Hydrologic Application Exercise
(1)
Asso. Prof.
Sayama,
ICHARM
9
Quiz(1)
Dr. Hasegawa, Discussion about Quiz-2
ICHARM
Dr. Yorozuya,
ICHARM
Geographic Information System Dr. Kwak,
(GIS) (2)
ICHARM
10
Arrays
Dr. Ushiyama,
ICHARM
Review of Specific force
Dr. Yorozuya,
ICHARM
Geographic Information System Dr. Kwak,
(GIS) (3)
ICHARM
11
Arrays
Dr. Ushiyama,
ICHARM
Review of Hydraulic jump,
Junction and Diversion
Dr. Yorozuya,
ICHARM
Geographic Information System Dr. Kwak,
(GIS) (4)
ICHARM
12
Procedures and Structured
Programming (subroutine,
function)
Dr. Ushiyama,
ICHARM
Review of Composite channel
flow
Dr. Yorozuya,
ICHARM
Geographic Information System Dr. Kwak,
(GIS) (5)
ICHARM
13
Procedures and Structured
Programming (subroutine,
function)
Dr. Ushiyama,
ICHARM
Review of Secondary flow
Dr. Yorozuya,
ICHARM
Geographic Information System Dr. Kwak,
(GIS) (6)
ICHARM
14
Hydrologic Application Exercise
(2)
Asso. Prof.
Sayama,
ICHARM
Review of Density currents
Dr. Yorozuya,
ICHARM
Geographic Information System Dr. Kwak,
(GIS) (7)
ICHARM
15
Quiz(2)
Dr. Ushiyama,
ICHARM
Discussion about Examination
Dr. Yorozuya,
ICHARM
Geographic Information System Dr. Kwak,
(GIS) (8)
ICHARM
Review of Gradually varied flow Dr. Yorozuya,
ICHARM
Annex 12
Geographic Information System Dr. Kwak,
(GIS) (1)
ICHARM
Lecture
Practice on Advanced Hydrology
Practice on Flood Hazard Modeling & Flood
Forecasting
Site Visit of Water-related Disaster
Management Practice in Japan
Number
DMP385E
DMP386E
DMP390E
Instructor
Prof. Amithirigala Widhanelage
JAYAWARDENA
Asso. Prof. Kazuhiko FUKAMI
Prof. Shigenobu TANAKA
Fall through Spring
1
Lecture
Lecturer
Exercises on System function Prof.
estimation
Jayawardena,
ICHARM
Lecture
Introduction to Flood Hazard
Modeling
Lecturer
Ass. Prof.
Sayama,
ICHARM
Lecture
River in Japan -Diversion
Channel, Levee ,River
administration - (Ara River)
Lecturer
MLIT local
office
2
Exercises on
estimation
Fundamentals of Conceptual
Rainfall-Runoff Models
Ass. Prof.
Sayama,
ICHARM
Flood information (MLIT
Regional bureau, Kita City or
Kuki City䠅
MLIT local
office
3
Exercises on Impulse and Prof.
Frequency Response Functions Jayawardena,
ICHARM
Finite Difference Method for
Ass. Prof.
Ordinary Differential Equations Sayama,
ICHARM
Retarding Basin (Watarase
Retarding Basin)
MLIT local
office
4
Exercises on IUH determination Prof.
Jayawardena,
ICHARM
Finite Difference Method for
ODE with Fortran Exercise
Ass. Prof.
Sayama,
ICHARM
Metropolitan Area Outer
Underground Discharge
Channel
MLIT local
office
5
Exercises on IUH application
Prof.
Jayawardena,
ICHARM
Fundamentals of Physically
based Rainfall-Runoff Models
Ass. Prof.
Sayama,
ICHARM
Integrated flood management
(Tsurumi River)
MLIT local
office
6
Exercises on a typical rainfall- Prof.
runoff model I
Jayawardena,
ICHARM
Finite Difference Method for
Partial Differential Equations
Ass. Prof.
Sayama,
ICHARM
Collaborative administration of MLIT local
Ikari Dam & Kawaji Dam
office
7
Exercises on a typical rainfall- Prof.
runoff model II
Jayawardena,
ICHARM
Finite Difference Method for
PDE with Fortran Exercise
Ass. Prof.
Sayama,
ICHARM
Sabo work in Ashio
MLIT local
office
8
Exercises on flood routing
Introduction of GFAS (Global
Flood Alert System)
Ass. Prof.
Fukami,
ICHARM
River Basin Planning (1) (Hii
River)
MLIT local
office
9
Exercises on Kalman filtering I Prof.
Jayawardena,
ICHARM
Introduction of IFAS
(Integrated Flood Analysis
System)
Mr. Nabesaka, River Basin Planning (2) (Ota
River)
Dr. Sugiura,
Mr. Fujioka,
ICHARM
MLIT local
office
10
Exercises on Kalman filtering II Prof.
Jayawardena,
ICHARM
Correction and Validation of
Satellite-Based Rainfall
Mr. Nabesaka, River improvement in mid-size
river
Dr. Sugiura,
Mr. Fujioka,
ICHARM
Tokyo
Metropolitan
11
Exercises
analysis I
on
Frequency Prof.
Jayawardena,
ICHARM
Runoff analysis with IFAS (1)
Data import, Model building
Mr. Nabesaka, Sabo work in Kamenose
Dr. Sugiura,
Mr. Fujioka,
ICHARM
MLIT local
office
12
Exercises
analysis II
on
Frequency Prof.
Jayawardena,
ICHARM
Runoff analysis with IFAS (2)
Parameter estimation
Mr. Nabesaka, Recovery from flood
Dr. Sugiura,
Mr. Fujioka,
ICHARM
Shingu City,
Wakayama
Pref.
13
Exercises
analysis III
on
Frequency Prof.
Jayawardena,
ICHARM
Runoff analysis with IFAS (3)
Validation of calculated
discharge
Mr. Nabesaka, Community based disaster
management in Ise
Dr. Sugiura,
Mr. Fujioka,
ICHARM
Ominato
comunnity, Ise
City, Mie Pref.
14
Exercises
estimation
on
parameter Prof.
Jayawardena,
ICHARM
Runoff analysis with IFAS (4)
Application to actual basins
Mr. Nabesaka,
Dr. Sugiura,
Mr. Fujioka,
ICHARM
15
Exercises on error analysis
Run-off analysis with IFAS (5)
Application to actual basins
Mr. Nabesaka,
Dr. Sugiura,
Mr. Fujioka,
ICHARM
least
squares Prof.
Jayawardena,
ICHARM
Prof.
Jayawardena,
ICHARM
Prof.
Jayawardena,
ICHARM
Fall through Spring
Fall through Summer
Period
Annex 13
Subject: Computer Programming
Course number㸸DMP180E
Instructor㸸Ass. Prof. Takahiro SAYAMA
Term / Time㸸Fall through Winter
㸯 Course Description
This course provides general knowledge on Fortran90 computer programming and
its skills for solving water-related problems covered in Course No. DMP280E “Basic
Hydrology”, No. DMP281E “Hydraulics”, No. DMP380E “Advanced Hydrology”,
No.DMP381E “Flood Hydraulics and Sediment Transport”, and No.DMP386E
“Practice on Flood hazard Modeling & Flood Forecasting”.
㸰 Course Outline (Course Topics)
Week
㸯㸸Introduction of Computer Programming with Fortran90
㸰㸸Variables
㸱㸸Arithmetic Calculation
㸲㸸Program Structure (if, do loop)
㸳㸸Program Structure (if, do loop)
㸴㸸Program Structure (if, do loop)
㸵㸸I/O Statement
㸶㸸Hydrologic Application Exercise (1)
㸷㸸Quiz(1)
㸯㸮㸸Arrays
㸯㸯㸸Arrays
㸯㸰㸸Procedures and Structured Programming (subroutine, function)
㸯㸱㸸Procedures and Structured Programming (subroutine, function)
㸯㸲㸸Hydrologic Application Exercise (2)
㸯㸳㸸Quiz(2)
㸱 Grading
Quiz (50%)
Reports (50%)
If a report is late for the deadline, it will be not evaluated.
㸲 Textbooks
Reference: Fortran95/2000 for Scientists and Engineers (Third Ed.), by Stephen J. Chapman,
McGraw-Hill,
Annex 14
Subject: Basic Hydrology
Course number㸸DMP280E
Instructor㸸Prof. A. W. Jayawardena
Term / Time㸸Fall through Winter
㸯 Course Description
The aim of this course is to introduce and expose the students to the basic concepts of
hydrology including the different processes, quantification of hydrological variables and
their measurement and/or estimation, unit hydrograph methods and the application of
probability and statistics in hydrology
㸰 Course Outline (Course Topics)
Week
㸯㸸Basic concepts of the Hydrological Cycle; Processes in the Hydrological Cycle
㸰㸸Precipitation – Types, measurement and presentation of data
㸱㸸Extreme weather – cyclones, typhoons, hurricanes
Evaporation and evapo-transpiration; Infiltration
㸲㸸Runoff – Components, measurement and estimation of runoff
㸳㸸Peak discharge estimation; Rational Method, Baseflow Separation
㸴㸸Concept of rainfall excess; Role of infiltration and evaporation
㸵㸸Unit Hydrograph Methods I
㸶㸸Unit Hydrograph Methods II
㸷㸸Remote sensing in Hydrology
㸯㸮㸸Satellite observation of rainfall (1) (by JAXA)
㸯㸯㸸Satellite observation of rainfall (2) (by JAXA)
㸯㸰㸸Probability and statistics in hydrology I; IDF curves
㸯㸱㸸Probability and statistics in hydrology II; Extreme value distribution
㸯㸲㸸Basic concepts of Stochastic Hydrology
㸯㸳㸸Examination
㸱 Grading
60% by examination; 40% by in-course assessment
㸲 Textbooks
4-1 Required
4-2 Others
References (selected)
¾ Linsley, R. K., Kohler, M.A. and Paulhus, J.L.H. (1988): Hydrology for Engineers, SI
Metric Edition), McGraw-Hill Book Company
¾ Raudkivi, A. J. (1979): Hydrology – An Advanced Introduction to Hydrological Processes
and Modelling, Pergamon Press.
¾ Shaw, E. M. (1983) Hydrology in Practice, Van Nostrand Reinhold (UK)
¾ Singh, V. P. (1992): Elementary Hydrology, Prentice Hall
¾ Viessman, W., Lewis, G. L. and knapp, J.W. (1989): Introduction to Hydrology (Third
Edition), Harper Row, Publishers.
¾ Wanielista, M., Kersten, R. and Eaglin, R. (1997): Hydrology: Water quantity and quality
control, Second Edition, John Wiley & Sons Inc.
¾ Course Lecture Notes
Annex 15
Subject: Hydraulics
Course number㸸DMP281E
Instructor㸸Prof. Guangwei HUANG
Term / Time㸸Fall through Winter
1㸬Course Description
Analysis of open channel flows and a selective presentation of some of the common river
management problems encountered by practicing engineers with the inclusion of related
computational techniques.
Course Goal:
To enable students to conduct professional channel flow analysis and applications and to
develop independent learning and problem solving skills. After completing this course, you will
be able to…
1. set up systems of equations representing flow through channel systems
2. perform 1-D steady and unsteady flow analysis of open channel systems
3. apply solution approaches to levee design
4. gain advanced knowledge on the design of weirs and spillways
5. present technical information effectively
2.
Course Outline (Course Topics)
1. Basic principles of open channel flows
z Introduction & Fundamental equations
z Flow resistance in open channel
z Flow resistance calculation in engineering practice
2. Uniform, gradually-varied and rapidly-varied flows
z Steady uniform flow in prismatic channels
z Steady gradually-varied flow – backwater surface profiles
z Numerical solution of the gradually-varied flow equation
z Hydraulic jump
Quiz
3. Unsteady flows
z The kinematic wave model
z The diffusive wave model
z The dynamic wave model
z Method of characteristics
z The Preissmann scheme
z Explicit Forward-Time-Centre-Space scheme
Exercise
4. Practical topics
z Calculation of backwater profiles for levee design
z Design of weirs and spillways
Annex 16
Final exam
3.
Grading:
Class participation (30%), Quiz and exercise (30%), Examination (40%)
4. Textbooks
Recommended books:
Open-channel Hydraulics, Ven Te Chow;
Practical aspects of computational river hydraulics, J.A. Cunge, F.M. Holly, Jr., A.
Verwey.
Handouts will be distributed.
Annex 17
Subject:
Basic Concepts of Integrated Flood Risk management (IFRM)
Course number㸸DMP282E
Instructor㸸Prof. Kuniyoshi TAKEUCHI
Term / Time㸸Fall through Winter
㸯 Course Description
This course provides the basic concepts of “Integrated Flood Risk Management
(IFRM)” as part of Integrated Water resources Management (IWRM). The
mechanism of disaster risk development with natural hazard, societal vulnerability,
exposure and coping capacity will be emphasized. New concepts of IWRM at basin
scale will be introduced and, as concrete examples, Japanese flood management
experiences and global activity trends will be introduced emphasizing good
practices and key for success. Anticipated future direction of risk management to
cope with societal changes and global climate changes will also be covered.
㸰 Course Outline (Course Topics)
1. Introduction: What is natural disaster? Overview of the course
2. Introduction of Risk, Hazard and Vulnerability
3. PAR Model (1) Root causes, progress of dynamic pressure and unsafe conditions
4. PAR Model (2) Concrete examples
5. ACCESS Model
6. Disaster management cycle; Hyogo Framework for Action
7. IFRM and traditional FRM; IFRM as part of IWRM
8. Concept of IWRM (1): Agenda 21, Global Water Partnership
9. Concept of IWRM (2): Guideline for IWRM at basin scale
10. Japanese experiences (1) Flood damages and flood control investment
11. Japanese experiences (2) Comprehensive flood control measures and focus
expansion from river to basin
12. Global trends (1) Impact of climatic change
13. Global trends (2) International actions
14. Future Issues of IFRM: Adaptation; Aging society; Depopulation; Social Capital;
15. Examination
㸱 Grading
Active participation(30%), Reports(40%), Final Examination(30%)
㸲 Textbooks
4-1 Required
1. Ben Wisner, Piers Blaikie, Terry Cannon and Ian Davis, At Risk -natural
hazards, people’s vulnerability and disasters- (Routledge, London & NY,
2004)
2. UNESCO IWRM guidelines steering committee, IWRM Guidelines at River
Basin Level: Part 1-1 Principles, 2-1 Part 2-1 Coordination, 2-2 Flood
Management, 2-3 Irrigation. (UNESCO, 2009)
Annex 18
Subject: Practice on Local Disaster Management Plan Course number㸸DMP286E
Instructor㸸Prof. Shigenobu TANAKA
Term / Time㸸Fall through Spring
㸯 Course Description
This course aims at consolidating the material covered in Course No. DMP287E
“Urban Flood Management and Flood Hazard Mapping”.
Exercises related to each topic will be given to the students and they will be discussed and
explained.
㸰 Course Outline (Course Topics)
Week
㸯㸸Project Cycle Management (PCM) (1)
㸰㸸Project Cycle Management (PCM) (2)
㸱㸸Project Cycle Management (PCM) (3)
㸲㸸Project Cycle Management (PCM) (4)
㸳㸸Project Cycle Management (PCM) (5)
㸴㸸Flood Fighting Drill
㸵㸸Town Watching (Field survey)
㸶㸸Geographic Information System (GIS) (1)
㸷㸸Geographic Information System (GIS) (2)
㸯㸮㸸Geographic Information System (GIS) (3)
㸯㸯㸸Geographic Information System (GIS) (4)
㸯㸰㸸Geographic Information System (GIS) (5)
㸯㸱㸸Geographic Information System (GIS) (6)
㸯㸲㸸Geographic Information System (GIS) (7)
㸯㸳㸸Geographic Information System (GIS) (8)
㸱 Grading
Reports (100%)
If a report is late for the deadline, it will be not evaluated.
㸲 Textbooks
4-1 Required
4-2 Others
Annex 19
Subject: Urban Flood Management and Flood Hazard Mapping
Course number㸸DMP287E
Instructor㸸Prof. Shigenobu TANAKA
Term / Time㸸Fall through Spring
㸯 Course Description
This course is specifically designed to study urban flood management. In the first half of the
course, students will learn about Japan’s basic legal systems concerning rivers and river
planning and management with special focus on the construction and management of river
levees, which are an important flood defense structure for urban areas. The second half aims to
acquire knowledge required to promote early public evacuation. Students will study topography,
hazard mapping and Disaster Imagination Game, for example. They will also learn about
psychological aspects underlying public behavior during disaster. Toward the end of the course,
students will conduct interviews in flood-vulnerable urban areas to investigate what measures
are in place to promote early public evacuation.
㸰 Course Outline (Course Topics)
Week
㸯㸸River law in Japan
㸰㸸River planning in Japan
㸱㸸Levee structure (1)
㸲㸸Levee structure (2)
㸳㸸River management during normal time 㸴㸸River management during flooding㻌 㻌
㸵㸸Discussion on urban flood management
㸶㸸Outline of flood hazard map and evacuation plan and local disaster management plan
㸷㸸Geomorphology around rivers and alluvial plain (1)㻌
㸯㸮㸸Geomorphology around rivers and alluvial plain (2)
㸯㸯㸸Disaster imagination game (DIG)
㸯㸰㸸Case study of integrated flood management -Tsurumi river-㻌
㸯㸱㸸Developments in social sciences on people’s reactions and responses to disasters
㸯㸲㸸Early evacuation of residents
㸯㸳㸸Examination
㸱 Grading
Reports (40%), Final Exam (60%)
If a report is late for the deadline, it will be not evaluated.
㸲 Textbooks
4-1 Required
"Local Disaster Management and Hazard Mapping" (2009), ICHARM
4-2 Others
Annex 20
Subject: Practices in Hydraulics
Course number㸸DMP288E
Instructor㸸Dr. Atsuhiro YOROZUYA
Term / Time㸸Fall through Spring
1. Course Description:
Analysis of open channel flows and a selective presentation of some of the common river
management problems encountered by practicing engineers with the inclusion of related
computational techniques.
Course Goal:
To enable students to prepare studying in class in Graduate school, and to understand basic
hydraulics with experimental study using computational study as well as flume study. Also
to understand a practical subject about hydraulics with studying about water discharge
measurement in a river.
2. Course Outline (Course Topics)
1. Review of Mathematics
z Ordinary differential equation
z Partial differential equations
2. Fundamentals of Fluid Flow
z Equation of continuity
z Energy equation
z Bernoulli’s equation
3. Flow in closed conduits
z Reynolds number
z Friction factor
4. Computational experiments of open channel flow
5. Flume experiments of open channel flow
6. Practical topics
z Introduction about flow discharge measurement
z Field trip to flow discharge measurement in a river
z Presentation about flow discharge measurement in your countries
3. Grading:
Class participation (10%), Experiment participation (30%), Reports (60%)
4. Text book
Beginning Calculus, Elliott Mendelson Ph.D., Schaum’s outlines
Fluid Mechanics and Hydraulics, R. V. Giles, J. B. Evett, and C. Lin, Schaum’s outlines
Annex 21
Subject : Advanced Hydrology
Course number㸸DMP380E
Instructor㸸Prof. A. W. Jayawardena
Term / Time㸸Fall through Winter
㸯 Course Description
The objective of this course is to provide knowledge and skill in advanced techniques of
hydrological data analysis, modeling and prediction.
㸰 Course Outline (Course Topics)
㸯㸸Hydrological modelling – basic concepts and approaches
㸰㸸Systems theory approach I – Linear theory; Time domain analysis; Frequency
domain analysis
㸱㸸Systems theory approach II – Non-linear systems, multi-linear systems
㸲㸸Instantaneous Unit Hydrograph (IUH)
㸳㸸Conceptual models of IUH
㸴㸸Synthetic Unit Hydrograph
㸵㸸Rainfall-runoff modelling I – Conceptual type
㸶㸸Rainfall-runoff modelling II – Physics-based type
㸷㸸Introduction to Hydroinformatics
㸯㸮㸸Flood routing – Muskingam method; Muskingam-Cunge method
㸯㸯㸸Kalman Filtering
㸯㸰㸸Frequency analysis
㸯㸱㸸Parameter estimation
㸯㸲㸸Errors in frequency analysis
㸯㸳㸸Examination
㸱 Grading
60% by examination; 40% by in-course assessment
㸲 Textbooks
4-1 Required
4-2 Others
Reference books
z Battan, L. J. (1984) : Fundamentals of meteorology, Prentice Hall Inc. Englewood Cliffs,
New Jersey
z Eagleson, P. S: (1970) : Dynamic hydrology, McGraw Hill Book Co.
z Kite, G. W. (1977): Frequency and risk analysis in hydrology, Water resources publication,
Fort Collins, Colorado.
z Lattermann, A. (1991) : System-Theoretical modelling in surface water hydrology,
Springer- Verlag.
z McCuen, R. M. ((1989) Hydrologic analysis and design, Prentice Hall
z Raudkivi, R. J. (1979) : Hydrology - An advanced introduction to hydrological processing
and modelling, Pergamon Press
z Viessman, W. Lewis, G. L. and Knapp, J. W. (1989): Introduction to hydrology, 3rd Edition,
Harper & Row.
z Wanielista, M. (1990) : Hydrology and water quality control, John Wiley
z Course Lecture Notes
Annex 22
Subject: Flood Hydraulics and Sediment Transport
Course number㸸DMP381E
Instructor㸸Prof. Shoji FUKUOKA
Term / Time㸸Fall through Winter
㸯 Course Description
This course provides the basic knowledge necessary for planning and designing the
structural measures for Integrated Flood Risk Management (IFRM). The course first
describes the river administration and planning for application of IFRM. Especially the
methodology of comprehensive river management will be emphasized that includes
planning of flood hydraulics, flood control, and sediment movement to river channels and
dam reservoirs. This will be followed by specific technologies of channel control and
channel improvement.
2. Course Outline (Course Topics)
Week
1. Characteristics and river management of Japanese rivers
2. Prediction method of flow resistance in rivers with compound channels and
application to river course design (1)
3. Prediction method of flow resistance in rivers with compound channels and
application to river course design (2)
4. Steady quasi-two dimensional analysis of flood flows (1)
5. Steady quasi-two dimensional analysis of flood flows (2)
6. Unsteady quasi-two-dimensional analysis of flood flows (1)
7. Unsteady quasi-two-dimensional analysis of flood flows (2)
8. To derive a relationship between stable dimensionless width, depth and discharge
in natural rivers - learning from natural rivers
9. How do we make a river cross-section harmonizing flood control and river
environment
10. 1-D bed deformation, computing model
11. 2-D bed deformation, sand waves and bars, meandering
12. Vegetations, flows in vegetated zone
13. River restoration based on sediment transport and vegetation on stabilized bars
14. Re-meandering project for river restoration
15. Bank erosion and drift woods
㸱 Grading
Reports (20%) Final examination (80%)
㸲 Textbooks
4-1 Required
4-2 Others
Annex 23
Subject: Mechanics of Sediment Transportation and Channel Changes
Course number㸸DMP 382E
Instructor㸸Prof. Shinji EGASHIRA
Term / Time㸸Fall through Winter
㸯 Course Description
Sediment transportation takes place in various forms such as bed-load, suspended load,
debris flow etc. and its spatial imbalance causes river bed degradation and aggradation, side
bank erosion, sand bar formation and channel shifting. Although these channel changes
will be suitable for ecological systems, if they are within an allowable level. However, if
these are over some critical level, flood and sediment disasters will happen. This course
provides methods for evaluating sediment transportation and associated channel changes
with attention focused on basic principles of sediment mechanics. In addition, methods of
sediment management are discussed for disaster mitigation as well as for developing a
suitable channel condition.
㸰 Course Outline (Course Topics)
Week
㸯㸸Introduction (1)
- Characteristics of sediment
㸰㸸Introduction (2)
- Sediment transportation and corresponding channel changes
- Methods to evaluate channel changes
㸱㸸Mechanics of sediment transportation (1)
- Parameters associated with sediment transportation
㸲㸸Mechanics of sediment transportation (2)
- Critical condition for initiating bed load
㸳㸸Mechanics of sediment transportation (3)
- Bed load formulas
㸴㸸Mechanics of sediment transportation (4)
- Bed load formulas
㸵㸸Mechanics of sediment transportation (5)
- Extension of bed load formula to non-uniform sediment
㸶㸸Mechanics of sediment transportation (6)
- Suspended load
㸷㸸Mechanics of debris flow (1)
- Constitutive equations
- Debris flow characteristics over erodible beds
㸯㸮㸸Mechanics of debris flow (2)
- A bed load formula derived from constitutive equations
Annex 24
㸯㸯㸸Bed forms and flow resistance (1)
- Geometric characteristics of bed forms
- Formative domain of bed forms
㸯㸰㸸Bed forms and flow resistance (2)
- Flow resistance
㸯㸱㸸Prediction of channel changes (1)
- Governing equations employed in steep areas
- Topographic change in steep areas
㸯㸲㸸Prediction of channel changes (2)
- Governing equations employed in alluvial reaches
- Topographic change in alluvial reaches
㸯㸳㸸Method to predict sediment transport process in drainage basins
-Sediment management in drainage basin
㸱 Grading
50 points for reports and short quizzes
50 points for the examination at the end of semester
Notice: Either a report or a short quiz is assigned every two weeks, regarding questions
illustrated at the end of each chapter in Lecture Note.
㸲 Textbooks
4-1 Required
z Egashira, S. (2009): Mechanics of Sediment Transportation and River Changes, Lecture
Note
4-2 Others
z
z
Sturm, T. W. (2001): Open Channel hydraulics, McGraw-Hill.
Graf, W. H. (1997): Fluvial Hydraulics, Wiley.
z
Julien Pierre: River Mechanics, Cambridge University Press
(Website: http://www.cambridge.org/us/catalogue/catalogue.asp?isbn=9780521529709)
(http://www.amazon.co.jp/River-Mechanics-Pierre-Y-julien/dp/0521529700)
Albert Gyr and Klaus Hoyer: Sediment Transport, A Geophysical Phenomenon, Springer
Netherlands
(http://www.springerlink.com/content/q0x656/)
Ashida K., Egashira S. and Nakagawa H. (2008), River Morphodynamics for the 21st
Century, Kyoto University Press (in Japanese)
z
z
Annex 25
Subject: Sustainable Reservoir Development & Management
Course number㸸DMP 383E
Instructor㸸Prof. Norihisa MATSUMOTO
Term / Time㸸Fall through Winter
㸯 Course Description
This course provides the basic ideas of dam reservoir design, construction and operation &
maintenance. The lecture starts from the purposes of dam reservoirs and looks into their
environmental and societal impacts. The lecture covers the basic methodologies of project
planning, site selection, design, construction, environmental impact assessment, sediment
management and operation and maintenance of dam reservoirs. The students are expected
to experience a preliminary but concrete process of environmental assessment of reservoirs
and gets insight of the role of reservoirs as one of adaptation measures of climate changes.
㸰 Course Outline (Course Topics)
Week
1: Outline of Dam Engineering
2: Planning and Operation of Flood Control
3: Earthquake Engineering for Dams
4: Environmental Impact of Dams (1)
5: Environmental Impact of Dams (2)
6: Sediment Management in Reservoirs (1)
7: Sediment Management in Reservoirs (2)
8: Dam Construction (1)
9: Dam Construction (2)
10: Dam Management
11: Effective Use of Existing Dams
12: Roles of Dams in the 21st Century
13: Practice on Dam Planning (1) -Presentation14: Practice on Dam Planning (2) -Presentation15: Tour of Dam Laboratory of PWRI
㸱 Grading
Class participation 50%㸪 Reports 30% Presentation 20%
If you miss the deadline for reports, your reports will only be evaluated for a certain
percentage of what they are supposed to be:
Up to seven days: 70%, Eight days or more: 50%
㸲 Textbooks
4-1 Required
Japan Commission on Large Dams, “Dams in Japan ---Past, Present and Future”
A Balkema Book, CRD Press 2009
4-2 Others
Annex 26
Subject: Control Measures for Landslide & Debris Flow
Course number㸸DMP 384E
Instructor㸸Prof. Hiroshi IKEYA
Term / Time㸸Fall through Winter
㸯 Course Description
This course provides the necessary knowledge and understanding of landslide and debris
flow phenomena and their control measures necessary to exercise the IFRM. The lecture
will illustrate the devastating phenomena and the causes of landslides and debris flows and
provide the basic concepts of the measures for sediment-related disasters, so-called Sabo
Works which is executed in the hill slopes and the channels. It will cover the important role
of hazard mapping for sediment-related disasters in both structural and non-structural
measures.
㸰 Course Outline (Course Topics)
Week
㸯㸬Outline of sediment-related disasters and Sabo projects 㸰㸬Sabo planning
㸱㸬Design of Sabo dam
㸲㸬Warning and evacuation system for sediment-related disasters
㸳㸬Hazard mapping for sediment-related disasters
㸴㸬Training of hazard mapping for sediment-related disasters (1)
㸵㸬Training of hazard mapping for sediment-related disasters (2)
㸶㸬Sabo Works in arid area and reforestation of degraded land
㸷㸬Countermeasures for earthquake-induced natural Dams
㸯㸮㸬Introduction of landslides
㸯㸯㸬Survey and emergency response for landslides
㸯㸰㸬Permanent measures for landslide damage reduction
㸯㸱㸬Case study of landslide
㸯㸲㸬Application of Sabo/landslide projects to overseas countries (1)
㸯㸳㸬Application of Sabo/landslide projects to overseas countries (2)
㸱 Grading
Class participation (30%)㻌
Report and final examination (70%)
㸲 Textbooks
4-1 Required
4-2 Others
Annex 27
Subject: Practice on Advanced Hydrology
Course number㸸DMP385E
Instructor㸸Prof. A. W. Jayawardena
Term / Time㸸Fall through Spring
㸯 Course Description
The objective of this course is to train the students in various quantitative methods in
Hydrology including some exercises on hydrological data analysis, modeling and prediction.
㸰 Course Outline (Course Topics)
㸯㸸Exercises on System function estimation
㸰㸸Exercises on least squares estimation
㸱㸸Exercises on Impulse and Frequency Response Functions
㸲㸸Exercises on IUH determination
㸳㸸Exercises on IUH application
㸴㸸Exercises on a typical rainfall-runoff model I
㸵㸸Exercises on a typical rainfall-runoff model II
㸶㸸Exercises on flood routing
㸷㸸Exercises on Kalman filtering I
㸯㸮㸸Exercises on Kalman filtering II
㸯㸯㸸Exercises on Frequency analysis I
㸯㸰㸸Exercises on Frequency analysis II
㸯㸱㸸Exercises on Frequency analysis III
㸯㸲㸸Exercises on parameter estimation
㸯㸳㸸Exercises on error analysis
㸱 Grading
100% in-course assessment
㸲 Textbooks
4-1 Required
4-2 Others
Annex 28
Subject: Practice on Flood Hazard Modeling & Flood Forecasting
Course number㸸DMP386E
Instructor㸸Ass. Prof. Kazuhiko FUKAMI
Term / Time㸸Fall through Spring
㸯 Course Description
The objective of this course is to build capacities for undertaking hydrological predictions
in poorly-gauged basins. The course first introduces the fundamentals of rainfall-runoff
models and flood inundation models. Then it describes finite difference methods to solve
simple differential equations for flood hazard modeling. The basic knowledge with
computer programming exercises will lead for understanding the background of the
“Integrated Flood Analysis System: IFAS,” which is a software developed by ICHARM for
rainfall-runoff analysis. During the second half of the course, the participants will learn
how to apply IFAS for flood predictions using IFAS in poorly-gauged basins with
satellite-based rainfall information.
㸰 Course Outline (Course Topics)
Week
㸯㸸Introduction to Flood Hazard Modeling
㸰㸸Fundamentals of Conceptual Rainfall-Runoff Models
㸱㸸Finite Difference Method for Ordinary Differential Equations
㸲㸸Finite Difference Method for ODE with Fortran Exercise
㸳㸸Fundamentals of Physically based Rainfall-Runoff Models
㸴㸸Finite Difference Method for Partial Differential Equations
㸵㸸Finite Difference Method for PDE with Fortran Exercise
㸶㸸Introduction of GFAS (Global Flood Alert System)
㸷㸸Introduction of IFAS (Integrated Flood Analysis System)
㸯㸮㸸Correction and Validation of Satellite-Based Rainfall
㸯㸯㸸Runoff analysis with IFAS (1) Data import, Model building
㸯㸰㸸Runoff analysis with IFAS (2) Parameter estimation
㸯㸱㸸Runoff analysis with IFAS (3) Validation of calculated discharge
㸯㸲㸸Runoff analysis with IFAS (4) Application to actual basins
㸯㸳㸸Runoff analysis with IFAS (5) Application to actual basins
㸱 Grading
Reports (100%)
㸲 Textbooks
4-1 Required
4-2 Others
Material made by the instructors
Annex 29
Subject:
Site Visit of Water-related Disaster Management Practice in Japan
Course number㸸DMP390E
Instructor㸸Prof. Shigenobu TANAKA
Term / Time㸸Fall through Summer
㸯 Course Description
This course provides opportunities for students to actually visit and study flood control
structures in Japan, which are introduced in other courses. The structures include river levees,
flood retarding basins, dams, and sabo structures. After each study visit, students will be
required to submit a report comparing the target structures in Japan and those in their
countries.
㸰 Course Outline (Course Topics)
㸦Kanto Area : November - December㸧 㸯㸸River in Japan -Diversion Channel, Levee ,River administration - (Ara River)
㸰㸸Flood information (MLIT Regional bureau, Kita City or Kuki City㸧
㸱㸸Retarding Basin (Watarase Retarding Basin)
㸲㸸Metropolitan Area Outer Underground Discharge Channel
㸳㸸Integrated flood management (Tsurumi River)
㸴㸸Collaborative administration of Ikari Dam & Kawaji Dam
㸵㸸Sabo work in Nikko
㸦Chugoku & Kinki Area : March㸧
㸶㸸River Basin Planning (1) (Hii River)
㸷㸸River Basin Planning (2) (Ota River)
㸯㸮㸸River use in Osaka City (Doutonbori)
㸯㸯㸸Sabo work in Kamenose
㸦Tohoku Area : May㸧
㸯㸰㸸Designated disaster hazard area along Kitakami River (Fujisawa Town, Iwate Pref.)
㸯㸱㸸Secondary levee (Kashimadai District, Miyagi Pref.)
㸦Hokuriku Area : August㸧
㸯㸲㸸Discontinuous levee, Silt flashing from dams (Kurobe River)
㸯㸳㸸Japanese philosophy on river improvement (Shinano River)
㸱 Grading
Attendance (60%), Report (40%)
If a report is late for the deadline, it will be not evaluated.
㸲 Textbooks
4-1 Required
4-2 Others
Annex 30
Site Visit (1) Urban River in Japan (Arakawa River)
[River management during normal time]
‫ە‬Date:
October 27th (Thu)
‫ە‬Lecturer:
Mr. Ohta, Chief of Local Cooperation Section,
Arakawa-Karyu (Arakawa River Downstream) Office,
Ministry of Land, Infrastructure, Transport and Tourism (MLIT)
‫ە‬Time table (tentative)
10:10 Boarding place
Ņship [Arakawa Lock Gate]
11:20
River Station in Shinden Area
11:25-11:45
Super Levee in Shinden Area
11:50 Boarding place
Ņship
12:10 River Station in Iwabuchi Area
Ņwalk
12:20-13:20
Lunch at Arakawa River Museum “amoa”
13:20-13:50
Tour of amoa &
Disaster management room in MLIT local office
Ņwalk
[Usual use of river side]
14:30-15:00 Disaster Prevention Station in Ukima Area
[End of the trip]
Annex 31
Annex 32
UkimaArea
㻸㼛㼏㼍㼠㼕㼛㼚㻌㻹㼍㼜㻌㼕㼚㻌㻭㼞㼍㻌㻾㼕㼢㼑㼞
MinstryofLand, Infrastructure,
TransportandTourism(MLIT)
Chuo University
ArakawaLockGate
Shinden Area
ArakawaRiverDownstreamOffice,
ArakawaMuseum"amoa"
BoardingPlace
Site Visit (2) Flood Information (MLIT Kanto) &
Water Discharge Tunnel
‫ە‬Date:
October 28th (Fri)
‫ە‬Lecturer:
Officer in charge
River Management Division,Kanto Regional Development Bureau,
Ministry of Land, Infrastructure, Transport and Tourism (MLIT)
Officer in charge
Edogawa River Work Office,
Ministry of Land, Infrastructure, Transport and Tourism (MLIT)
‫ە‬Time table (tentative)
9:00-10:30
Lecture by Prof. Fukuoka at Chou Univ.
10:30-12:00
Move to Saitama City by train
12:00-13:00
Lunch
13:00-14:30
Site visit at Flood Forecasting Center,
Kanto Regional Development Bureau, MLIT
14:30-15:30
Move by bus
15:30-17:00
Site visit at Water Discharge Tunnel
17:00-18:00
Move to TBIC
Annex 33
Site Visit (3)
Kuki City Town & Watarase Retarding Basin
10th November (Thu)
‫ ە‬Date㸸
‫ ە‬Schedule㸸
㸵㸸㸰㸮 Departure from TBIC
Ļ Bus
(㸵㸸㸳㸮 Departure from ICHARM)
Ļ Bus
㸷㸸㸱㸮㸫㸯㸮㸸㸱㸮 Lecture on “Flood Information (2)”
㹙Tonegawa-Joryu (Tone River Upstream River) Work Office, MLIT㹛
Ļ Bus
㸯㸮㸸㸲㸮㸫㸯㸰㸸㸯㸮 Tour in Kuki City
¾
Breach point by Typhoon Kathleen in 1947
¾
“Marugoto Machigoto Hazard Map” (Past Flood Marks)
¾
Display Tower of Water Level of Tone River
¾
Display on Flood Information at Kurihashi Station
㸯㸰㸸㸱㸮㸫㸯㸱㸸㸰㸮 Lunch & Break
㹙Road Station “Kita-kawabe”㹛
Ļ Bus
㸯㸱㸸㸱㸮㸫㸯㸱㸸㸳㸮 Lecture on Watarase Retarding Basin
㹙Branch office of Tonegawa-Joryu (Tone River Upstream River) Work Office㹛
Ļ Bus
㸯㸲㸸㸮㸮㸫㸯㸳㸸㸮㸮 Watarase Retarding Basin
Ļ Bus
(㸯㸴㸸㸲㸳 Arrival at ICHARM)
Ļ Bus
㸯㸵㸸㸯㸳 Arrival at TBIC
Annex 34
Ibaraki Pref.
Saitama Pref.
Pacific Ocean
Tone River
Tokyo
Watarase Retarding Basin
ICHARM
Bus Route
Kuki City
Annex 35
Site Visit (4)
River improvement in Tokyo Metropolitan
Date: 22nd November, 2011
Schedule:
8:10
Tsukuba Center
ЎBus
8:40
JICA Tsukuba
ЎBus
10:00-11:30 Lecture on “River improvement by Tokyo Metropolitan Government”
11:30-12:00
12:00-13:00
Site visit of Bikunibashi downstream flood control reservoir
Lunch & Break 13:00-14:10
Site visit of Bikunibashi upstream flood control reservoir
14:15-14:45
Site visit of river improvement of Shirako River
ЎBus
15:25-16:00
Site visit of river improvement of Shakujii River
ЎBus
17:15
JICA Tsukuba
ЎBus
17:45
Tsukuba Center
Annex 36
Annex 37
䐟 ShirakoRiver
䐠
䐟
BikunibashiupstreamfloodͲ
controlreservoir
Bikunibashishaft
SirakoRiver
BikunibashidownstreamfloodͲ
controlreservoir
ShakujiiRiver
䐠 ShakujiiRiver
SumidaRiver
Site Visit (5) Integrated River Basin Management on
Urban Rivers –Case study in Tsurumi River-
[9th December (Fri)]
7:00
Tsukuba Center
7:25
JICA Tsukuba
move by bus
9:30
ձTsurumi River Basin Information Center
(Kozukue, Kouhoku-ku, Yokohama-city㸧
9:30-10:30
Lecture on Integrated River Basin Management by Mr. Imbe
10:30-11:30
Guidance on Integrated River Basin Management in Tsurumi River
(including a view from the rooftop)
11:30-12:30
Walk and look around the Tsurumi retarding basin
12:30-13:20
Lunch at Shin-yokohama Park
move by bus
14:00-14:20
ղKirigaoka Regulating Pond
㸦Kirigaoka, Midori-ku, Yokohama-city㸧
move by bus
14:40-15:10
ճ Onmawasi Park Underground Tunnel-type Reservoir
㸦Miwa-machi, Machida-city, Tokyo㸧
move by bus
16:00-16:30
մRainwater storage and infiltration system in individual house
㸦Prof. Takahashi’s house : Todoroki, Setagaya-ku, Tokyo㸧
move by bus
18:30
JICA Tsukuba
19:00
Tsukuba Center
Annex 38
Annex 39
䐡
YokohamaCity
䐠
9:30Ͳ10:30 䐟 LectureonIntegratedRiverBasinManagement
䠄㭯ぢᕝὶᇦ䝉䞁䝍䞊䠅
10:30Ͳ11:30
GuidanceonIntegratedRiverBasinManagementinTsurumiRiver
11:30Ͳ12:30
WalkandlookaroundtheTsurumiretardingbasin
љ movebybus
14:00Ͳ14:20 䐠 KirigaokaRegulatingPond
䠄⥳䝔䝙䝇䜺䞊䝕䞁䠄㟝䛜ୣ㐟Ỉᆅ䠅䠅
љ movebybus
14:40Ͳ15:10 䐡 OnmawashiParkUnderground TunnelͲtypeReservoir
䠄ᜠᘔබᅬᆅୗㄪᩚụ䠅
љ movebybus
16:00Ͳ16:30 䐢 Rainwaterstorageandinfiltrationsystemat individualhouse
䠄㧗ᶫ⿱ඛ⏕Ꮿ䛷䛾㈓␃ᾐ㏱᪋タ䠅
䐟
TsurumiRiver
䐢
Kawasaki City
Tokyo
Site Visit (7)
Chugoku & Kinki Region
࠙13 March (Tue)ࠚ
TBIC Ѝ(Bus)Ѝ Hitachi-no-ushiku Sta.
15:09 Hitachi-no-ushiku Sta. Ѝ(JR)Ѝ 15:53 Nippori Sta. Ѝ(JR)Ѝ 16:20 Shinagawa Sta.
Ѝ(Keikyu Railway)Ѝ 16:51 Haneda Airport
18:30 Haneda Airport
Ņ JAL1671
20:00 Izumo Airport
20:10 Izumo Airport
ЎLocal Bus
20:40 Hotel in Matsue City [Accommodation: Matsue Tokyu Inn]
Matsue Castle
http://www.tokyuhotelsjapan.com/en/TI/TI_MATUE/index.html
㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫
࠙14 March(Wed)ࠚ
8:30 Departure from Hotel
Ņ Bus (30min.)
9:00- 9:45 㸯㸬Ohashi Riv. Community Center (Matsue City, Shimane Pref.)
኱ᶫᕝࢥ࣑ࣗࢽࢸ࢕ࢭࣥࢱ࣮㸦ᯇỤᕷẊ⏫ 383 ␒ᆅᒣ㝜୰ኸࣅࣝ 1 㝵 㸧
Ņ Bus (60min.)
10:45-12:00 㸰㸬Construction site of Hii Riv. Diversion Channel (Izumo City, Shimane Pref.)
ᩫఀᕝᨺỈ㊰ᘓタ⌧ሙ
㸦ᩫఀᕝᨺỈ㊰ࡩࢀ࠶࠸ࢭࣥࢱ࣮㸦ฟ㞼ᕷୖሷ෬⏫ 942-1㸧㸧
Ņ Lunch in the conference room & Bus (60min.)
14:00-15:00 㸱㸬Obara Dam(Unnan City, Shimane Pref.)
ᑿཎࢲ࣒㸦ᓥ᰿┴㞼༡ᕷᮌḟ⏫ᖹ⏣ 36㸧
Ņ Bus (4 hours including break)
19:00 Hotel in Higashi-hiroshima City
[Accommodation: JICA Chugoku]
㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫
࠙15 March(Thu)ࠚ
8:30
Departure from JICA Chugoku
Ņ Bus (1 hours)
9:30-
㸲㸬Ota Riv. (Takase Weir, Gion Water Gate, Motoyasu Riv. Water Terrace)
㸦Hiroshima City, Hiroshima Pref.㸧
9:30-10:00 Outline of Ota River ኴ⏣ᕝᴫせㄝ᫂
Annex 40
Visit of Takase Weir 㧗℩ሖどᐹ
Ņ Move (20 min.) ⛣ື㸦20 ศ㸧
10:20-11:00 Visit of Sabo countermeasure in west side of Hiroshima City
㸦◁㜵᪋タどᐹ㸦┦⏣ 1 ྕሖሐ㸧㸧
Ņ Move (20 min.) ⛣ື㸦20 ศ㸧
11:20-11:50 Visit of Gion Water Gate
♲ᅬỈ㛛ㄝ࣭᫂どᐹ㸦኱Ⱚฟᙇᡤෆ㸦ᗈᓥᕷす༊኱Ⱚ 3-1-1㸧㸧
Ņ Move (15 min.) ⛣ື㸦15 ศ㸧
12:05-12:30
Motoyasu Riv. Water Terrace ඖᏳᕝぶỈࢸࣛࢫ
12:30-14:00 Lunch
Ņ Bus (10 min.)
14:44 Hiroshima Sta.
Ў Shinkansen (NOZOMI 128) ᪂ᖿ⥺㸦ࡢࡒࡳ 128 ྕ㸧
16:01 Shin-Kobe Sta.
Ў JR, etc.
17:00
Hotel in Kobe City
A-Bomb Dome
[Accommodation: JICA Hyogo]
http://www.jica.go.jp/english/contact/domestic/pdf/hyogo_facilities.pdf
㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫
࠙16 March(Fri)ࠚ
9:00 Departure from Hotel
Ņ bus
9:30-11:00 㸳㸬Disaster Reduction and Human Renovation Institution (Kobe City, Hyogo Pref.)
㜰⚄࣭ῐ㊰኱㟈⅏グᛕ ே࡜㜵⅏ᮍ᮶ࢭࣥࢱ࣮㸦⚄ᡞᕷ㸧
Ņ Lunch & Bus (90min.)
12:30-14:00 㸴㸬Kamenose Landslide㸦Kashiwara City, Osaka Pref㸧
டࡢ℩ᆅࡍ࡭ࡾ㸦኱㜰ᗓ᯽ཎᕷ኱Ꮠᓘ㸧
Ņ Bus (50min.)
15:00 Shin-Osaka Sta.
15:27 Shin-Osaka Sta.
Ņ Shinkansen (NOZOMI 238) ᪂ᖿ⥺㸦ࡢࡒࡳ 238 ྕ㸧
18:03 Tokyo Sta.
18:15 Tokyo Sta.
Ņ JR
18:38 Ueno Sta.-> (JR Joban Line) -> 19:39 Hitachi-no-ushiku Sta.
㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫㸫
Annex 41
Map of Field Trip in Chugoku & Kinki Region
13th - 16th March, 2012
1. Ohashi Riv.
Community Center
Hi-i River
Matsue
City
Izumo Airport
Izumo
City
Shinji Lake
Tsukuba
3. Obara Dam
Kando River
2. Hii Riv.
Diversion Channel
Matsue
Tokyo
Izumo
Kyoto
Kobe
Osaka
Hiroshima
Kyoto
City
Ota River
Yodo River
Kobe
City
Shin-Osaka
4. Takase Wier, Sabo countermeasure
Gion Water Gate,
Motoyasu Riv. Water Terrace
Hiroshima
City
5. Disaster Reduction and㻌
Human Renovation Institution
Osaka
City
Yamato River
Annex 42
Nara
City
6. Kamenose Landslide
Site Visit (8)
Lecture at Japan Meteorological Agency (JMA)
& "The 61st Tonegawa River System Joint Flood Fighting Drill"
࠙Venueࠚ
HQs of Japan Meteorological Agency (JMA) (Otemachi, Tokyo)
Kurihashi Area, Kuki City, Saitama Pref
࠙Scheduleࠚ
18th May (Fri)
8:00 TBIC -> (JICA Bus) -> 8:10 Hitachi-no-ushiku Sta 8:27 Hitachi-no-ushiku Sta. -> (JR
Joban Line) -> 9:16 Kitasenju Sta. -> (Transfer to Tokyo Metro Chiyoda Line)-> 9:29
Kitasenju Sta. -> 9:45 Otemachi Sta -> walk (5 minutes)
10:00
Arrival at JMA
10:30-12:00
Lecture at JMA
12:00-14:30
Lunch & Break (Mr. Kamoto will accompany.)
14:49 Otemachi Sta -> (Tokyo Metro Hanzomon Line) -> 15:57 Kuki Sta. ->
(transfer) -> 15:59 Kuki City -> (Tobu Line) -> 16:09 Kazo Sta. -> walk (7 minutes)
16:15
Arrival at the hotel in Kazo City (Kazo Daiichi hotel)
19th May (Sat)
7:30
Departure from the hotel by bus
8:00
Arrival at the venue of flood fighting drill (Kuki City) 8:50
Opening event
9:30
Opening Ceremony
10:00- Start of the drills (Session Part I: Flood Fighting Drill)
11:35
Closing of the Session Part I
11:35-12:15
Seeing of displays
Exercise on Flood Fighting activities" will be held from 10:00-12:20.
We can experience of making sandbags, etc.
12:15-14:00
move by bus
14:00
Arrival at TBIC via Tsukuba Center
Annex 43
Site Visit (9) Sabo & Dam Project in Kanto Region
࠙21st May (Mon)ࠚ
6:30
Departure from Tsukuba Center
Ļ
7:00
Departure from TBIC
Ļ
10:00-12:00
Dam Collaboration between Kawaji Dam & Ikari Dam
㸦⾜ඛ㸸ᕝ἞ࢲ࣒⟶⌮ᡤ㸦ᰣᮌ┴᪥ගᕷᕝ἞ Ἠᕝ἞ 319-6㸧
㸧
Ļ
Lunch
Ļ
14:00-16:00
Sabo Works in Ashio
㸦⾜ඛ㸸㖡ぶỈබᅬ㸦ᰣᮌ┴᪥ගᕷ㊊ᑿ⏫ཎࣞ 885㸧
㸧
Ļ
19:00
Stay in Kazo City (Kazo Daiichi Hotel)
࠙22nd May (Tue)ࠚ
8:30
Departure from hotel
Ļ
9:00-10:15
Tone Weir ฼᰿኱ሖ
㸦⾜ඛ㸸㸦⊂㸧Ỉ㈨※ᶵᵓ ฼᰿ᑟỈ⥲ྜ஦ົᡤ
㸦ᇸ⋢┴⾜⏣ᕷ኱Ꮠ㡲ຍᏐ⯪ᕝ 4369㸧㸧
Ļ
Lunch
Ļ
13:00-15:00
Exercise on ADCP at Taisho Bridge of Tone River by Dr. Yorozuya
㸦⾜ඛ㸸⩌㤿┴῰ᕝᕷ኱ṇᶫ௜㏆㸧
Ļ
17:30 Arrival at TBIC
Ļ
18:00 Arrival at Tsukuba Center
Annex 44
㻹㼍㼜㻌㼛㼒㻌㻿㼕㼠㼑㻌㼂㼕㼟㼕㼠㻌㻔㻤㻕㻌㻒㻌㻔㻥㻕
IkariDam&KawajiDam
NikkoCity
AshioSaboWorks
UtsunomiyaCity
FloodFightingDrill
ICHARM
Annex 45
Site Visit (10) Shingu City, Ise City
5th Sep (Wed)
15:09 Hitachi-no-ushiku Sta.->(JR Line)-> 15:53 Nippori Sta. 16:00-> (JR Line) ->
16:11 Tokyo Sta. (Ph.D. students and Prof. Jaya join at the Shinkansen Platform)
16:40 ->㸦Shinkansen NOZOMI 241㸧->18:24 Nagoya Sta.->㸦Subway, etc.㸧->Hotel
6th Sep. (Thu)
Hotel
Ļ㸦Subway, etc.㸧
9:30- JSCE General Meeting at Nagoya University
Registration
10:25-11:55 Presentation by ICHARM students
12:00-13:00 Lunch
13:00 Departure from Nagoya Univ.
Ļ㸦Bus: 4 hours including break)
17:00 Shingu City
7th Sep. (Fri)
8:30 Hotel
9:00-12:00
Explanation of flood damage last year by Shingu City officer
(Mr. Kuribayashi and some students will return from Shingu Sta. to Tsukuba)
12:00-13:00 Lunch
13:00-15:00 Explanation of flood damage last year by MLIT officer
15:00 Departure from Shingu City
Ļ㸦Bus: 3 hours including break)
18:00 Ise City
8th Sep. (Sat)
9:30-10:30 Community based disaster management activities in Ohminato district
Ļ㸦Bus:30 minutes)
11:14 Ujiyamada Sta.
Ļ㸦Kintetsu Railway)
12:37 Nagoya Sta. 13:10 -> (Shinkansen NOZOMI 122㸧-> 14:53 Tokyo Sta. ->(JR Line)->
Nippori Sta. 15:36->(JR Line) 16:39 Hitachi-no-ushiku Sta.->(Bus)->
Annex 46
TBIC
Tsukuba
Tokyo
Nagoya
PacificOcean
Nagoya
Kyoto
Kobe
Osaka
Ise
MiePrefecture
KiiPeninsula
Shingu
Annex 47
Major feedback from M.Sc. students (Questionnaire Result)
Category
A. Course
Contents
No.
Feedback ◊ಟ⏕࠿ࡽࡢពぢ
1
4
Some design part like levees, head works, spill ways, dam is necessary regarding Master’s course
Dam & reservoir & Landslide debris flow are very poor quality for master degree course. So many
lecturer and overlap lecture. Grading system is not ok.
Some of the subjects which have little relevance with the course (Earthquakes we studied at
GRIPS)
More emphasis should be given to the flood forecasting and flood management in small and large
rivers, steep slope and gentle slope rivers.
Joining international meeting (or seminar) may be a good choice.
5
Some students duplicated other’s students report (examination). Please be strict to them.
6
More time should be given to technical software.
The theory subjects should be reduced and practical training (IFAS, GIS, RRI, & Fortran) be given
more time.
The number of course and the time should be increased.
Course work was so extensive.
The course is packed a little.
The duration of the course is quite short.
2
3
7
B. Course
Schedule
8
9
10
11
12
C. Lecturer
13
14
15
16
D. Master’s
Thesis
(Schedule)
17
Software tools used for research work should be taught as a subject from start of course.
In the first month (October), some basic courses should be conducted for beginners.
Modeling lectures should be at the end of first semester.
There is no coordination between exam date/time and next lecture.
Please avoid the concentration of many examinations.
There should make a balance between the theory course and individual study.
Teacher should provide more example, guidance & answers to help student be easy to understand
clearly.
Some of lecture materials do not include the sample questions that were asked in examination
Most of the lecturers were very weak in English conversation.
Teaching procedure is not academic standard. Japanese river law and subjects are also not
academic standards.
Same subject areas done by different lecturers.
Some contents of lectures were duplicated.
Research work should be started as one subject from the start of the course.
The thesis proceedings should be started with the start of course.
If thesis work starts in parallel to course work, we can save time.
Annex 48
Question date
ᅇ⟅᫬ᮇ
June
June
Actions to be taken by ICHARM ពぢ࡟ᑐࡍࡿᑐᛂ㸦᱌㸧
We will deliver the feedback to Prof. Matsumoto to take some actions.
June
We will deliver the feedback to Prof. Okazaki to take some actions.
June
We will rearrange the contents.
June
September
September
We have to investigate the international meeting (or seminar) to which students
can attend.
As for examinations held in ICHARM, we can take some measures (e.g. 1 student
for 1 desk). But as for the reports, we have to ask lecturers to look into their
reports more closely.
We will arrange the schedule to focus on practical courses.
June
September
September
June
June
June
September
June
September
September
June
June
September
June
June
We have to make balance on appreciate volume of this course.
The whole duration (1 year) cannot be changed. We deleted “Practice on Advanced
Hydrology” to increase thesis work time.
In the early stage (October) we put priorities on courses by Prof. Takeuchi and
Prof. Fukuoka. After those, we start software classes.
We don’t think so.
In the next course, we arranged the course schedule to make intervals of at least
2 week between the last lecture and examination. And avoid concentration as
much as possible.
(We should discuss continuously.)
We will ask lecturers to do so.
June
June
June
June
September
June
September
June
September
June
We have to try to investigate whole contents to remove meaningless duplication.
Research work is one subject as Individual study.
We have to arrange their thesis matching activities earlier.
We deleted “Practice on Advanced Hydrology” to increase thesis work time.
More time should be spare for individual study during course work as well.
18
19
More time would be helpful for better thesis.
Students employing numerical model need more time.
Before coming to Japan, please instruct us to bring what kind of data should be brought with us.
June
September
September
September
September
We have to prepare higher spec PCs.
In the General Information which is distributed to each participant before coming to
Japan , the instruction is written as follows; The participants are strongly recommended
to bring the relevant data for water-related disasters in your country on your
laptop/notebook computers for preparing the action plan, presentation slides etc.
But in detail, supervisor have to tell students what kind of date they need.
E. Master’s
Thesis
(Theme)
28
Options were limited in selecting topic.
Some participants have experience to have written Master’s thesis, but some don’t. I’d like
ICHARM to have instructed how to write thesis for them.
Some participants feel realized that they chose wrong thesis title or supervisor. Please be mindful
a little more while allocating thesis topics and supervisors.
Please ask some private company to accept some students to make M.Sc. thesis from the next year.
I’d like ICHARM to suggest thesis topic, subject, and software because some of them are written by
Japanese.
Sometimes supervisors have no time to guidance.
There is limited guidance for the students who are doing research in social topics.
Sometime the methods/advises given to students are not clear or often miss-guided.
The supervisors should be grouped and they can provide more support from different aspects.
29
The evaluation system of individual study is not good/fare. It’s better to give chance to everybody
September
September
June
September
September
30
to increase their grades. Some supervisors give the chance, but the others didn’t.
Please tell us not what we should study, but how we study.
The time for final presentation was very short.
September
September
20
21
22
23
24
F. Master’s
Thesis
(Supervisor)
25
26
27
June
September
September
September
September
G. Master’s
Thesis
(Others)
31
H. Field
trips
33
34
I wish more good laptops
We should have more field trips if possible.
The materials of field trips if provided in soft copy from will be helpful in future.
September
June
June
I. Others
35
There should be more exchange between ICHARM staff & students.
June
36
We wanted some opportunities to discuss with other university students.
Japanese language class should be added.
September
September
32
37
Annex 49
(We should discuss continuously.)
Supervisors have to have time to consult with students.
ICHARM has to increase various kinds of researchers.
This year some supervisors were assigned to one student, which is the cause of
confusion by student. From next year, we have to consider the supervisor system.
(We should discuss continuously.)
The presentation time was 20 minutes for each student. In the next year, we can
increase presentation time because the number of students reduced.
We have 4 high spec PC. As for rental laptop PC. It’s difficult to procure them.
We think the total number of field trips is enough.
From the next year, we will give students soft copy after permission from
lecturers
We have to have some occasions of Japanese cultural events besides weekday
lectures to become familiar with students.
We have to seek or arrange some occasions (with Tsukuba Univ.(?))
The Japanese language classes have been conducted by JICA. But JICA has been
reducing such classes. Do we have to add some language classes in self-study time
(e.g. once in a week)?
(We should discuss continuously.)