This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
Afshari S., Tavakoly A.A., Rajib M.A., Zheng X., Follum M.L., Omranian E., Fekete B.M., 2018. Comparison of new generation low-complexity flood inundation mapping tools with a hydrodynamic model. Journal of Hydrology 556: 539–556. Doi: 10.1016/j.jhydrol.2017.11.036.AfshariS.TavakolyA.A.RajibM.A.ZhengX.FollumM.L.OmranianE.FeketeB.M.2018Comparison of new generation low-complexity flood inundation mapping tools with a hydrodynamic modelJournal of Hydrology55653955610.1016/j.jhydrol.2017.11.036Open DOISearch in Google Scholar
Alexakis D.D., Grillakis M.G., Koutroulis A.G., Agapiou A., Themistocleous K., Tsanis I.K., Michaelides S., Pashiardis S., Demetriou C., Aristeidou K., Retalis A., Tymvios F., Hadjimitsis D.G., 2014. GIS and remote sensing techniques for assessment of land use change impact on hydrology: The case study of Yialis Basin in Cyprus. Natural Hazards and Earth System Science 14: 413–426.AlexakisD.D.GrillakisM.G.KoutroulisA.G.AgapiouA.ThemistocleousK.TsanisI.K.MichaelidesS.PashiardisS.DemetriouC.AristeidouK.RetalisA.TymviosF.HadjimitsisD.G.2014GIS and remote sensing techniques for assessment of land use change impact on hydrology: The case study of Yialis Basin in CyprusNatural Hazards and Earth System Science1441342610.5194/nhess-14-413-2014Search in Google Scholar
Apip, Takara K., Yamashiki Y., Ibrahim A.B., 2010. Assessment of spatially-distributed sediment budget and potential shallow landslide area for investment prioritization in sediment control of engaged catchment: A case study on the upper Citarum river, Indonesia. Annuals of Disaster Prevention Research Institute, Kyoto University 53B: 45–59.ApipTakaraK.YamashikiY.IbrahimA.B.2010Assessment of spatially-distributed sediment budget and potential shallow landslide area for investment prioritization in sediment control of engaged catchment: A case study on the upper Citarum river, IndonesiaAnnuals of Disaster Prevention Research Institute, Kyoto University53B4559Search in Google Scholar
Armenteras D., Murcia U., González T.M., Barón O.J., Arias J.E., 2019. Scenarios of land use and land cover change for NW Amazonia: Impact on forest intactness. Global Ecology and Conservation 17: e00567. Doi: 10.1016/j.gecco.2019.e00567.ArmenterasD.MurciaU.GonzálezT.M.BarónO.J.AriasJ.E.2019Scenarios of land use and land cover change for NW Amazonia: Impact on forest intactnessGlobal Ecology and Conservation17e0056710.1016/j.gecco.2019.e00567Open DOISearch in Google Scholar
Bajabaa S., Masoud M., Al-Amri N., 2013. Flash Flood Hazard Mapping Based on Quantitative Hydrology, Geomorphology and GIS Techniques (Case Study of Wadi Al Lith, Saudi Arabia). Arab Journal of Geosciences 7: 2469–2481. Doi: 10.1007/s12517-013-0941-2.BajabaaS.MasoudM.Al-AmriN.2013Flash Flood Hazard Mapping Based on Quantitative Hydrology, Geomorphology and GIS Techniques (Case Study of Wadi Al Lith, Saudi Arabia)Arab Journal of Geosciences72469248110.1007/s12517-013-0941-2Open DOISearch in Google Scholar
Bass B., Bedient P., 2018. Surrogate modeling of joint flood risk across coastal watersheds. Journal of Hydrology 558: 159–173. Doi: 10.1016/j.jhydrol.2018.01.014.BassB.BedientP.2018Surrogate modeling of joint flood risk across coastal watershedsJournal of Hydrology55815917310.1016/j.jhydrol.2018.01.014Open DOISearch in Google Scholar
Beretta R., Ravazzani G., Maiorano C., Mancini M., 2018. Simulating the influence of buildings on flood inundation in urban areas. Geosciences 8(2): 77. Doi: 10.3390/geosciences8020077.BerettaR.RavazzaniG.MaioranoC.ManciniM.2018Simulating the influence of buildings on flood inundation in urban areasGeosciences827710.3390/geosciences8020077Open DOISearch in Google Scholar
Birhanu A., Masih I., van der Zaag P., Nyssen J., Cai X., 2019. Impacts of land use and land cover changes on hydrology of the Gumara catchment, Ethiopia. Physics and Chemistry of the Earth, Parts A/B/C. Doi: 10.1016/j.pce.2019.01.006.BirhanuA.MasihI.van der ZaagP.NyssenJ.CaiX.2019Impacts of land use and land cover changes on hydrology of the Gumara catchment, EthiopiaPhysics and Chemistry of the EarthParts A/B/C.10.1016/j.pce.2019.01.006Open DOISearch in Google Scholar
Bosch J.M., Hewlett J.D., 1982. A review of catchment experiments to determine the effect of vegetation changes on water yield and evapotranspiration. Journal of Hydrology 55: 3–23.BoschJ.M.HewlettJ.D.1982A review of catchment experiments to determine the effect of vegetation changes on water yield and evapotranspirationJournal of Hydrology5532310.1016/0022-1694(82)90117-2Search in Google Scholar
Botai C.M., Botai J.O., De Wit J.P., Ncongwane K.P., Adeola A.M., 2017. Drought Characteristics over the Western Cape Province, South Africa. Water 9: 876.BotaiC.M.BotaiJ.O.De WitJ.P.NcongwaneK.P.AdeolaA.M.2017Drought Characteristics over the Western Cape Province, South AfricaWater987610.3390/w9110876Search in Google Scholar
Burrough P.A., van Gaans P.F.M., MacMillan R.A., 2000. High-resolution landform classification using fuzzy k-means. Fuzzy Sets and Systems 113: 37–52.BurroughP.A.van GaansP.F.M.MacMillanR.A.2000High-resolution landform classification using fuzzy k-meansFuzzy Sets and Systems113375210.1016/S0165-0114(99)00011-1Search in Google Scholar
Chakravarty P., Manoj Kumar M., 2019. Chapter 6 – Floral Species in Pollution Remediation and Augmentation of Micrometeorological Conditions and Microclimate: An Integrated Approach, Phytomanagement of Polluted Sites, Elsevier: 203–219. Doi: 10.1016/B978-0-12-813912-7.00006-5.ChakravartyP.Manoj KumarM.2019Chapter 6 – Floral Species in Pollution Remediation and Augmentation of Micrometeorological Conditions and Microclimate: An Integrated ApproachPhytomanagement of Polluted SitesElsevier20321910.1016/B978-0-12-813912-7.00006-5Open DOISearch in Google Scholar
Coates D.R. 1958. Quantitative geomorphology of small drainage basins in Southern Indiana. 1st Edn. New York: Columbia UniversityCoatesD.R.1958Quantitative geomorphology of small drainage basins in Southern Indiana1st EdnNew YorkColumbia UniversitySearch in Google Scholar
Collier Ch.G., 2016. Hydrometeorology. Wiley Blackwell.CollierCh.G.2016HydrometeorologyWiley Blackwell10.1002/9781118414965Search in Google Scholar
Dang A.T.N., Kumar L., 2017. Application of remote sensing and GIS-based hydrological modelling for flood risk analysis: A case study of District 8, Ho Chi Minh city, Vietnam. Geomatics, Natural Hazards and Risk 8(2): 1792–1811. Doi: 10.1080/19475705.2017.1388853.DangA.T.N.KumarL.2017Application of remote sensing and GIS-based hydrological modelling for flood risk analysis: A case study of District 8, Ho Chi Minh city, VietnamGeomatics, Natural Hazards and Risk821792181110.1080/19475705.2017.1388853Open DOISearch in Google Scholar
Dasanto B.D., Boer R., Pramudya B., Suharnoto Y., 2014. Simple method for assessing spread of flood prone areas under historical and future rainfall in the upper Citarum watershed. Environment Asia 7(2): 79–86.DasantoB.D.BoerR.PramudyaB.SuharnotoY.2014Simple method for assessing spread of flood prone areas under historical and future rainfall in the upper Citarum watershedEnvironment Asia727986Search in Google Scholar
Dewan A.M., Yamaguchi Y., 2009a. Land use and land cover change in Greater Dhaka, Bangladesh: Using remote sensing to promote sustainable urbanization. Applied Geography 29(3): 390–401. Doi: 10.1016/j.apgeog.2008.12.005.DewanA.M.YamaguchiY.2009aLand use and land cover change in Greater Dhaka, Bangladesh: Using remote sensing to promote sustainable urbanizationApplied Geography29339040110.1016/j.apgeog.2008.12.005Open DOISearch in Google Scholar
Dewan A.M., Yamaguchi Y., 2009b. Using remote sensing and GIS to detect and monitor land use and land cover change in Dhaka Metropolitan of Bangladesh during 1960–2005. Environmental Monitoring and Assessment 150(1–4): 237–249. Doi: 10.1007/s10661-008-0226-5.DewanA.M.YamaguchiY.2009bUsing remote sensing and GIS to detect and monitor land use and land cover change in Dhaka Metropolitan of Bangladesh during 1960–2005Environmental Monitoring and Assessment1501–423724910.1007/s10661-008-0226-518317939Open DOISearch in Google Scholar
Diakakis M., 2010. A method for flood hazard mapping based on basin morphometry: Application in two catchments in Greece. Natural Hazards 56(3): 803–814. Doi: 10.1007/s11069-010-9592-8.DiakakisM.2010A method for flood hazard mapping based on basin morphometry: Application in two catchments in GreeceNatural Hazards56380381410.1007/s11069-010-9592-8Open DOISearch in Google Scholar
Drăguţ L., Eisank C., 2012. Automated object-based classification of topography from SRTM data. Geomorphology 141–142: 21–33.DrăguţL.EisankC.2012Automated object-based classification of topography from SRTM dataGeomorphology141–142213310.1016/j.geomorph.2011.12.001331278822485060Search in Google Scholar
Ehsani A.H., Quiel F., 2008. Geomorphometric feature analysis using morphometric parameterization and artificial neural networks. Geomorphology 99: 1–12EhsaniA.H.QuielF.2008Geomorphometric feature analysis using morphometric parameterization and artificial neural networksGeomorphology9911210.1016/j.geomorph.2007.10.002Search in Google Scholar
Evans I.S. 1972. General geomorphometry, derivatives of altitude and descriptive statistics. In: R.J. Chorley (ed.), Spatial Analysis in Geomorphology, New York: Harper and Row Publishers: 17–90.EvansI.S.1972General geomorphometry, derivatives of altitude and descriptive statisticsIn:ChorleyR.J.(ed.),Spatial Analysis in GeomorphologyNew YorkHarper and Row Publishers179010.4324/9780429273346-2Search in Google Scholar
Fu Q., Shi R., Li T., Sun Y., Liu D., Cui S., Hou R., 2019. Effects of land-use change and climate variability on streamflow in the Woken River basin in Northeast China. River Research and Applications 35(2): 121–132. Doi: 10.1002/rra.3397.FuQ.ShiR.LiT.SunY.LiuD.CuiS.HouR.2019Effects of land-use change and climate variability on streamflow in the Woken River basin in Northeast ChinaRiver Research and Applications35212113210.1002/rra.3397Open DOISearch in Google Scholar
Godfrey A., Ciurean R.L., van Westen C.J., Kingma N.C., Glade T., 2015. Assessing vulnerability of buildings to hydro-meteorological hazards using an expert based approach – An application in Nehoiu Valley, Romania. International Journal of Disaster Risk Reduction 13: 229–241. Doi: 10.1016/j.ijdrr.2015.06.001.GodfreyA.CiureanR.L.van WestenC.J.KingmaN.C.GladeT.2015Assessing vulnerability of buildings to hydro-meteorological hazards using an expert based approach – An application in Nehoiu Valley, RomaniaInternational Journal of Disaster Risk Reduction1322924110.1016/j.ijdrr.2015.06.001Open DOISearch in Google Scholar
Gorum T., Gonencgil B., Gokceoglu C., Nefeslioglu H.A., 2008. Implementation of Reconstructed Geomorphologic Units in Landslide Mapping. Natural Hazards 46: 323–351.GorumT.GonencgilB.GokceogluC.NefesliogluH.A.2008Implementation of Reconstructed Geomorphologic Units in Landslide MappingNatural Hazards4632335110.1007/s11069-007-9190-6Search in Google Scholar
Goudie A.S. (ed.), 2004. Encyclopedia of Geomorphology. Routledge Taylor and Francis Group, New York.GoudieA.S.(ed.),2004Encyclopedia of GeomorphologyRoutledge Taylor and Francis GroupNew YorkSearch in Google Scholar
Grabs T., Seibert J., Bishop K., Laudon H., 2009. Modeling spatial patterns of saturated areas: A comparison of the topographic wetness index and a dynamic distributed model. Journal of Hydrology 373(1–2): 15–23. Doi: 10.1016/j.jhydrol.2009.03.031.GrabsT.SeibertJ.BishopK.LaudonH.2009Modeling spatial patterns of saturated areas: A comparison of the topographic wetness index and a dynamic distributed modelJournal of Hydrology3731–2152310.1016/j.jhydrol.2009.03.031Open DOISearch in Google Scholar
Guisan A., Weiss S.B., Weiss A.D., 1999. GLM versus CCA spatial modeling of plant species distribution. Plant Ecology 143: 107–122.GuisanA.WeissS.B.WeissA.D.1999GLM versus CCA spatial modeling of plant species distributionPlant Ecology14310712210.1023/A:1009841519580Search in Google Scholar
Hannan M.F.I., 2017. Risk assessment and disaster mitigation directions flood in the Bandung basin area. MS. Bogor Agriculture University (IPB), IndonesiaHannanM.F.I.2017Risk assessment and disaster mitigation directions flood in the Bandung basin areaMS. Bogor Agriculture University (IPB)IndonesiaSearch in Google Scholar
Ho L.T.K., Umitsu M., 2011. Micro-landform classification and flood hazard assessment of the Thu Bon alluvial plain, central Vietnam via an integrated method utilizing remotely sensed data. Applied Geography 31(3): 1082–1093. Doi: 10.1016/j.apgeog.2011.01.005.HoL.T.K.UmitsuM.2011Micro-landform classification and flood hazard assessment of the Thu Bon alluvial plain, central Vietnam via an integrated method utilizing remotely sensed dataApplied Geography3131082109310.1016/j.apgeog.2011.01.005Open DOISearch in Google Scholar
Ho L.T.K., Umitsu M., Yamaguchi Y., 2010. Flood hazard mapping by satellite images and SRTM DEM in the Vugia – Thu Bon alluvial plain, central Vietnam. International archive of the photogrammetry, remote sensing and spatial information sciences XXXVIII(8). Kyoto, Japan.HoL.T.K.UmitsuM.YamaguchiY.2010Flood hazard mapping by satellite images and SRTM DEM in the Vugia – Thu Bon alluvial plain, central VietnamInternational archive of the photogrammetry, remote sensing and spatial information sciences XXXVIII(8).Kyoto, JapanSearch in Google Scholar
Horton R.E., 1945. Erosional development of streams and their drainage basins: Hydrophysical approach to quantitative morphology. Bulletin of the Geological Society of America 56: 275–370.HortonR.E.1945Erosional development of streams and their drainage basins: Hydrophysical approach to quantitative morphologyBulletin of the Geological Society of America5627537010.1130/0016-7606(1945)56[275:EDOSAT]2.0.CO;2Search in Google Scholar
Huang X., Wang L., Yang L., Kravchenko A.N., 2008. Management effects on relationships of crop yields with topography represented by wetness index and precipitation. Agronomy Journal 100(5): 1463. Doi: 10.2134/agronj2007.0325.HuangX.WangL.YangL.KravchenkoA.N.2008Management effects on relationships of crop yields with topography represented by wetness index and precipitationAgronomy Journal1005146310.2134/agronj2007.0325Open DOISearch in Google Scholar
Hudalah D., Winarso H., Woltjer J., 2010. Planning by opportunity: An analysis of periurban environmental conflicts in Indonesia. Environment & Planning A 42(9): 2254–2269.HudalahD.WinarsoH.WoltjerJ.2010Planning by opportunity: An analysis of periurban environmental conflicts in IndonesiaEnvironment & Planning A4292254226910.1068/a4317Search in Google Scholar
Huggett R.J., 2011. Fundamentals of Geomorphology. Routledge Taylor and Francis Group, New York.HuggettR.J.2011Fundamentals of GeomorphologyRoutledge Taylor and Francis GroupNew York10.4324/9780203860083Search in Google Scholar
Inglezakis V.J., Poulopoulos S.G., Arkhangelsky E., Zorpas A.A., Menegaki A.N., 2016. Chapter 3 – Aquatic Environment, Environment and Development, Elsevier: 137–212, Doi: 10.1016/B978-0-444-62733-9.00003-4.InglezakisV.J.PoulopoulosS.G.ArkhangelskyE.ZorpasA.A.MenegakiA.N.2016Chapter 3 – Aquatic EnvironmentEnvironment and DevelopmentElsevier13721210.1016/B978-0-444-62733-9.00003-4Open DOISearch in Google Scholar
Irvin B.J., Ventura S.J., Slater B.K., 1997. Fuzzy and isodata classification of landform elements from digital terrain data in Pleasant Valley, Wisconsin. Geoderma 77: 137–154.IrvinB.J.VenturaS.J.SlaterB.K.1997Fuzzy and isodata classification of landform elements from digital terrain data in Pleasant Valley, WisconsinGeoderma7713715410.1016/S0016-7061(97)00019-0Search in Google Scholar
Iwahashi J., Pike R.J., 2007. Automated classifications of topography from DEMs by an unsupervised nested-means algorithm and a three-part geometric signature. Geomorphology 86(3–4): 409–440. Doi: 10.1016/j.geomorph.2006.09.012.IwahashiJ.PikeR.J.2007Automated classifications of topography from DEMs by an unsupervised nested-means algorithm and a three-part geometric signatureGeomorphology863–440944010.1016/j.geomorph.2006.09.012Open DOISearch in Google Scholar
Jasiewicz J., Stepinski T.F., 2013. Geomorphons – a pattern recognition approach to classification and mapping of landforms. Geomorphology 182: 147–156. Doi: 10.1016/j.geomorph.2012.11.005.JasiewiczJ.StepinskiT.F.2013Geomorphons – a pattern recognition approach to classification and mapping of landformsGeomorphology18214715610.1016/j.geomorph.2012.11.005Open DOISearch in Google Scholar
Kartiwa B., Murniati E., Bormudoi A., 2013. Application of hydrological model, RS and GIS for flood mapping of citarum watershed, West Java Province, Indonesia. Journal of Remote Sensing Technology 1(1): 1–8.KartiwaB.MurniatiE.BormudoiA.2013Application of hydrological model, RS and GIS for flood mapping of citarum watershed, West Java Province, IndonesiaJournal of Remote Sensing Technology111810.18005/JRST0101001Search in Google Scholar
Lambin E.F., 1997. Modeling and monitoring land-cover change processes in tropical regions. Progress in Physical Geography 21(3): 375–393.LambinE.F.1997Modeling and monitoring land-cover change processes in tropical regionsProgress in Physical Geography21337539310.1177/030913339702100303Search in Google Scholar
Langhammer J., Vacková T., 2018. Detection and mapping of the geomorphic effects of flooding using UAV photogrammetry. Pure and Applied Geophysics 175(9): 3223–3245. Doi: 10.1007/s00024-018-1874-1.LanghammerJ.VackováT.2018Detection and mapping of the geomorphic effects of flooding using UAV photogrammetryPure and Applied Geophysics17593223324510.1007/s00024-018-1874-1Open DOISearch in Google Scholar
Lastra J, Fernández E., Díez-Herrero A., Marquínez J., 2008. Flood hazard delineation combining geomorphological and hydrological methods: An example in the Northern Iberian Peninsula. Natural Hazards 45: 277–293.LastraJFernándezE.Díez-HerreroA.MarquínezJ.2008Flood hazard delineation combining geomorphological and hydrological methods: An example in the Northern Iberian PeninsulaNatural Hazards4527729310.1007/s11069-007-9164-8Search in Google Scholar
Lopez E., Bocco G., Mendoza M., Duhau E., 2001. Predicting land cover and land use change in the urban fringe a case in Morelia City, Mexico. Landscape and Urban Planning 55(4): 271–285.LopezE.BoccoG.MendozaM.DuhauE.2001Predicting land cover and land use change in the urban fringe a case in Morelia City, MexicoLandscape and Urban Planning55427128510.1016/S0169-2046(01)00160-8Search in Google Scholar
Marshall S.J., 2013. Hydrology. Reference Module in Earth Systems and Environmental Sciences. Doi: 10.1016/B978-0-12-409548-9.05356-2MarshallS.J.2013HydrologyReference Module in Earth Systems and Environmental Sciences.10.1016/B978-0-12-409548-9.05356-2Open DOISearch in Google Scholar
Marshall S.J., 2014. The Water Cycle. Reference Module in Earth Systems and Environmental Sciences. Doi: 10.1016/B978-0-12-409548-9.09091-6.MarshallS.J.2014The Water CycleReference Module in Earth Systems and Environmental Sciences.10.1016/B978-0-12-409548-9.09091-6Open DOISearch in Google Scholar
Mergili M., Emmer A., Juřicová A., Cochachin A., Fischer J.T., Huggel C., Pudasaini S.P., 2018. How well can we simulate complex hydro-geomorphic process chains? The 2012 multi-lake outburst flood in the Santa Cruz Valley (Cordillera Blanca, Perú). Earth Surface Processes and Landforms 43(7): 1373–1389. Doi: 10.1002/esp.4318.MergiliM.EmmerA.JuřicováA.CochachinA.FischerJ.T.HuggelC.PudasainiS.P.2018How well can we simulate complex hydro-geomorphic process chains? The 2012 multi-lake outburst flood in the Santa Cruz Valley (Cordillera Blanca, Perú)Earth Surface Processes and Landforms4371373138910.1002/esp.4318Open DOISearch in Google Scholar
Motevalli A., Vafakhah M., 2016. Flood hazard mapping using synthesis hydraulic and geomorphic properties at watershed scale. Stochastic Environmental Research and Risk Assessment 30(7): 1889–1900. Doi: 10.1007/s00477-016-1305-8.MotevalliA.VafakhahM.2016Flood hazard mapping using synthesis hydraulic and geomorphic properties at watershed scaleStochastic Environmental Research and Risk Assessment3071889190010.1007/s00477-016-1305-8Open DOISearch in Google Scholar
Muharomah R., 2014. Analisis run-off sebagai dampak perubahan lahan sekitar pembangunan underpass Simpang Patal Palembang dengan memanfaatkan teknik GIS. Jurnal Teknik Sipil and Lingkungan 2(3): 424–433.MuharomahR.2014Analisis run-off sebagai dampak perubahan lahan sekitar pembangunan underpass Simpang Patal Palembang dengan memanfaatkan teknik GISJurnal Teknik Sipil and Lingkungan23424433Search in Google Scholar
Mulyo A., Haryanto A.D., Trirahardjo S., 2018. Korelasi hidrologi dan intensitas curah hujan daerah aliran sungai Cikapundung: suatu pemahaman untuk mitigasi banjir di Kasawan Cekungan Bandung. Laporan Kemajuan Riset Kompetensi Dosen UNPAD.MulyoA.HaryantoA.D.TrirahardjoS.2018Korelasi hidrologi dan intensitas curah hujan daerah aliran sungai Cikapundung: suatu pemahaman untuk mitigasi banjir di Kasawan Cekungan BandungLaporan Kemajuan Riset Kompetensi Dosen UNPADSearch in Google Scholar
Narasimhan T.N., 2009. Hydrological Cycle and Water Budgets, Encyclopedia of Inland Waters, Academic Press: 714–720. Doi: 10.1016/B978-012370626-3.00010-7.NarasimhanT.N.2009Hydrological Cycle and Water BudgetsEncyclopedia of Inland WatersAcademic Press71472010.1016/B978-012370626-3.00010-7Open DOISearch in Google Scholar
Narulita I., Rahmat A., Maria R., 2008. Geographic information system application for determining regions rehabilitation priorities in the Bandung Basin. Journal of Geology and Mining Research 18(1): 23–35.NarulitaI.RahmatA.MariaR.2008Geographic information system application for determining regions rehabilitation priorities in the Bandung BasinJournal of Geology and Mining Research181233510.14203/risetgeotam2008.v18.9Search in Google Scholar
Nurjaman A. (2018). Utilization of geographic information systems mapping of village areas in the area flow of Citarum river at Bandung district. MS. Bogor Agriculture University (IPB).NurjamanA.2018Utilization of geographic information systems mapping of village areas in the area flow of Citarum river at Bandung districtMS. Bogor Agriculture University (IPB)Search in Google Scholar
Olaya V., Conrad O., 2009. Geomorphometry in SAGA. In: T. Hengl, H.I. Reuter (eds.), Geomorphometry: Concepts, software, applications, Developments in Soil Science 33: 293–308. Doi: 10.1016/s0166-2481(08)00012-3.OlayaV.ConradO.2009Geomorphometry in SAGAIn:HenglT.ReuterH.I.(eds.),Geomorphometry: Concepts, software, applications, Developments in Soil Science3329330810.1016/s0166-2481(08)00012-3Open DOISearch in Google Scholar
Oya M., 2002. Applied geomorphology for mitigation of natural hazards. Natural Hazards 25(1): 17–25.OyaM.2002Applied geomorphology for mitigation of natural hazardsNatural Hazards251172510.1007/978-94-010-0961-4Search in Google Scholar
Panizza M., 1986. Environmental Geomorphology. Amsterdam: Elsevier.PanizzaM.1986Environmental GeomorphologyAmsterdamElsevierSearch in Google Scholar
Ramalingan S., Liu ZQ., Iourinski D., 2006. Curvature-based fuzzy surface classification. IEEE Transactions on Fuzzy Systems 14(4): 573–589.RamalinganS.LiuZQ.IourinskiD.2006Curvature-based fuzzy surface classificationIEEE Transactions on Fuzzy Systems14457358910.1109/TFUZZ.2006.876718Search in Google Scholar
Requena A.I., Flores I., Mediero L., Garrote L. 2015. Extension of observed flood series by combining a distributed hydro-meteorological model and a copula-based model. Stochastic Environmental Research and Risk Assessment 30(5): 1363–1378. Doi: 10.1007/s00477-015-1138-x.RequenaA.I.FloresI.MedieroL.GarroteL.2015Extension of observed flood series by combining a distributed hydro-meteorological model and a copula-based modelStochastic Environmental Research and Risk Assessment3051363137810.1007/s00477-015-1138-xOpen DOISearch in Google Scholar
Righini M., Surian N., Wohl E., Marchi L., Comiti F., Amponsah W., Borga M., 2017. Geomorphic response to an extreme flood in two Mediterranean rivers (northeastern Sardinia, Italy): Analysis of controlling factors. Geomorphology 290: 184–199. Doi: 10.1016/j.geomorph.2017.04.014.RighiniM.SurianN.WohlE.MarchiL.ComitiF.AmponsahW.BorgaM.2017Geomorphic response to an extreme flood in two Mediterranean rivers (northeastern Sardinia, Italy): Analysis of controlling factorsGeomorphology29018419910.1016/j.geomorph.2017.04.014Open DOISearch in Google Scholar
Rimal B., Zhang L., Stork N., Sloan S., Rijal S., 2018. Urban expansion occurred at the expense of agricultural lands in the Tarai region of Nepal from 1989 to 2016. Sustainability 10: 1341.RimalB.ZhangL.StorkN.SloanS.RijalS.2018Urban expansion occurred at the expense of agricultural lands in the Tarai region of Nepal from 1989 to 2016Sustainability10134110.3390/su10051341Search in Google Scholar
Rosyidie A., 2013. Flood: Facts and effects, and the effects of land use change. Journal of Urban and Regional Planning 24(3): 241–249.RosyidieA.2013Flood: Facts and effects, and the effects of land use changeJournal of Urban and Regional Planning24324124910.5614/jpwk.2013.24.3.1Search in Google Scholar
Ruffell A., McKinley J., 2014. Forensic geomorphology. Geomorphology 206: 14–22. Doi: 10.1016/j.geomorph.2013.12.020.RuffellA.McKinleyJ.2014Forensic geomorphologyGeomorphology206142210.1016/j.geomorph.2013.12.020Open DOISearch in Google Scholar
Samela C., Troy T.J., Manfreda S., 2017. Geomorphic classifiers for flood-prone areas delineation for data-scarce environments. Advances in Water Resources 102: 13–28. Doi: 10.1016/j.advwatres.2017.01.007.SamelaC.TroyT.J.ManfredaS.2017Geomorphic classifiers for flood-prone areas delineation for data-scarce environmentsAdvances in Water Resources102132810.1016/j.advwatres.2017.01.007Open DOISearch in Google Scholar
Schillaci C., Braun A., Kropáček J., 2015. Terrain analysis and landform recognition. In: L. Clarke, J. Nield, Geomorphological techniques, chap. 2, 4.2. Doi: 10.13140/RG.2.1.3895.2802.SchillaciC.BraunA.KropáčekJ.2015Terrain analysis and landform recognitionIn:ClarkeL.NieldJ.Geomorphological techniqueschap. 2, 4.2.10.13140/RG.2.1.3895.2802Open DOISearch in Google Scholar
Srivastava P.K., Han D., Rico-Ramirez M.A., Islam T., 2013. Sensitivity and uncertainty analysis of mesoscale model downscaled hydro-meteorological variables for discharge prediction. Hydrological Processes 28(15): 4419–4432. Doi: 10.1002/hyp.9946.SrivastavaP.K.HanD.Rico-RamirezM.A.IslamT.2013Sensitivity and uncertainty analysis of mesoscale model downscaled hydro-meteorological variables for discharge predictionHydrological Processes28154419443210.1002/hyp.9946Open DOISearch in Google Scholar
Strahler A.N., 1957. Quantitative analysis of watershed geomorphology. Transactions, American Geophysical Union 38(6): 913–920. Doi: 10.1029/tr038i006p00913.StrahlerA.N.1957Quantitative analysis of watershed geomorphologyTransactions, American Geophysical Union38691392010.1029/tr038i006p00913Open DOISearch in Google Scholar
Szwagrzyk M., Kaim D., Price B., Wypych A., Grabska E., Kozak J., 2018. Impact of forecasted land use changes on flood risk in the Polish Carpathians. Natural Hazards 94: 227–240. Doi: 10.1007/s11069-018-3384-y.SzwagrzykM.KaimD.PriceB.WypychA.GrabskaE.KozakJ.2018Impact of forecasted land use changes on flood risk in the Polish CarpathiansNatural Hazards9422724010.1007/s11069-018-3384-yOpen DOISearch in Google Scholar
Tagil S., Jenness J., 2008. GIS-based automated landform classification and topographic, landcover and geologic attributes of landforms around the Yazoren Polje, Turkey. Journal of Applied Sciences 8: 910–921.TagilS.JennessJ.2008GIS-based automated landform classification and topographic, landcover and geologic attributes of landforms around the Yazoren Polje, TurkeyJournal of Applied Sciences891092110.3923/jas.2008.910.921Search in Google Scholar
Twele A., Cao W., Plank S., Martinis S., 2016. Sentinel-1-based flood mapping: A fully automated processing chain. International Journal of Remote Sensing 37(13): 2990–3004. Doi: 10.1080/01431161.2016.1192304TweleA.CaoW.PlankS.MartinisS.2016Sentinel-1-based flood mapping: A fully automated processing chainInternational Journal of Remote Sensing37132990300410.1080/01431161.2016.1192304Open DOISearch in Google Scholar
Verstappen, H.Th., 1983. Applied Geomorphology: Geomorphological Surveys for Environmental Development. Amsterdam: Elsevier.VerstappenH.Th.1983Applied Geomorphology: Geomorphological Surveys for Environmental DevelopmentAmsterdamElsevierSearch in Google Scholar
Wan R., Yang G., 2007. Influence of land use/cover change on storm runoff—a case study of Xitiaoxi River Basin in upstream of Taihu Lake watershed. Chinese Geographical Science 17(4): 349–356.WanR.YangG.2007Influence of land use/cover change on storm runoff—a case study of Xitiaoxi River Basin in upstream of Taihu Lake watershedChinese Geographical Science17434935610.1007/s11769-007-0349-6Search in Google Scholar
Warburton M.L., Schulze R.E., Jewitt G.P.W., 2012. Hydrological impacts of land use change in three diverse South African catchments. Journal of Hydrology 414–415: 118–135.WarburtonM.L.SchulzeR.E.JewittG.P.W.2012Hydrological impacts of land use change in three diverse South African catchmentsJournal of Hydrology414–41511813510.1016/j.jhydrol.2011.10.028Search in Google Scholar
Weiss A.D. 2001. Topographic position and landforms analysis. ESRI Users Conference, San Diego, CA, USA.WeissA.D.2001Topographic position and landforms analysisESRI Users ConferenceSan Diego, CA, USASearch in Google Scholar
Wilson J.P., Gallant J.C., 2000. Primary topographic attributes. In: J.P. Wilson, J.C. Gallant (eds.), Terrain analysis: Principles and applications, John Wiley & Sons, New York: 51–85.WilsonJ.P.GallantJ.C.2000Primary topographic attributesIn:WilsonJ.P.GallantJ.C.(eds.),Terrain analysis: Principles and applicationsJohn Wiley & SonsNew York5185Search in Google Scholar
Yang L., Chen L., Wei W., 2015. Effects of vegetation restoration on the spatial distribution of soil moisture at the hill slope scale in semi-arid regions. Catena 124: 138–146. Doi: 10.1016/j.catena.2014.09.014.YangL.ChenL.WeiW.2015Effects of vegetation restoration on the spatial distribution of soil moisture at the hill slope scale in semi-arid regionsCatena12413814610.1016/j.catena.2014.09.014Open DOISearch in Google Scholar
Yang W., Long D., Bai P., 2019. Impacts of future land cover and climate changes on runoff in the mostly afforested river basin in North China. Journal of Hydrology 570: 201–219. Doi: 10.1016/j.jhydrol.2018.12.055.YangW.LongD.BaiP.2019Impacts of future land cover and climate changes on runoff in the mostly afforested river basin in North ChinaJournal of Hydrology57020121910.1016/j.jhydrol.2018.12.055Open DOISearch in Google Scholar
Yucel I., Onen A., Yilmaz K.K., Gochis D.J., 2015. Calibration and evaluation of a flood forecasting system: Utility of numerical weather prediction model, data assimilation and satellite-based rainfall. Journal of Hydrology 523: 49–66. Doi: 10.1016/j.jhydrol.2015.01.042.YucelI.OnenA.YilmazK.K.GochisD.J.2015Calibration and evaluation of a flood forecasting system: Utility of numerical weather prediction model, data assimilation and satellite-based rainfallJournal of Hydrology523496610.1016/j.jhydrol.2015.01.042Open DOISearch in Google Scholar
Yulianto F., Maulana T., Khomarudin M.R., 2018. Analysis of the dynamics of land use change and its prediction based on the integration of remotely sensed data and CA-Markov model, in the upstream Citarum Watershed, West Java, Indonesia. International Journal of Digital Earth 12(10): 1151–1176. Doi: 10.1080/17538947.2018.1497098.YuliantoF.MaulanaT.KhomarudinM.R.2018Analysis of the dynamics of land use change and its prediction based on the integration of remotely sensed data and CA-Markov model, in the upstream Citarum Watershed, West Java, IndonesiaInternational Journal of Digital Earth12101151117610.1080/17538947.2018.1497098Open DOISearch in Google Scholar
Yulianto F., Sofan P., Zubaidah A., Sukowati K.A.D., Pasaribu J.M., Khomarudin M.R., 2015. Detecting areas affected by flood using multi-temporal ALOS PALSAR remotely sensed data in Karawang, West Java, Indonesia. Natural Hazards 77(2): 959–985. Doi: 10.1007/s11069-015-1633-x.YuliantoF.SofanP.ZubaidahA.SukowatiK.A.D.PasaribuJ.M.KhomarudinM.R.2015Detecting areas affected by flood using multi-temporal ALOS PALSAR remotely sensed data in Karawang, West Java, IndonesiaNatural Hazards77295998510.1007/s11069-015-1633-xOpen DOISearch in Google Scholar
Yulianto F., Suwarsono S., Sulma S., 2019. Improving the accuracy and reliability of land use/land cover simulation by the integration of Markov cellular automata and landform-based models – a case study in the upstream Citarum watershed, West Java, Indonesia. Journal of Degraded and Mining Lands Management 6(2): 1675–1696. Doi: 10.15243/jdmlm.2019.062.1675.YuliantoF.SuwarsonoS.SulmaS.2019Improving the accuracy and reliability of land use/land cover simulation by the integration of Markov cellular automata and landform-based models – a case study in the upstream Citarum watershed, West Java, IndonesiaJournal of Degraded and Mining Lands Management621675169610.15243/jdmlm.2019.062.1675Open DOISearch in Google Scholar
Zhang B.P., Yao Y.H., Cheng W.M., Zhou C.H., Lu Z., Chen X.D., 2002. Human-induced changes to biodiversity and alpine pastureland in the Bayanbulak Region of the East Tianshan Mountains. Mountain Research and Development 22: 1–7.ZhangB.P.YaoY.H.ChengW.M.ZhouC.H.LuZ.ChenX.D.2002Human-induced changes to biodiversity and alpine pastureland in the Bayanbulak Region of the East Tianshan MountainsMountain Research and Development221710.1659/0276-4741(2002)022[0383:HICTBA]2.0.CO;2Search in Google Scholar
, 