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31520149JournalofUniversityofChineseAcademyofSciencesVol.31SeptemberNo.52014*2013CB430401Y3A1014001E-mailSongks@neigae.ac.cn2095-6134201405-0640-07ArcGISEngine*1211121212121130102210004920139302013125DingZSongKSWangZMetal.ContrastiveanalysisofalgorithmsoftheforestfirespreadingsimulationbasedonArcGISEngineJ.JournalofUniversityofChineseAcademyofSciences2014315640-646...5、7、16s3204、458、1325s.59.75%.79.51%.ArcGISEngineS762Adoi10.7523/j.issn.2095-6134.2014.05.009ContrastiveanalysisofalgorithmsoftheforestfirespreadingsimulationbasedonArcGISEngineDINGZhi12SONGKaishan1WANGZongming1TANGXuguang12DONGZhangyu12JIAMingming12SHAOTiantian121NortheastInstituteofGeographyandAgroecologyChineseAcademyofSciencesChangchun130102China2UniversityofChineseAcademyofSciencesBeijing100049ChinaAbstractSelectionofalgorithmsforforestfirespreadingsimulationisimportant.Inthispaperthetraditionalboundaryinterpolationalgorithmisoptimizedandthencomparedwiththemazealgorithminforestfirespreadingsimulation.Theresultsarethefollowing.Themazealgorithmconsumesmoretime204、458、1325sthantheboundaryinterpolationalgorithm5、7、16s.ThetimeconsumedbythemazealgorithmwilldoublyincreaseAsfarasaccuracyofsimulationresultsconcernedtheboundaryinterpolationalgorithmhasaloweraccuray59.75%thanthemazealgorithmbutitshowssimplechangesoftheforestfirespreadinggenerally.Resultsobtainedfrommazealgorithmprovidemoredetailedinformationfortheforestfirespreadinganditresemblescloselytoactualspreadingarea.KeywordsforestfirespreadingsimulationboundaryinterpolationmazealgorithmArcGISEngine5ArcGISEngine.22640hm20.23%1.200920.36%198756124.3hm2.、、2.、.、、、、3.4-7.Rothermel8、9、McArthur1011-14.15-19.20.、Huygens21..20094272.11.1VisualC#ArcGISEngine.ArcGISEngineESRIArcMapArcObjects.ArcGISEngineArcMapArcMap.ArcGISEngineArcObjectsArcGISEngine.ArcGISEngineESRIGISGIS.ArcGISEngine.1.212、、3..———.211R0=0.0299×T+0.047×W+0.009×100-h-0.3041R0WTh.22Rup=R0×Ks×exp3.533×tgφ×1.2×exp0.1783×V×cosθ214631Rdown=R0×Ks×exp-3.533×tgφ×1.2×exp0.1783×V×cos180°-θ3Rleft=R0×Ks×exp0.1783×cos90°+θ4Rright=R0×Ks×exp0.1783×V×cosθ-90°5Rwl=R0×Ks×exp3.533×tgφ×cosθ1.2×exp0.1783×V6θ=0°~90°θ=270°~360°Rw2=R0×Ks×exp-3.533×tgφ×cos180°-θ1.2×exp0.1783×V7θ=90°~270°.Rw1Rw2R0KsΦVθ22.1.3.88、、、、、、....88.3.3TT+t、T、T-t.3..ESRIArcGISEngineArcGIS.Kringing、spline、IDW3.3..1.4..8E、SE、S、SW、W、NW、N、NE.8∑t∑tT∑t∑t∑tT8.∑tT.2.1.1.2465ArcGISEngine232..1Fig.1Diagramofdepth-firstsearch2Fig.2Diagramofbreadth-firstsearch22.12009.42713405212.4291404..21.7℃37.4%2.1m/s6.1m/s.DEM、、.2008Landsat-730mESRIArcMapDEM30m2009429Landsat2009427—29.、、、、、.3Fig.3Processofbasedata2.2213234..ESRIArcGIS346314Fig.4SimulationofboundaryinterpolationalgorithmEngine.IRasterRendererArcGISEngine11.5.5Fig.5Simulationofmazealgorithm2.3、、..6.6Fig.6Resultsofsimulation.3.1313Table1ResultsattimeofT1T2andT3T1=20hT2=48hT3=76h/km2/km221.2340.2566.1922.48/s5716/km236.5870.65125.35/s204458132544.394465ArcGISEngine7km221km2.30s10s.72./79.51%/458s7s.7T2Fig.7OverlayofactualandsimulatedburnedareasattimeofT22T2Table2ComparisonofsimulationresultsattimeofT2/km2/km2/%/%/s58.6640.2535.0587.0759.75770.6546.6466.0279.5145832.87.07%..、.2、.1GuoKJZhangWQuJX.PresentstatusandprospectofforestfirefightingequipmentJ.ForestryMachinery&WoodworkingEquipment20093778inChinese..J.20093778.2ZhaoLLiuPJZhouYFetal.InterpolationovercomplexterrainanditsapplicationinthesimulationofforestfirespreadingJ.JournalofBeijingForestryUniversity201032412-16inChinese..J.201032412-16.3TangXYMengXYYiHR.ReviewandprospectofresearchesonforestfirespreadingmodelsandsimulatingmethodJ.JournalofBeijingForestryUniversity200224187-91inChinese..J.200224187-91.546314HernándezEncinasAHernándezEncinasLHoyaWhiteSetal.SimulationofforestfirefrontsusingcellularautomataJ.AdvancesinEngineeringSoftware2007386372-378.5YassemiSDragicevicSSchmidtM.DesignandimplementationofanintegratedGIS-basedcellularautomatamodeltocharacterizeforestfirebehaviorJ.EcologicalModelling2008210171-84.6DenhamMCortésAMargalefT.ComputationalsteeringstrategytocalibrateinputvariablesinadynamicdatadrivengeneticalgorithmforforestfirespreadpredictionM.ComputationalScience-ICCSSpringerBerlinHeidelberg2009479-488.7FinneyMAGrenfellICMcHughCWetal.AmethodforensemblewildlandfiresimulationJ.EnvironmentalModeling&Assessment2011162153-167.8RothermelRC.AmathematicalmodelforpredictingfirespreadinwildlandfuelsM.USFS1972.9.M.199224.10McArthurAG.WeatherandgrasslandfirebehaviorM.ForestryandTimberBureauDepartmentofnationalDevelopmentCommonwealthofAustralia1966.11WangZF.ThemeasurementmethodofthewildfireinitialspreadrateJ.MountainResearch19831242-51inChinese..J.19831242-51.12WangZF.CurrentforestfiredangerratingsystemJ.JournalofNaturalDisasters19921341inChinese..J.19921341.13WangHHZhuQPJiangWetal.AmathematicalmodelforestimatingsurfacefirebehaviorJ.FireSafetyScience19943133-41inChinese..J.19943133-41.14YuanHYFanWC.ThemathematicmodelforsurveyingsurfacefirebehaviorbyuseofaerophotogrammetryandDTMJ.FireSafetyScience19954231-51inChinese..DTMJ.19954231-51.15MuzyAWainerGInnoce
本文标题:基于ArcGISEngine林火蔓延模拟算法的比较分析-丁智
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