疏勒河上游流域地面坡谱特征

坡谱是以某项坡面因子为自变量,其对应的地面面积为因变量所构成的统计图表或模型。坡谱用微观的地形因子反映宏观的地貌特征的空间分异。以ASTER GDEM V002作为基础数据,利用Arc GIS中数字地形分析工具,提取了疏勒河上游流域的地面坡度、坡向、坡度变率、坡向变率,并分别进行了面积统计,绘制了坡谱曲线。结果显示:研究区以陡坡、斜坡为主,二者占总面积的74.16%,陡坡主要分布在疏勒南山、托来南山,斜坡则主要分布在山脉与盆地的过渡地带。在疏勒河盆地和昌马盆地,坡度变率较小,而坡向变率则较大。疏勒河上游流域地面坡谱反映出研究区地面起伏大,地形破碎。坡度变率、坡向变率对山脊线、疏勒河沟沿线具有重要的指示作用。     

基于 SRTM DEM 的祁连山自然保护区地形特征研究

基于研究区的 SRTM DEM 模型,应用 ArcGIS10.5 空间分析模块及 Excel、SPSS 数据统计分 析功能,采用均值变点分析法确定地形起伏度的邻域分析最佳统计单元;提取了研究区高程、地形 起伏度、地形坡度、地表粗糙度和地表切割度 5 个地形因子,以分析研究区的地形特征。结果表明： 研究区地形起伏度最佳统计单元为 11 像元×11 像元（0.98 km²）,地形起伏度为 0～1 216 m。研究区 包含 13 种地貌类型,87.28%的区域为中海拔,中海拔平原、台地、丘陵为主要地貌类型。走廊南山、 冷龙岭、乌鞘岭和龙首山地平行分布,台地、丘陵穿插其中,地形复杂。研究结果为进一步探索自 然保护区的生态保护、开发利用等具体问题提供了基础数据支持。     

黄土丘陵沟壑区坡度尺度效应空间分异分析

基于DEM提取的地形因子随分辨率变化问题(尺度效应)受到广泛关注,不同地貌类型区地形因子随分辨率变化规律存在差异,其差异的机理性原因还有待进一步探讨。本研究以黄土丘陵沟壑区五个副区为研究区,统计了不同地貌类型区坡度随分辨率变化规律,计算了高程变异函数,并引入独立结构变异函数模型(Independent Structures Model,ISM)拟合了高程表面不同空间频率层次,分析了地形空间频率层次在黄土丘陵沟壑区的空间分异规律,从而进一步分析坡度随分辨率变化规律与地形空间频率层次之间的关系。研究表明:平均坡度相近的地区坡度随分辨率变化规律并不相同,高频地形信息的存在与否及其所占比重,是决定一个地区坡度随分辨率变化衰减程度的重要因素,在坡度随分辨率变化衰减程度和坡度尺度变换研究及应用中应考虑研究区内地形空间频率组成情况,这对于丰富和完善数字地形分析理论体系具有重要意义。     

黄土地貌地形特征点格局研究

地形特征点广泛分布于地球表面,是反映地貌空间形态的重要点位。通过对不同地形特征点空间分布格局的研究,能够较好地探讨地形特征点群间的空间结构关系及其关联模式,并进一步映射地貌演变过程与发育机理。该文以黄土高原为研究区域,提取山顶点、鞍部点与径流节点作为地形特征点,运用点格局分析方法研究地形特征点间的空间结构特征。结果表明:1)地形特征点的空间分布规律与其地貌类型有显著相关性,而与其等级无明显相关;2)不同特征点存在较为固定的空间关联尺度,这种尺度对地貌类型不存在依赖性;3)在地貌演变的多个时期,不同特征点间的空间格局指标变化趋势具有相似性,而空间分布类型由于受地貌影响存在差异性。运用点格局研究中的相关方法,探索了地形特征点单点及多点间的格局特征,对地形特征结构及其模式研究具有参考意义。     

基于DEM的地球与火星格状沙丘对比分析

沙丘是柴达木盆地可类比火星的重要地貌类型,沙丘形态是类火星风沙地貌研究的重要内容。基于数字地形分析（DTA）的方法,采用高程、坡度、坡向及地表复杂程度4个地形计量学指标对火星（北极地区）和地球（柴达木盆地）格状沙丘的地貌形态特征进行定量对比分析。结果表明：（1）两个研究区的高程剖面、坡度、坡向的地理学空间分布格局具有较大相似性;（2）高程、高程梯度、坡度和坡向的直方图相似度指数均大于0.7;（3）不同尺度上的分形维数近似相等,即地表复杂程度相似。用数字地形分析与直方图相似度指数结合的方法,定量或半定量地分析两个研究区沙丘地貌形态的相似性,这对类火星风沙地貌研究中科学选择试验点是一种新的尝试,以期为反演火星风沙地貌的形成与演化提供科学依据。     

基于GIS的侵蚀冲沟与地貌因子的关系

冲沟是多种外力作用的结果,展示为多种地貌现象。选择胶东半岛北岩子口小流域作为研究对象,以正射影像（DOM）和数字高程模型（DEM）为数据源,选择土地利用、地形湿度指数、坡度坡长因子、水流动力指数、坡向、平面曲率和地表粗糙度等7个地貌因子,计算小流域土壤侵蚀敏感性,研究侵蚀冲沟与地貌因子的关系。结果表明:冲沟多发生在坡度坡长较大、水流动力强、地表湿度较低的林草地区域,多分布在阳坡的凹面;冲沟大多分布在土壤侵蚀中等敏感性及以上的区域,约占总冲沟的96.4%;在土壤侵蚀中等敏感性及以上区域,实验权重值对验证区冲沟分布的响应精度为87.9%,与实际值93.3%相差较小,精度较高。研究结果可为区域内冲沟侵蚀的评价提供一定科学依据。     

基于高分辨率DEM的黄土地貌正负地形自动分割技术研究

黄土地貌正负地形自动分割是构建地表空间分布式机理-过程模型的基础。在分析黄土高原地区典型地貌坡面形态及汇流过程特征的基础上,提出了基于5m分辨率栅格DEM自动分割黄土正、负地形的技术方案。该方案首先利用坡面上下游栅格点的坡度对比识别沟沿线点,然后利用汇水模型提取沟沿线点约束的上游汇水区域,从而实现正、负地形的自动分割。在黄土塬区及丘陵沟壑区的实验结果表明,该方法的优点是提取精度高,人工干预少,在不同地貌类型区域内有很好的应用适宜性。     

滇东北山区坡耕地土壤侵蚀的地形因子

通过在滇东北山区坡耕地上设置１８个不同坡度和坡长的试验小区,并进行连续３年实测,得到本区域土壤侵蚀地形因子（ＬＳ）的定量关系式,据此求得滇东北山区坡耕地土壤侵蚀的坡面地形效应（ＬＳ值）表。     

黄土高原坡耕地苜蓿产量及水土流失地形分异模拟——以延安燕沟流域为例

退耕还林还草是目前黄土高原整治生态环境和控制水土流失的主体政策。为使生态退耕政策得到有效落实,本文基于WIN-YIELD软件,以延安燕沟流域为例,利用2006年延安站的逐日气象数据和燕沟流域地貌、土壤及土地利用等资料,模拟分析了不同地形高程、坡度和坡向条件下坡耕地种植苜蓿的秸秆干物质产量、水土流失量及其地形分异特征。结果表明:在黄土高原,地形坡度是影响苜蓿秸秆干物质产量和泥沙流失的重要因素,苜蓿秸秆产量模拟值随地形坡度的增大而减小,泥沙流失的模拟值随地形坡度的增大而增大;地形高程1000 m以下的地域种植苜蓿其产量明显高于1000 m以上的地域,坡耕地苜蓿产生径流和泥沙随地形高程的变化不显著;地形坡向对苜蓿秸秆产量和水土流失量的影响不大。     

新疆地形复杂度的空间格局及地理特征

地形复杂度（TCI）是区域地表外在形态结构的数字化表达,既可表征坡面单元的多样性及其组合形式的复杂性,也可映射地球内外营力在地表留下“烙印”的过程,其客观描述和定量表达可为地表形态定义、刻画及分异等地形地貌理论研究提供重要依据。新疆独特的山盆地貌结构为地貌学研究提供了理想的场所。本文基于“倒金字塔滤网系统”逐步筛选微观和宏观坡面因子并确定权重进而构建地形复杂度模型;运用均值变点法确定新疆地形复杂度的最佳窗口,分析不同地貌单元地形复杂度的空间异质性,进一步探究不同营力作用对地表复杂程度的贡献。结果显示：① 地形复杂度模型综合相关性分析、聚类分析、变异系数法与主成分分析等方法对地形因子进行客观筛选与科学组合,使其具有全面客观性及独立有效性。② 地形复杂度以ASTER GDEM数据（30 m）为基础,得到最佳窗口（14×14）下全疆TCI介于0.13~46.36。山地与盆地相同地貌类型TCI面积占比峰值相近,不同地貌类型可比较其斜率、偏度及峰度得以区分。在经纬向上能更好的刻画出独立山峰及深切峡谷等局部地形分异,TCI≈1可作为平原与山地地貌单元之间的分界值。在高程分区下TCI>2时为各山系（山群）震荡高程区起始处,山麓处TCI曲线差异显著。③ 地形复杂度能较好的体现不同外营力在地表留下的痕迹,一定程度上也可表征外营力对不同成因地貌类型的贡献度。本研究对新疆地形地貌的形态特征和形成原因等方面提供理论依据和科学方法,可为地形地貌研究、生态环境影响以及区域发展评价提供实践指导。     

基于DEM的任意方向坡度计算方法

坡度是数字地形分析中重要的地形因子,在水文分析、土壤侵蚀模拟、地貌类型划分等地学分析及工程上均有广泛的应用。由于地形的各向异性,坡度在各个方向上并不相同。目前,基于DEM所提取的坡度,均是位于最陡方向上的坡度,而任意给定方向坡度计算是地学分析和工程应用中较为常见的问题。在对目前DEM坡度提取算法研究的基础上,通过数学分析,给出了格网DEM上任意方向格网点的坡度计算模型和计算流程,并给出了相应的计算实例,从而将坡度计算模型从特定方向推向任意方向,使DEM坡度计算更具普适性。     

Simulation on slope uncertainty derived from DEMs at different resolution levels： a case study in the Loess Plateau

Slope is one of the crucial terrain variables in spatial analysis and land use planning, especially in the Loess Plateau area of China which is suffering from serious soil erosion. DEM based slope extracting method has been widely accepted and applied in practice. However slope accuracy derived from this method usually does not match with its popularity. A quantitative simulation to slope data uncertainty is important not only theoretically but also necessarily to applications. This paper focuses on how resolution and terrain complexity impact on the accuracy of mean slope extracted from DEMs of different resolutions in the Loess Plateau of China. Six typical geomorphologic areas are selected as test areas, representing different terrain types from smooth to rough. Their DEMs are produced from digitizing contours of 1:10,000 scale topographic maps. Field survey results show that 5 m should be the most suitable grid size for representing slope in the Loess Plateau area. Comparative and math-simulation methodology was employed for data processing and analysis. A linear correlativity between mean slope and DEM resolution was found at all test areas, but their regression coefficients related closely with the terrain complexity of the test areas. If taking stream channel density to represent terrain complexity, mean slope error could be regressed against DEM resolution (X) and stream channel density (S) at 8 resolution levels and expressed as(0.0015S2 0.031S-0.0325)X-0.0045S2-0.155S 0.1625, with a R2 value of over 0.98. Practical tests also show an effective result of this model in applications. The new development methodology applied in this study should be helpful to similar researches in spatial data uncertainty investigation.     

基于USLE和GIS的水土流失敏感性空间分析——以河北太行山区为例

以USLE方程为理论指导,遥感影像为主要数据源,基于ArcGIS 进行水土流失敏感性空间分析。选择降雨侵蚀力、土地利用类型、坡度、植被覆盖度等影响因子构建水土流失敏感性评价指标体系,在考虑不同因子影响作用大小的情况下,运用空间分析的方法按标准将水土流失敏感性分为五级;并以河北太行山区为例进行研究,利用危险性指数表征研究区水土流失敏感性大小,分析研究区在不同地理背景下的水土流失敏感区的空间分布特征。研究表明：河北太行山区的水土流失敏感性危险性指数为3.97;空间上水土流失敏感性分等级呈现明显的条带状分布;中度敏感区所占面积比例最大,为39.2%;整体水土流失敏感性中度偏重。     

Simulation on slope uncertainty derived from DEMs at different resolution levels: a case study in the Loess Plateau

Slope is one of the crucial terrain variables in spatial analysis and land use planning, especially in the Loess Plateau area of China which is suffering from serious soil erosion. DEM based slope extracting method has been widely accepted and applied in practice. However slope accuracy derived from this method usually does not match with its popularity. A quantitative simulation to slope data uncertainty is important not only theoretically but also necessarily to applications. This paper focuses on how resolution and terrain complexity impact on the accuracy of mean slope extracted from DEMs of different resolutions in the Loess Plateau of China. Six typical geomorphologic areas are selected as test areas, representing different terrain types from smooth to rough. Their DEMs are produced from digitizing contours of 1:10,000 scale topographic maps. Field survey results show that 5 m should be the most suitable grid size for representing slope in the Loess Plateau area. Comparative and math-simulation methodology was employed for data processing and analysis. A linear correlativity between mean slope and DEM resolution was found at all test areas, but their regression coefficients related closely with the terrain complexity of the test areas. If taking stream channel density to represent terrain complexity, mean slope error could be regressed against DEM resolution (X) and stream channel density (S) at 8 resolution levels and expressed as (0.0015S2+0.031S-0.0325)X-0.0045S2-0.155S+0.1625, with a R2 value of over 0.98. Practical tests also show an effective result of this model in applications. The new development methodology applied in this study should be helpful to similar researches in spatial data uncertainty investigation.     

DEM提取黄土高原地面坡度的不确定性

选择陕北黄土高原6个典型地貌类型区为试验样区,采用野外实测及高精度的1:1万比例尺DEM为基准数据,研究栅格分辨率及地形粗糙度对DEM所提取地面平均坡度精度的影响。结果显示,对于1:1万比例尺DEM,5 m是保证该地区地形描述精度的理想分辨率尺度;多要素逐步回归模拟的方法进一步揭示了DEM所提取的地面平均坡度误差E与栅格分辨率X以及地形起伏的代表性因子-沟壑密度S之间存在的量化关系为E = (0.0015S2+0.031S-0.0325)X-0.0045S2-0.155S+0.1625,该结果也为确定适用的DEM分辨率提供了理论依据。     

规则格网DEM坡度坡向算法的比较分析

DEM的主要用途之一就是提取坡度和坡向。目前基于格网DEM的坡度坡向算法比较多,正确分析和评价现有算法是当前较为关心的问题。通过对格网DEM的算法进行了简要的归纳,然后对坡度坡向算法进行了理论分析。并通过实验对相关的结论进行了验证。本研究澄清了目前有关DEM坡度坡向算法中存在的一些问题,对实际应用有一定的指导意义。     

Crossing natural and data set boundaries: coastal terrain modelling in the South-West Finnish Archipelago

Geographical information systems (GIS) are important tools in coastal research and management. Coastal GIS applications involve special challenges, because the coastal environment is a complex transitional system between the terrestrial and marine realms. Also acquisition methods and responsibilities for spatial data (and thus their properties) change at the shoreline. This article explores the consequences of this land-sea divide for coastal terrain modelling. We study how methods designed for terrestrial environments can be used to create integrated raster coastal terrain models (CTMs) from coarse elevation and depth data. We focus on shore slopes, because many particularities of coastal terrain and the data which describe it as well as the resulting problems are concentrated in the shore zone. Based on shorelines, terrestrial contours, depth contours and depth points, we used the ANUDEM algorithm to interpolate CTMs at different spatial resolutions, with and without drainage enforcement, for two test areas in a highly complex archipelago coast. Slope aspect and gradient rasters were derived from the CTMs using Horn's algorithm. Values were assigned from the slope rasters to thousands of points along the test areas' shorelines in different ways. Shore slope gradients and aspects were also calculated directly from the shorelines and contours. These modelled data were compared to each other and to field-measured shore profiles using a combination of qualitative and quantitative methods. As far as the coarse source data permitted, the interpolation and slope calculations delivered good results at fine spatial resolutions. Vector-based slope calculations were very sensitive to quality problems of the source data. Fine-resolution raster data were consequently found most suitable for describing shore slopes from coarse coastal terrain data. Terrestrial and marine parts of the CTMs were subject to different errors, and modelling methods and parameters had different consequences there. Thus, methods designed for terrestrial applications can be successfully used for coastal terrain modelling, but the choice of methods and parameters and the interpretation of modelling results require special attention to the differences of terrestrial and marine topography and data.     

不同分辨率DEM提取地面坡度的不确定性模拟:以在黄土高原的试验为例

Slope is one of the crucial terrain variables in spatial analysis and land use planning,especially in the Loess Plateau area of China which is suffering from serious soil erosion. DEM based slope extracting method has been widely accepted and applied in practice. However slope accuracy derived from this method usually does not match with its popularity. A quantitative simulation to slope data uncertainty is important not only theoretically but also necessarily to applications. This paper focuses on how resolution and terrain complexity impact on the accuracy of mean slope extracted from DEMs of different resolutions in the Loess Plateau of China. Six typical geomorphologic areas are selected as test areas, representing different terrain types from smooth to rough. Their DEMs are produced from digitizing contours of 1:10,000 scale topographic maps. Field survey results show that 5 m should be the most suitable grid size for representing slope in the Loess Plateau area. Comparative and math-simulation methodology was employed for data processing and analysis. A linear correlativity between mean slope and DEM resolution was found at all test areas,but their regression coefficients related closely with the terrain complexity of the test areas. If taking stream channel density to represent terrain complexity, mean slope error could be regressed against DEM resolution (X) and stream channel density (S) at 8 resolution levels and expressed as (0.0015S2+0.031S-0.0325)X-0.0045S2-0.155S+0.1625, with a R2 value of over 0.98. Practical tests also show an effective result of this model in applications. The new development methodology applied in this study should be helpful to similar researches in spatial data uncertainty investigation.     

中亚土库曼斯坦绿洲土壤盐渍化动态演变评估

针对土库曼斯坦广泛存在的土壤盐渍化问题,选取达绍古兹州典型盐渍地为研究区,利用1990年、2000年和2010年的Landsat TM、ETM遥感影像,获取盐分指数（SI）和反照率（Albedo）构建SI-Albedo特征空间,利用土壤盐渍化遥感监测指数（SMI）,计算并划分研究区盐渍化等级。结果表明：（1）利用SMI指数对区域土壤盐渍化状况进行统计及定量分析,有利于大尺度范围的土壤盐渍化动态监测;（2）1990-2010年间研究区盐渍化程度持续加重,其中,重度盐渍地增加1 103.9 km²,增长了5.28%;中度盐渍地增加1 716.184 km²,增长8.21%;（3）地形及气候等自然因素对研究区土壤盐渍化过程有较大影响,盲目的垦荒、不合理灌溉等人为因素更加剧了研究区盐渍化的形成,使得盐渍化现象更加严重,导致盐渍地面积的不断扩大。     

地形异质性对天山山区气候的影响分析

地形具有高度的空间异质性,同一区域不同地形对该区的气候变化有着显著的影响,分析研究地形异质性对气候的影响具有十分重要的意义。基于天山山区DEM栅格图像资料和61个气象站点1961-2014年的气温和降水资料,运用空间分析、反距离权重插值法、偏最小二乘法和统计分析等方法,对该区域的地形异质性及其对气候的影响进行了相关研究。结果表明：（1）天山山区整体坡度大,其中中部与西南部的地形异质性指标值较高,其它地区的地形异质性值偏低。（2）从气候的空间分布来看,天山中部的气温较低,降水量丰富,其他区域的气温较高,降水量较少。（3）在地形异质性对气候影响方面,坡度对研究区气候的影响贡献最大,而地表粗糙度对研究区气候的影响最弱。