基于Srtm-DEM与遥感的长白山基本地貌类型提取方法

基于中国1∶100万数字地貌制图工作,以吉林省长白山区为试验区,对基于Srtm-DEM与遥感提取基本地貌类型方法进行了探讨。研究表明,基于Srtm-DEM派生的各种模型对基本地貌类型自动提取具有很大的实效性:其中坡度3.5°是实现该区平地和山地宏观地貌单元自动提取的最佳断点,高程模型及起伏度模型相结合,可初步实现基本地貌类型的自动提取,其结果可很好的反应区域地貌宏观规律;在此基础上,基于30 m空间分辨率的遥感影像,综合运用区域地质、土地利用、植被、土壤等多地理要素信息及制图综合知识,以及地貌单元的完整性特征,以山脊线、坡折线和山麓线为地貌单元的标志线,基于地貌知识的专家修正,可获得研究区完整的基本类型地貌单元,实现了基于Srtm-DEM与遥感的基本地貌类型的智能化提取;最后,以研究区内1∶50万地貌图为准,对提取结果进行定性、定量评价分析表明,其提取总体精度达76%,面积相差较小;该方法在一定程度上改进了传统手工和野外调查为主的提取方法,实现了地貌信息的数字化、定位化及定量化,为全国1∶100万数字地貌信息提取与集成奠定了基础。     

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。     

不同地貌类型水土流失区的地面坡谱分析

坡度是影响水土流失的重要因素之一,然而坡度作为一种微观定量因子,并不能有效表达区域地形的总体特征。本研究采用地面坡谱统计分析方法,研究地形对水土流失的影响,并以福建省宁化县为例,选取5个不同地貌类型的典型水土流失区,通过均值、中位数等7个统计值对坡谱特征进行刻画,并与研究区的水土流失程度进行拟合分析。研究结果表明：1）丘陵和山地地貌类型分别具有特定形态的坡谱,反映了不同地貌类型的地形起伏差异,以及地表的破碎程度;2）从坡谱统计值与其水土流失程度商值的拟合曲线上,可以看出宁化县水土流失程度除与坡谱锋态不相关外,与其他统计值均相关,并且在水土流失越轻区域,水土流失程度对坡谱统计值的微小变化越敏感;3）坡谱蕴含丰富的地貌信息,有望较准确地量化地形对水土流失影响的程度。     

典型黄土地貌类型区的地形复杂度分形研究

黄土高原地貌形态与地形复杂度自南向北有序变化,构成了举世瞩目的独特的地理景观。选择陕西省南北剖面六个典型黄土地貌样区为基本实验区,以其1∶1万栅格DEM为数据源,探讨典型黄土地貌类型区的地形复杂度分形与空间分异特征。首先提出的元分维模型方法,以计算得到的DEM元分维值作为特征指标,研究样区的地形复杂度问题。这种通过滑动窗口的扩展分维分析方法,既可以用于分析该区域不同尺度下的地形复杂度变化情况,也可以探讨区域的局部单元复杂程度及其空间分布,从而不再局限于对全区域的单一分维评价。以此为基础,进一步应用元分维谱方法,研究地貌网格单元的元分维分级分布情况。实验结果表明:以绥德和延川为代表的黄土峁状丘陵沟壑区最为复杂,以宜君和甘泉为代表的梁状丘陵沟壑区居中,而以淳化为代表的黄土塬区和以神木为代表的风沙黄土过渡区最为平缓。实验进一步证明了扩展分形方法在黄土地貌研究中的可行性。     

面向DEM地形复杂度分析的分形方法研究

在基于栅格DEM数据的基础上,应用分形几何学方法,采用元分维模型理论,提出一种描述DEM地形复杂度的分形分析方法,并得出分析指标———地形分维指数(TFI)。实验证明,该指标可以有效描述栅格DEM数据反映的地形变化特征,分析窗口由小到大的规律性变化反映出地貌从微观到宏观的变化情况,因此其既可以作为对栅格DEM所描述地形进行评价的坡面因子,又可以作为基于DEM的地貌类型区自动划分的参照依据。     

模糊坡位信息在精细土壤属性空间推测中的应用

坡位的空间渐变特征影响着小流域及坡面尺度上的土壤、水文、地貌等现象和过程,因此对精细尺度下的地理建模(如土壤空间信息推理)有重要作用。虽然目前已有多种模糊坡位信息定量提取方法,但所得到的模糊坡位信息还缺乏实际应用。本文以精细尺度下的土壤属性空间分布推测为例,对此展开探索。应用模型假设:(1)在小流域内,地形因素主导着土壤属性空间分布的变化;(2)典型坡位上对应分布着典型的土壤属性值,土壤属性与坡位之间存在协同变化关系。据此建立以模糊坡位信息对各类典型坡位上土壤样点属性值的加权平均模型,推测土壤属性的空间分布。模型应用于黑龙江省嫩江流域一个地形平缓的小区(面积约60 km²),通过一个以坡位典型位置作为原型的模糊坡位定量方法提取5类坡位(山脊、坡肩、背坡、坡脚、沟谷)的空间渐变信息,对土壤表层有机质含量的空间分布进行推测。推测结果通过研究区70个土壤采样点进行评价,以推测结果与评价样点集之间的相关系数、平均绝对误差、均方根误差作为定量评价指标,与使用常用地形属性的多元线性回归模型推测结果进行对比。评价结果表明,仅使用极少建模点的加权平均模型的推测结果优于多元线性回归模型的推测结果。     

地貌面、地文期与地貌演化——从华北地貌演化研究看地貌学的一些基本理论

华北地貌的形成演化研究以传统地貌学理论戴维斯等的"地貌面"和"侵蚀旋回"理论为指导。研究表明,它基本适用于华北地貌的形成与演化;同时也发现了传统地貌学理论的不足。该文用华北地貌形成演化的实际资料弥补了这个不足,并进一步探讨了地貌形成演化理论的某些新观点。     

3S技术在抛物线沙丘形态特征研究中的应用

3S技术的发展为风沙地貌研究提供了新的方法和强有力的技术支持。基于GIS平台,利用差分GPS实测数据,通过空间插值生成DEM,可有效提取地形因子和形态参数,实现风沙地貌三维形态特征的定量化研究;结合高分辨率遥感影像,不但可以提取风沙地貌二维形态特征,还可以提取植被覆盖信息。该文以内蒙古库布齐沙漠典型抛物线沙丘为研究对象,探讨3S技术在沙丘形态特征研究中的应用,结果表明:该区沙丘平面形态呈U型,丘臂指向W;纵剖面上迎风坡较缓、背风坡较陡,横剖面不对称;沙脊线所夹中轴线走向为WNW-ESE,反映了盛行风或合成输沙方向;油蒿灌丛分布在背风坡、两翼及其间平坦地;在长期合成风的作用下,沙丘向前移动,丘臂间的油蒿灌丛发生阶段性的弧带状自然恢复。     

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。     

黄土高原数字地形分析研究进展

黄土高原数字地形分析以我国黄土高原为研究对象,基于该区域不同尺度DEM数据提取各类坡面地形因子及特征地形要素,并通过对各种地形因子和特征要素的自身特点、空间分异规律及各因子与要素之间的相互关系建立地学统计模型,从更深层次探讨黄土地貌演化及其空间分异规律,深化对黄土高原的认识。该文总结了黄土高原数字地形分析的基本理论与分析方法,从该区域的DEM数据模型、地形特征要素、地形信息图谱、地形纹理、沟壑信息图谱和地貌发育演化机理等方面对黄土高原数字地形分析的研究成果进行较全面地梳理与分析。可以看出,黄土高原数字地形分析已成为数字地形分析领域独具特色的研究方向,其中很多方法均已成为地貌计量学的重要研究手段。     

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.     

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.     

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。     

在降雨侵蚀中黄土地面坡度变化的高分辨研究

运用近景数字摄影测量方法,获得在不同人工降雨时段黄土模拟小流域高精度、高分辨率的DEM数据,并以地面坡度及其组合形态的变化为切入点,通过对比分析和理论验证,探讨黄土小流域降雨侵蚀过程中地面坡度变化特征,在更宏观空间尺度和高分辨的时间尺度上,揭示黄土地貌形成与发育特征。研究结果表明：1）在较好地维持黄土的土壤结构与抗蚀特征,较真实地模拟自然降雨的条件下,模拟流域地面的变化能很好地反映自然地面的发育进程。2）在降雨侵蚀过程中,黄土小流域地面坡度呈现持续性变化规律,平均坡度在地貌发育幼年期呈加速增长趋势,到了壮年期增长幅度呈递减性变化;坡度组合以侵蚀临界角度为轴点呈持续逆转变化,侵蚀临界坡度单元所占面积基本保持稳定。3）黄土地面坡度的变化,一方面受地表物质被侵蚀和迁移程度的影响,另一方面,也是沟间地、沟坡地和沟底地空间面积重新分配的结果。     

黄土丘陵沟壑区坡面产流能力及影响因素研究

坡面是黄土高原土壤侵蚀的重要来源,本文以团山沟流域的7个径流场9年的降雨－径流事件,对不同坡面和降雨特征下径流系数随坡面的变化进行了研究。结果表明,研究区存在降雨强度大、持续时间短的A型雨、降雨强度小持续时间长的C型雨以及居于二者之间的B型雨。不同雨型下坡面产流能力大小为A型雨>B型雨>C型雨,而产流尺度效应则为C型雨>B型雨>A型雨。坡度一定,A型雨下随着坡面长度增加产流能力先增加后减小,径流系数峰值出现在坡长为40m的坡面上,B型和C型雨坡面产流能力随坡面长度的增加而增加;坡长一定,峁坡区坡面产流能力随着坡度的增加而增加;A型雨下沟坡产流能力最小,而在B型和C型雨下,坡面产流能力相对有所提高。     

黄土高原植被恢复潜力研究

黄土高原从1999年开始大规模退耕还林（草）,植被覆盖发生了较大变化,对黄土高原植被恢复现状和恢复潜力进行评估具有重要意义。本文使用1999-2013年SPOT VEG NDVI数据,采用线性回归、Hurst指数分析法、统计学方法以及地理空间分析技术,对黄土高原植被恢复状况和潜力进行了探讨。结论主要为：① 1999年退耕还林（草）以来,黄土高原植被覆盖度呈显著上升趋势,黄土高原三分之二地区的植被将会持续改善;② 植被响应曲线分析表明,黄土区植被覆盖度和干旱指数呈显著的指数关系,且缓坡相关性大于陡坡。土石山区植被响应函数为线性函数,相关系数下降;③ 整个黄土高原地区平均植被恢复潜力为69.75%。植被恢复潜力值东南高而西北低,黄土高原东南地区植被恢复状况较好,其植被恢复潜力指数较小,而植被恢复潜力指数较高的地区主要为北方风沙区及西部丘陵沟壑区;④ 不同降水量条件下,植被恢复速度差别显著,其中降水量在375~575 mm之间的地区,植被恢复最快。植被恢复措施应该“因水制宜”,避免因造林带来的土壤干化加剧。研究结果以期为黄土高原生态文明建设提供科学支撑。     

黄土高原气象干旱和农业干旱特征及其相互关系研究

选择标准化降水指数（SPI）和植被状态指数（VCI）分别作为评价黄土高原气象干旱和农业干旱的指标,使用干旱频率和Sen斜率分析了黄土高原地区干旱的分布特征与变化趋势,并探讨了气象干旱与农业干旱的相关性。结果表明：① 黄土高原西部干旱频率总体上高于东部。气象干旱和农业干旱变化趋势在空间上表现有所不同,黄土高原西部、北部气象干旱呈不显著减缓趋势,东部和南部呈不显著加重趋势,但绝大部分地区的农业干旱呈减缓趋势,尤其是400 mm等降水量一线两侧区域。② 季节上,黄土高原夏季和秋季气象干旱频率较高,春季和冬季气象干旱频率相对较低。黄土高原农业干旱频率春季最高,夏季其次,VCI对农业干旱实时监测的适用性更强。③ 不同季节,农业干旱滞后气象干旱的时间长短不同,冬季滞后约2个月,春季滞后约1个月,夏季和秋季滞后少于1个月。黄土高原一熟制种植区的SPI-12值与VCI值具有较好的正相关性。研究结果可以为黄土高原的干旱监测和预警、干旱区划以及干旱灾害风险评估提供科学依据。     

陕北黄土高原正负地形研究(英文)

The Loess positive and negative terrains (P-N terrains), which are widely distributed on the Loess Plateau, are discussed for the first time by introducing its characteristic, demarcation as well as extraction method from high-resolution Digital Elevation Models. Using 5 m-resolution DEMs as original test data, P-N terrains of 48 geomorphological units in different parts of Shaanxi Loess Plateau are extracted accurately. Then six indicators for depicting the geomorphologic landscape and spatial configuration characteristic of P-N terrains are proposed. The spatial distribution rules of these indicators and the relationship between the P-N terrains and Loess relief are discussed for further understanding of Loess landforms. Finally, with the integration of P-N terrains and traditional terrain indices, a series of un-supervised classification methods are applied to make a proper landform classification in northern Shaanxi. Results show that P-N terrains are an effect clue to reveal energy and substance distribution rules on the Loess Plateau. A continuous change of P-N terrains from south to north in Shaanxi Loess Plateau shows an obvious spatial difference of Loess landforms and the positive terrain area only accounted for 60.5% in this region. The P-N terrains participant landform classification method increases validity of the result, especially in the Loess tableland, Loess tableland-ridge and the Loess low-hill area. This research is significant on the study of Loess landforms with the Digital Terrains Analysis methods.     

Remote-sensing data reveals the response of soil erosion intensity to land use change in Loess Plateau,China

Developing an effective approach to rapidly assess the effects of restoration projects on soil erosion intensity and their extensive spatial and temporal dynamics is important for regional ecosystem management and the development of soil conservation strategies in the future. This study applied a model that was developed at the pixel scale using water soil erosion indicators (land use, vegetation coverage and slope) to assess the soil erosion intensity in the Loess Plateau, China. Landsat TM/ETM+ images in 2000, 2005 and 2010 were used to produce land use maps based on the object-oriented classification method. The MODIS product MOD13Q1 was adopted to derive the vegetation coverage maps. The slope gradient maps were calculated based on data from the digital elevation model. The area of water soil-eroded land was classified into six grades by integrating slope gradients, land use and vegetation coverage. Results show that the Grain-To-Green Project in the Loess Plateau worked based on the land use changes from 2000 to 2010 and enhanced vegetation restoration and ecological conservation. These projects effectively prevented soil erosion. During this period, lands with moderate, severe, more severe and extremely severe soil erosion intensities significantly decreased and changed into less severe levels, respectively. Lands with slight and light soil erosion intensities increased. However, the total soil-eroded area in the Loess Plateau was reduced. The contributions of the seven provinces to the total soil-eroded area in the Loess Plateau and the composition of the soil erosion intensity level in each province are different. Lands with severe, more severe and extremely severe soil erosion intensities are mainly distributed in Qinghai, Ningxia, Gansu and Inner Mongolia. These areas, although relatively small, must be prioritised and preferentially treated.