帮助 关于我们

返回检索结果

平缓地区地形湿度指数的计算方法
Computation Method of Topographic Wetness Index in Low Relief Area

查看参考文献23篇

文摘 地形湿度指数(topographic wetness index)可定量模拟流域内土壤水分的干湿状况.在流域的土壤及分布式水文模型等研究中具有重要的意义。但现有的地形湿度指数计算方法在应用于地形平缓地区时会得到明显不合理的结果。即在河谷地区内。地形湿度指数仅在狭窄的汇水线上数值较高,而在汇水线以外的位置则阶跃式地变为异常低的地形湿度指数值。本文针对此问题对地形湿度指数的计算方法提出改进:以多流向算法MFD-fg计算汇水面积.相应地以最大下坡计算地形湿度指数。再基于一个正态分布函数对河谷平原地区内的地形湿度指数进行插值处理。应用结果表明.所得地形湿度指数的空间分布不但能合理地反映平缓地区坡面上的水分分布状况,并且在河谷地区内地形湿度指数值也都比较高。其空间分布呈平滑过渡,因而整个研究区域的水分分布状况得到了比较合理的反映.
其他语种文摘 Topographic wetness index, which is designed for modeling the status ("dry" or "wet")of the soil moisture quantitatively, is an important index for both predictive soil mapping and distributed hydrological modeling in a catchment. Current methods for calculating topographic wetness index have evident problems when applied in low relief area. Outside the positions of narrow accumulation line with high topographic wetness index, the topographic wetness value of topographic wetness index should be high. This problem is caused by both the flow accumulation algorithm and the slope gradient used during computing the topographic wetness index. A new method for computing topographic wetness index is proposed in this paper to address this problem. Firstly, flow accumulation is calculated by a multiple flow direction algorithm (MFD-fg). Topographic wetness index is then computed by the flow accumulation and maximum downslope. The maximum downslope used in the computation of topographic wetness index is matched with the idea of both MFD-fg and topographic wetness index. Furthermore, a post-processing method is also proposed to compute the topographic wetness index in valley area. The topographic wetness index in the valley area is interpolated by a Gaussian function based on the value of the topographic wetness index on the nearest position on extracted flow accumulation line. The application in a small watershed shows that the method proposed in this paper can get a comparatively reasonable distribution of topographic wetness index for not only the hillslope but also the wide valley area. The value of topographic wetness index in valley area is averagely high and with a smooth transition, which reflects the natural status of the soil moisture in application area. In the future research, the method proposed in this paper will be evaluated by both artificial surfaces and the real applications.
来源 地理科学进展 ,2006,25(6):87-93 【核心库】
关键词 地形湿度指数 ; 平缓地区 ; DEM ; 多流向算法 ; 最大下坡 ; 插值
地址

中国科学院地理科学与资源研究所, 资源与环境信息系统国家重点实验室, 北京, 100101

语种 中文
文献类型 研究性论文
ISSN 1007-6301
学科 地球物理学
基金 国家自然科学基金资助项目 ;  中国科学院“百人计划”项目
文献收藏号 CSCD:2666972

参考文献 共 23 共2页

1.  Kirkby M J. Hydrograph modeling strategies. Process in Physical and Human Geography,1975:69-90 被引 2    
2.  O'Loughlin E M. Prediction of surface saturation zones in natural catchments by topographic analysis. Water Resour Res,1986,22(5):794-804 被引 19    
3.  Beven K J. A physically based variable contributing area model of basin hydrology. Hydro Sci Bull,1979,24(1):43-69 被引 281    
4.  Wolock D M. Topographic effects on flow path and surface water chemistry of the Llyn Brianne catchments in Wales. J Hydrol,1990,115:243-259 被引 3    
5.  Moore I. Soil attribute prediction using terrain analysis. Soil Sci Soc Am J,1993,57(2):443-452 被引 2    
6.  邓慧平. 地形指数的物理意义分析. 地理科学进展,2002,21(2):103-110 被引 46    
7.  孔凡哲. 基于地形特征的流域水文相似性. 地理研究,2003,22(6):709-715 被引 26    
8.  张彩霞. 基于DEM的地形湿度指数及其应用研究进展. 地理科学进展,2005,24(6):116-123 被引 30    
9.  Ambroise B. Towards a generalization of the TOPMODEL concepts:Topographic indices of hydrologic similarity. Water Resour Res,1996,32(7):2135-2145 被引 15    
10.  Quinn P. The In(α/tanβ)index:how to calculate it and how to use it within the TOPMODEL framework. Hydrol Process,1995,9:161-182 被引 36    
11.  熊立华. 利用DEM提取地貌指数的方法述评. 水科学进展,2002,13(6):775-780 被引 16    
12.  Güntner A. Modeling spatial patterns of saturated areas:An evaluation of different terrain indices. Water Resour.Res,2004,40 被引 1    
13.  Quinn P. The prediction of hillslope flow paths for distributed hydrological modeling using digital terrain models. Hydrol Process,1991,5:59-79 被引 76    
14.  Wolock D M. Comparison of single and multiple flow direction algorithms for computing topographic parameters. Water Resour Res,1995,31(5):1315-1324 被引 21    
15.  Pan F. A comparison of geographical information system-based algorithms for computing the TOPMODEL topographic index. Water Resour Res,2004,40:3069 被引 1    
16.  秦承志. 基于栅格DEM的多流向算法述评. 地学前缘,2006,13(3):91-98 被引 29    
17.  Sorensen R. On the calculation of the topographic wetness index:evaluation of different methods based on field observations. Hydrol Earth Sys Sci Discuss,2005,2:1807-1834 被引 1    
18.  孔凡哲. 一种地形指数计算方法在Topmodel洪水模拟计算中的应用. 水文,2003,23(3):16-19 被引 4    
19.  Hjerdt K. A new topographic index to quantify downslope controls on local drainage Water Resour. Water Resour.Res,2004,40:3130 被引 1    
20.  Burrough P A. High-resolution landform classification using fuzzy k-means. Fuzzy Sets and Systems,2000,113:37-52 被引 17    
引证文献 17

1 朱连奇 土壤侵蚀研究中的“3S”技术应用进展 地理科学进展,2008,27(6):57-62
被引 6

2 杨琳 运用模糊隶属度进行土壤属性制图的研究——以黑龙江鹤山农场研究区为例 土壤学报,2009,46(1):9-15
被引 27

显示所有17篇文献

论文科学数据集
PlumX Metrics
相关文献

 作者相关
 关键词相关
 参考文献相关

版权所有 ©2008 中国科学院文献情报中心 制作维护:中国科学院文献情报中心
地址:北京中关村北四环西路33号 邮政编码:100190 联系电话:(010)82627496 E-mail:cscd@mail.las.ac.cn 京ICP备05002861号-4 | 京公网安备11010802043238号