The drainage area is an important, non-local property of a landscape, which controls surface and subsurface hydrological fluxes. Its role in numerous ecohydrological and geomorphological applications has given rise to several numerical methods for its computation. However, its theoretical analysis has lagged behind. Only recently, an analytical definition for the specific catchment area was proposed (Gallant & Hutchinson. 2011 Water Resour. Res. >47, . ()), with the derivation of a differential equation whose validity is limited to regular points of the watershed. Here, we show that such a differential equation can be derived from a continuity equation (Chen et al. 2014 Geomorphology >219, 68–86. ()) and extend the theory to critical and singular points both by applying Gauss’s theorem and by means of a dynamical systems approach to define basins of attraction of local surface minima. Simple analytical examples as well as applications to more complex topographic surfaces are examined. The theoretical description of topographic features and properties, such as the drainage area, channel lines and watershed divides, can be broadly adopted to develop and test the numerical algorithms currently used in digital terrain analysis for the computation of the drainage area, as well as for the theoretical analysis of landscape evolution and stability.
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机译:流域是景观的重要非局部属性,可控制地表和地下水文通量。它在众多生态水文和地貌学应用中的作用已经产生了几种数值计算方法。但是,其理论分析却落后了。直到最近,才提出了针对特定集水区的解析定义(Gallant&Hutchinson。2011 Water Resour。Res。> 47 ,。()),并推导了一个微分方程,其有效性仅限于分水岭的规则点。在这里,我们证明了这样的微分方程可以从连续性方程中导出(Chen等人,2014 Geomorphology > 219 ,68–86。()),并将该理论扩展到临界点和奇点应用高斯定理并借助动力学系统方法来定义局部最小表面的吸引盆。研究了简单的分析示例以及在更复杂的地形表面上的应用。可以广泛采用对地形特征和特性(例如流域,河道线和分水岭划分)的理论描述,以开发和测试当前在数字地形分析中用于流域计算的数字算法以及用于景观演化与稳定性的理论分析。
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