@article{fdi:010074248,
  title = {{I}mpact of spatial input data resolution on hydrological and erosion modeling : recommendations from a global assessment},
  author = {{C}haplot, {V}incent},
  editor = {},
  language = {{ENG}},
  abstract = {{T}he need to precisely describe the characteristics of a landscape is well-known in mathematical modeling from different environmental disciplines. {B}ecause spatial input data, such as climate, relief and soil maps are costly to obtain, especially when large areas are considered, several research studies have investigated the extent to which the resolution of these can be reduced. {Y}et, a consensus has not been reached on the question of models' sensitivity to the whole range of spatial input data and for different environmental conditions. {T}his issue was illustrated with the analysis of existing results from 41 watersheds from 30 research studies using the {S}oil and {W}ater {A}ssessment {T}ool ({SWAT}). {B}ecause these studies were not consistent in the type of spatial input data considered and the range of resolutions, an application of {SWAT} was performed in a flat 2612 ha flat watershed of central {I}owa ({USA}) where the sensitivity of runoff ({R}), {NO}3-{N} ({N}) and sediment ({SED}) yields was tested for changes in the resolution of all the required spatial input data (digital elevation model: {DEM}: 20-500 m; n = 12; number of rain gauge: {NRAIN} from 1 to 13; n = 8; soil map: {SOIL}: 1/25,000-1/500,000; n = 3) and in the number of watershed sub-divisions ({NSW} from 4 to 115; n = 4). {A}t the flat watershed, a {C}anonical {C}orrelation {A}nalysis with 67.4% of data variance explained by the two first variates, revealed that {R} and {SED} predictions were affected, mostly by {NSW} (r = 0.95), followed by {SOIL} (r = 0.18). {N} loads were the most sensitive to {RAIN} (r = 0.76) and {DEM} (r = 0.41), followed by {SOIL} (r = 0.23) and {NSW} (r = -0.17). {T}he {K}olmogorov {S}mirnov statistic ({KS}), that describes the significance of resolution changes for a considered spatial input data, showed that the model's sensitivity was greater for {SSW} below 261 ha, for 30 < {DEM} < 100 m and across the whole range of {NRAIN}. {F}inally, the analysis of watersheds with different sizes and environmental conditions revealed that the minimum spatial input data resolution needed, to achieve accurate modeling results can be predicted from watersheds' terrain declivity and mean annual precipitation. {T}hese results are expected to help modelers weight the level of investment to be made in generating spatial input data and in subdividing their watersheds as a function of both watersheds' environmental conditions and desired level of accuracy in the output variables.},
  keywords = {},
  booktitle = {},
  journal = {{P}hysics and {C}hemistry of the {E}arth},
  volume = {67-69},
  numero = {},
  pages = {23--35},
  ISSN = {1474-7065},
  year = {2014},
  DOI = {10.1016/j.pce.2013.09.020},
  URL = {https://www.documentation.ird.fr/hor/fdi:010074248},
}