COMPARING SPATIAL INTERPOLATION METHODS FOR CMIP5 MONTHLY PRECIPITATION AT CATCHMENT SCALE
By: Md Monowar Hossain
.
Contributor(s): Garg, Nikhil.
Publisher: Roorkee Indian Water Resources Society 2021Edition: Vol,41(2),Apr.Description: 28-34p.Subject(s): Civil EngineeringOnline resources: Click here
In:
Journal of indian water resource societySummary: Use of Regional Climate Models (RCMs) is prevalent in downscaling the large scale climate information from the General Circulation
Models (GCMs) to local scale. But it is computationally intensive and requires application of a numerical weather prediction model. For
more straightforward computation, spatial interpolation are commonly used to re-gridding the GCM data to local scales. There are many
interpolation methods available, but mostly they are chosen randomly, especially for GCM data. This study compared eight interpolation
methods (linear, bi-linear, nearest neighbour, distance weighted average, inverse distance weighted average, first-order conservative,
second-order conservative and bi-cubic interpolation) for re-gridding of CMIP5 decadal experimental data to a catchment scale. For this,
CMIP5 decadal precipitation data from three GCMs were collected and subset for Australia and then re-gridded to 0.05 degree spatial
resolution matching with the observed gridded data. The re-gridded data were subset for Brisbane catchment in Queensland, Australia and a
number of skill tests (root mean squared error, mean absolute error, correlation coefficient, Pearson correlation, Kendal’s tau correlation
and index of agreement) were conducted for a selected observed point to check the performances of different interpolation methods.
Additionally, temporal skills were computed over the entire catchment and compared. Based on the skill tests over the study area, the second-
order conservative (SOC) method was found to be an appropriate choice for interpolating the gridded dataset
| Item type | Current location | Call number | Status | Date due | Barcode | Item holds |
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Articles Abstract Database
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School of Engineering & Technology (PG) Archieval Section | Not for loan | 2023-0946 |
Use of Regional Climate Models (RCMs) is prevalent in downscaling the large scale climate information from the General Circulation
Models (GCMs) to local scale. But it is computationally intensive and requires application of a numerical weather prediction model. For
more straightforward computation, spatial interpolation are commonly used to re-gridding the GCM data to local scales. There are many
interpolation methods available, but mostly they are chosen randomly, especially for GCM data. This study compared eight interpolation
methods (linear, bi-linear, nearest neighbour, distance weighted average, inverse distance weighted average, first-order conservative,
second-order conservative and bi-cubic interpolation) for re-gridding of CMIP5 decadal experimental data to a catchment scale. For this,
CMIP5 decadal precipitation data from three GCMs were collected and subset for Australia and then re-gridded to 0.05 degree spatial
resolution matching with the observed gridded data. The re-gridded data were subset for Brisbane catchment in Queensland, Australia and a
number of skill tests (root mean squared error, mean absolute error, correlation coefficient, Pearson correlation, Kendal’s tau correlation
and index of agreement) were conducted for a selected observed point to check the performances of different interpolation methods.
Additionally, temporal skills were computed over the entire catchment and compared. Based on the skill tests over the study area, the second-
order conservative (SOC) method was found to be an appropriate choice for interpolating the gridded dataset
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