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Spatial Interpolation of monthly precipitation by Kriging method

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1 Spatial Interpolation of monthly precipitation by Kriging method

2 Kriging method Kriging is one of the spatial interpolation algorithm and falls within the field of geostatistics. Kriging is known to be more realistic spatial behavior of the climate variables. Semivariogram - The fundamental tool of kriging - This concept explains how quickly spatial autocorrelation falls off with increasing distance. range sill distance semivariance nugget

3 Types of Kriging Ordinary kriging
- uses a random function model of spatial correlation to calculated a weighted linear combination of the available samples to predict the response for an unmeasured location. Simple kriging Universal kriging Cokriging

4 Kriging analysis example
Compare Kriging method with and without considering elevation as a trend. Find the best Kriging model in semivariogram. Choose the best method and do spatial interpolation of monthly precipitation: 45 COOP stations from 1968 to 2007. Produce 1km resolution spatially interpolated precipitation map for each time step. Calculate the mean precipitation of each month in Yadkin river basin

5 Study Area: Yadkin River Basin
Location: western NC Area: 17,775 km2 Dataset for analysis : monthly scale data from 1968 to 2007 1) precipitation: approximately 45 COOP stations around Yadkin river basin area 2) stream discharge: USGS #

6 Kriging trend: Elevation
The relationship between elevation (m) and annual precipitation (mm) 45 COOP stations Period: 1968~2007 Positive precipitation trend with elevation

7 Semivariogram with and without trend

8 Semivariogram with trend
"ML“: Maximum Likelihood "REML“: Restricted Maximum Likelihood parameter estimation “ML matern” is the best fitted correlation function for both jan00 and feb00 (with the lowest AIC and maximum likelihood value).

9 Kriging method comparison (1) semivariogram
Without topographic trend “Power” Model With topographic trend “ML Matern” Model

10 Kriging method comparison (2) visualization (1km resolution)
w/o trend -Mean: , SD:33.27 With trend -Mean: , SD: 34.32

11 Kriging method comparison (3) error analysis
Comparison between observed precipitation and interpolated precipitation

12 Kriging result example (1)
Interpolation of monthly precipitation of 1998 using Ordinary Kringing with trend

13 Kriging result example (2)
Jul. 1975 -The most spatially heterogeneous - Mean: - SD: 82.71 Oct. 2000 - The most spatially homogeneous - Mean: 0.30 - SD: 0.22

14 Kriging error analysis (1)
Step 1: Monthly interpolations are sampled at the location of each precipitation stations. Step 3: Aggregate monthly data to annual scale both observed and interpolated data. Step 4: Linear regression between observed and interpolated data.

15 Kriging error analysis (2)
Slope R2 Available stations 1968 0.9979 0.9932 40 1969 0.9999 0.9901 41 1970 1.0005 0.9708 1971 0.9996 0.9896 1972 0.9994 0.9804 36 1973 0.9965 0.9192 35 1974 0.9998 0.9806 37 1975 1.0001 0.9780 38 1976 0.9993 0.9667 1977 0.9988 0.8974 1978 1.0000 0.9871 1979 1.0010 0.9554 39 1980 1.0030 0.9925 1981 1982 0.9963 0.8196 1983 0.9958 1984 0.9990 0.9364 1985 0.9933 1986 0.9748 1987 0.9989 0.9771 Slope R2 Available stations 1988 0.9975 0.7924 38 1989 1.0001 0.9798 37 1990 1.0013 0.9712 1991 0.9994 0.9742 1992 0.9995 0.9745 32 1993 0.9937 0.8859 1994 0.9993 0.9862 1995 0.9997 0.9635 28 1996 0.9979 0.9716 31 1997 0.9985 0.9945 34 1998 1.0009 0.9955 1999 1.0003 0.9681 30 2000 0.9944 0.8853 2001 1.0094 0.8950 2002 1.0004 0.9583 35 2003 1.0046 0.9338 2004 1.0063 0.9071 2005 0.8121 2006 1.0039 0.8949 33 2007 1.0166 0.8370 18

16 Monthly precipitation in Yadkin river basin (1968~2007)
- Mean value of interpolated precipitation data Standard deviation of precipitation within basin : 0.22 ~ 82.71

17 Conclusion Kriging interpolation considering elevation as a trend is better fitted than without trend method. Ordinary Kringing with elevation as a trend produces spatially well interpolated precipitation data. The interpolated precipitation data by this method can be useful input data for hydrologic modeling, especially distributed model.

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