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Minimum temperature mapping Minimum temperature mapping in complex terrain for fruit frost in complex terrain for fruit frost
warningwarning
Jin I. YunKyung Hee University
Suwon, Korea
Spatial Interpolation = Objective Analysis Optimum Interpolation
Model for Tmin (~1km)
Ti : observed temperature at station 'i', (synoptic)di : distance from the site to station 'i', z : elevation of the site zi : elevation of the station 'i'
Γ : temperature change per unit change in the elevation ε : interpolation error
Inverse Distance Weighting (IDW)
Elevation Correction (lapse rate)
Urban Heat Island Correction
Choi et al.(2003) J. Appl. Meteorol. 42:1711-1719
January Tmin of South Korea (30 year normal, 1km resolution)
- Elevation correction
- UHI correction
Tmin on January 6, 2003
1 km
1 km
Scope
• Description of a spatial interpolation scheme incorporating local topography
• Applying this scheme to production of gridded minimum temperature data
• Combining this scheme with phenology model for fruit frost warning in spring
Tmin at Synop Station
Z0
Dry Adiabatic Line
Z2
Z1
Thermal Belt Effect
Cold Air Effect
Tmin model at landscape scale
E1 : correction for thermal belt effectE2 : correction for cold air accumulation effect
Study Area
Determining Inversion Cap Height and Strength for Quantifying Thermal Belt Effect
0
100
200
300
400
500
600
6 8 10 12 14
TEMPERATURE,degC
ALTI
TUD
E, m
200
300
400
800
Correction for Thermal Belt Effect
• Flow of Cold Air
• Flow Direction
• Flow Accumulation
84
Searching for Relationship between Tmin and Topographic Cold Air Accumulation Potential
Elevation Contour (vector)
Digital Elevation Model : DEM (raster)
Potential Flow Accumulation
Regression Analysis
1. Produce temperature map by applying the conventional model to DEM of the study area
2. Extract the estimated – measured temperature deviation at 8 HOBO sites
3. Extract the flow accumulation at 8 HOBO sites (zonal averages of cell radius from 1 to 10)
4. Regress the temperature estimation error to Log 10 of zonal averages of flow accumulation
Best Fit Equation
Temperature estimation error at observation site is linearly related to log10 of Flow Accumulation Potential
y = 0.9879x - 0.3432
R2 = 0.7808
0 1 2 3 4
LOG(FA)
3
2
1
0
4
5
Temperature Estimation Error, C
Potential Error from Cold Air Accumulation
R and Rmax : daily temperature range
FA5 : 5 cell average flow accumulation
Tmin model at landscape scale
Validation at Hydrologic Units (watershed)
-15
-10
-5
0
5
10
-15 -10 -5 0 5 10
Observed Tmin, C
Est
imat
ed T
min
, C
OLD
NEW
Winter 04/05, Baikgu Vineyards
RMSE=2.4
RMSE=1.5
Application : Fruit Frost Warning
1. Flowering date estimation by a phenology model which requires daily Tmin and Tmax (Tmax estimated by BioSIM of Canadian Forest Service) since last fall
2. Site-specific Tmin for tomorrow morning based on official Tmin forecasts at nearby synoptic stations
FloweringDate ofPear
As of
21 May
Conclusion• Potential effects of cold air accumulation and
inversion profile on minimum temperature were added to the large area estimation model
• This new interpolation scheme was successful in estimating minimum temperature mapping at landscape scale
• Combination with a phenology model showed a strong feasibility for development of a site-specific frost warning system
