Full text: Proceedings, XXth congress (Part 7)

  
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
between these two packages, which do not have a common user 
interface. The advantage of this approach is that redundant 
programming can be avoided. Map input, data handling, spatial 
analysis, and map output capabilities of GIS are used for the 
preparation of the land resource database required by the EPIC. 
The EPIC processing is outside of the GIS. 
3.3 Combining Spatial EPIC Model and MODIS LAI 
Product 
The integration of MODIS LAI product with the spatial EPIC 
model is achieved by using two distinct methods. The first 
method is the updating of LAI value in EPIC model. The LAI 
value simulated by EPIC model in some key stage of crop 
growth is updated by using the MODIS LAI product directly. In 
the second method, the time series of MODIS LAI product is 
used to calibrate the spatial EPIC model. Calibration was 
performed to adjust some model parameters: the maximum 
potential LAI of the crop; the leaf area decline rate (RLAD); 
and the time when green LAI begins to decline (DLAI). 
4. MATERIALS AND DATA REQUIREMENTS 
The MODIS LAI product and some important input data for 
EPIC model, such as weather, soil, and management data, are 
introduced here. 
4.1 Weather Data 
EPIC uses a stochastic weather generator to generate daily 
weather from monthly climatic parameters. The basic data set 
needed for each site is a record of monthly maximum and 
minimum temperatures, precipitation, Standard Deviation (S.D.) 
of maximum daily air temperature, S.D. of minimum daily air 
temperature, S.D. of daily precipitation, skew coefficient for 
daily precipitation, probability of wet day after dry day, and 
probability of wet day after wet day. The weather data from year 
1981 to 1990 in this study is from Global Daily Summary 
produced by National Climatic Data Center from 256 available 
terrestrial stations in China. This history weather data were used 
to validate the spatial EPIC model. When the MODIS LAI 
product is integrated with the spatial EPIC model in order to 
estimate winter wheat yield of North China in 2003, data from 
more than 200 weather stations of North China will be applied. 
Kriging method aided by climatologically and topographically 
interpolation with quality control model is applied (Tan et al. 
2002). 
4.2 Soil Data 
EPIC can accept up to 20 parameters for 10 soil layers. 
However, only a minimum of seven parameters is required: 
depth, percent sand, percent silt, bulk density, PH, percent 
organic carbon, and percent calcium carbonate. Other soil 
parameters can be estimated by EPIC itself. Therefore only 
these seven parameters in four layers are applied in this study. 
The soil-depth intervals are 0-0.1, 0.1-10, 10-30, 30-50, and 
50-80 cm. All soil databases are provided by the Global Soil 
Task cooperated by the Data and Information System (DIS) 
framework activity of the International Geosphere-Biosphere 
Programme (IGBP) (Scholes et al. 1995). The highest spatial 
resolution of this database is 5 min x 5 min (about 6km x 6km). 
4.3 Management Data 
EPIC requires detailed descriptions of management practices, 
These descriptions must specify the timing of individual 
operations either by date or by fraction of the growth period (ie, 
by heat units). EPIC allows the user to simulate complex crop 
rotations with a variety of irrigation, fertilizer, pesticide, and 
tillage control options. There are two options for irrigation and 
fertilizer scheduled application in the EPIC program: manually 
and automatically. Only the manual option is applied in the 
spatial EPIC model. Some parameters of manual mode are 
described in details in Table ! (Huang et al. 2001). The land use 
map at the scale of 1:1,000,000 is made by the Australian 
Center of the Asian Spatial Information and Analysis Network, 
Griffith University. 
Table 1. The Operation Parameters of Winter Wheat — Summer 
Corn Rotation for EPIC Model in North China 
  
  
  
SUMMER CORN WINTER WHEAT 
Date Operation Volume Date Operation Volume 
Jun. 20 Irrigation 40mm Oct. 8 Irrigation 40mm 
Jun.20 Fertilizer — 72kg/ha' Oct. 8 Fertilizer 72kg/ha 
Jun. 23 Planting Oct. 8 Fertilizer ^ 5Skgha” 
Aug.10 Fertilizer — 48kgha | Oct.10 Planting 
Sep.28 Harvest Apr.10 Irrigation 100mm 
Apr.20 Fertilizer ^ 48kg/ha 
Mayl0 Irrigation 100mm 
Jun.18 Harvest 
  
  
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Note: “*” means the application amount of 10076 nitrogen in chemical fertilizer. 
** means the application amount of 10096 phosphorus in chemical fertilizer. 
4.4 MODIS LAI Product 
The MODIS LAI-FPAR algorithm is based on three- 
dimensional radiative transfer theory and developed for 
inversion using a look-up table (LUT) approach (Myneni et al. 
2002). According to the algorithm, global vegetation is 
classified into six canopy architectural types: grasses and cereal 
crops, shrubs, broadleaf crops, savannas, broadleaf forests and 
needle leaf forests. The structural characters among these 
biomes, such as the horizontal (homogeneous vs 
heterogeneous) and vertical (single- vs. multi- story) 
dimensions, canopy height, leaf type, soil brightness and 
climate (precipitation and temperature), are used to define 
unique model configurations, including some fixed parameter 
values appropriate for the biome characteristics. LUTS are then 
generated for each biome by running the model for various 
combinations of LAI and soil type. The algorithm ingests 
atmospherically corrected bi-directional reflectance factors, 
their uncertainties and corresponding sun-view geometries. It 
compares the observed reflectances to comparable values 
evaluated from model-based entries stored in LUTs and derives 
the distribution of all possible solutions. When this method fails 
to identify a solution, a back-up method based on relations 
between the normalized difference vegetation index (NDVI) 
and LAI and FPAR is used. 
The current MODIS 1-km LAI-FPAR product is retrieved from 
the reflectances of two bands (648 and 858 nm) and on an 8-day 
compositing period. The product also includes extensive quality 
control (QC) information regarding cloud and data processing 
conditions. During each 8-day period, the highest-quality LAI 
and FPAR are selected. These data are further composited over 
4 (or 3) consecutive 8-day periods to produce monthly data 
(Tian et al. 2004). This study uses the MODIS LAI product 
from Sep. 2002 to Jul. 2003, which was downloaded from the 
home page of Myneni's Climate and Vegetation research group 
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