IAPRS & SIS, Vol.34, Part 7, “Resource and Environmental Monitoring”, Hyderabad, India,2002
data obtained from India Meteorological Department (IMD)
Weekly Weather Reports for the years 1977 onwards during
November - March (rabi) period. Dadhwal (1989) and Saini and
Dadhwal (1986) have highlighted the significant contribution of
temperature on wheat yield in India. A trend was fitted to this
yield series. Deviations from trend were regressed with
fortnightly minimum and maximum average temperatures of
rabi (Nov -Mar) season (Vyas et al. 1999).
Early wheat yield forecast in February end/March beginning
were obtained using truncated regression models, which used
data upto Ist fortnight of February. The final pre-harvest wheat
yields were based on the yield models developed using weather
data upto February end. The yield equations were developed at
meteorological sub-division level. The weighting factors, based
on contribution of meteorological subdivision to state acreage,
were used wherever necessary to arrive at the state yield
forecasts. The final pre-harvest yield models and forecasts for
2001-02 are given in Table 3.
4. RESULTS
4.1 ARIMA Analysis
Historical national wheat production series for 1950-51
onwards was taken from a publication of Directorate of
Economics and Statistics. For the time series analysis, method
developed and described by Box and Jenkins (1976), namely
Auto-Regressive Integrated and Moving Average (ARIMA)
analysis was followed. On the basis of analysis of auto-
correlation and partial auto-correlation functions, ARIMA
(1,1,0) was identified for wheat production series. Since this
method does not use any in-season information/input/data, this
formed an a-priori (or Fo) forecast at the beginning of crop
season. The performance of this type of models for last six years
(1995-96 to 2000-01) had deviations of 5.5496, -6.58%, 2.65%,
—2.96%, —6.04% and 9.22%, respectively.
Table 3 : Temperature based yield models and yield forecasts
for 2001-02 using weather data upto March
N,D,J,F,M stand for months from November to March;
Met. MODEL , [YPRED_ YPRED
STATE |. bdiv| PARAMETERS | |. M..|C 79]. s. |CYC9
D2TN, D2TX,
BIHAR| 9 |. orn | 9953 | 2200 | 72 2201 | 72
HAR. | 13 D2TN 0.962 | 4307 | 487 | 4307 | 487
PUN. | 14 | DITX,F2TN | 0972 | 464 | 46 | 464 | 46
MP. | 19 | NITX;D2TN| 032 | 204 | 864 | 1854 | 7.65
MP. | 20 | J2TX,FITN | 0.765 | 1.177 | 126
JITX, F2TX
RAJ. | 18 : '| 0957 | 2.265 | 10.92 | 2.265 | 10.92
MITN, M2TX
UP. 10 | N2TN,FITN | 0.938 | 2.488 | 841 | 2.804 | 5.15
UP. 11 | N2TN,JITX | 095 | 3241 | 642
1 and 2 are first and second fortnights respectively;
TX: Maximum Temperature;
TN: Minimum Temperature;
CV is coefficient of variation in percentage;
YPRED S is predicted yield for state;
YPRED M is predicted yield for meteorological subdivision;
Com. R? is combined coefficient of determination.
4.2 Rabi- Cropped Area
Since the early crop forecasts conflict with optimal bio-window
for crop identification, the early assessment of total rabi sown
area was incorporated. However, the existence of cropped area
can be detected and mapped. Rabi crop area for the wheat study
districts was attempted for the first time during 1997-98 season.
If two or more cloud free data since mid-December were
available, it was possible to detect large anomalies and give rabi
cropped area using multi-date IRS WiFS data.
4.3 Early And Final Wheat Production Forecast
Early forecast of wheat production was planned to be made by
end of February. The IRS WiFS data upto middle of Feb were
used for wheat area estimation. The fortnightly minimum and
maximum average temperatures upto Jan - end / Feb 15 at
meteorological sub-divisions were used to develop truncated
regression based yield models. The current year's temperature
data were used to forecast the yields.
The final national wheat production pre-harvest forecast was
targeted to be given on March 31. The harvest of wheat starts
around April 15 in Northwest India, which is major wheat
production belt. The final pre-harvest forecasts used multi-date
IRS WiFS data upto March 15 and weather data upto Feb end.
The consolidated final forecasts across the years are given in
Table 4. It can be seen that during last four seasons, RS based
forecasts deviated from post-harvest estimates by 0.9, 42.1, -
5.4 and +0.1 Mt only.
Table 4: The results of final production since 1996 are
summarized in the following table.
Your NWPF (RS) DES
ACR(Mha) PRO D(Mt) | ACR(Mha) PROD(Mt)
1995-961 27.261 | ----- 25.01 62.1
1996-97 26.093 64.979 25.89 69.35
1997-98 26.2 67.27 26.7 66.35
1998-99| 26.603 72.876 27.4 70.78
70.10(M ar)
1999-00 26.884 70.203 26.74 to
75.6 (Jun)
2000-01 24.291 68.373 24.96 68.46
73.53 (Apr
2001-02} 26.423 73.568 25.8 05, 2002)
5. SPATIAL ANALYSIS OF CROP GROWTH
DIFFERENCES
The difference of vegetation index of comparable dates
provides information about crop status vis-à-vis previous
season. This type of analysis over multiple dates during
previous years has been useful in identifying crop shifts (Rajak
et al., 2000; Rajak et al., 2002), changes in sowing dates and
vigour of crop. Similar analyses were carried out from time to
time and were communicated to Ministry of Agriculture,
Government of India, along with results. The crop assessments
cover change in extent and vigour of the crop and major
observations in previous years include (a) late sowing in parts
of Bihar during 1997-98, (b) early sowing in parts of Haryana
during 1999-2000, (c) decrease in mustard area in East
Rajasthan during 1999-2000, (d) mustard -wheat crop shift in
parts of Rajasthan during 2000-01, and (e) decrease in wheat
area due to drought in Western MP during 2000-01. The
consolidated highlights across the years are given in Table 5.
