782
trend of area change could be described as a descending curve with the area decrease speeded up (for example
hydromorphic and mesohydromorphic ecosystems). The trend of area changes for other ecosystems is
described by an ascending curve with the decreasing rate of increase of area with time. The trend of the area
increase of saline-meadow ecosystem, for example, is described by function of the following form:
0.50 0.24
Y = 6.56(X[i] - 1961) - 2.22(X[i] - 1961) - 0.03.
Extrapolation of this trend on one-third of training time interval could be predict area of this ecosystem classe
on 10 years forward.
Mathematical modelling of the dynamics of the ecosystem combinations is more complicated but forecasting
on the basis of complex analysis is more correct. Formerly for ecological forecasting we used simple
Markovian chains. These simple Markovian chains were compiled from comparison of two sets of aerospace
surveys only. According to this procedure the simple transition matrix for all ecosystem classes during the
training time interval (M[l-2]) was multiplied by transposed vector of final state (V[2]) of each ecosystem classe
within the study area. As the result we received a prognosed vector of forecasted state on one time interval
forward (V[f]):
M[l-2] x V[2] = V[q.
In our study area of the Lower Amudarya delta the transition matrix M[1980-1985] is a training sequence of
the ecosystem areadynmamics for ecological forecasting on 5 years forward. Then, M[1980-1985] is multiplied
by vector of final state V[1985] and we receive the prognosed vector on 1990, i.e. V[1990]. After this, received
M[1985-1990] could be multiplied by V[1990] for receiving V[1995] (i.e. forecast for 1995), then likewise for
2000, etc. [Vinogradov, Popov, 1988].
At the present time taking into account the nonlinearity of the dynamic trends we prefer to use an
heterogeneous transition matrices. These heterogeneous transition matrices request more then two survey sets
for the same study area. For compilation of these heterogeneous transition matrices we used
photo-interpretation maps of three survey times 1975,1980, and 1985 which had been received from spacecraft
"Salyut-4, 6, and 7".
A normative forecast of the ecosystem dynamics to 2010 reveals the following area changes of all ecosystem
classes (Fig.l). The most rapid growth is predicted for desert (Xero) and saline (Halo) ecosystems. Only
these two extraarid ecosystems could occupy to 2010 near 70% of the whole area of the Amudarya delta and
will be increased by 2.3-3.5 times in comparison with 1985. In contrary, area of mesomorphic ecosystem
classes could drop to 5% of the delta and will be decreased by 3-9 (!) times. Some ecosystem classes will be
disappeared at near future (for example, hydromesomorpic meadow-swamps at 2000, mesoxeromorphic
meadows and forests at 2005). But two ecosystem classes will not change their area sufficiently. Area of
irrigated fields will be supported on level of near 13-14% by man's efforts. Then, predicted trend of area of
intermediate haloxeromorphic ecosystem classe will have a fluctuated form on the subclimax level.
Control of the Forecast
An experimental control of forecast is underway the procedure "epignosis". According to this procedure the
previous studied time interval was used as a training sequence of the ecosystem dynamics for forecast of the
ecosystem state on the recent time, which could be tested during the field control studies. In our area study
the transition matrix M[1975-1980] was used as training sequence for prediction of area changes on 1985
(tabl.2). Then, predicted areas of all ecosysytem classes V[1985] were tested during the ground thruth in 1985.
The comparison of predicted and tested areas in 1985 reveals mean error of forecast for 5 predicted years.
Mean error of forecast is 10.65% of the whole changed area for 5 predicted years. For more remote prediction
on future such errors will be larger. We estimated mean error on 10 predicted years near 16%, for 15 near
