Geoscience Reference
In-Depth Information
Table 5.18 The ESPAP software
Identi
er of software
product
Characteristic of software product
CSII
Calibration and scaling of input information
IDF
Input data
ltration
STA
Spatial-temporal agreement of various types of data
SIOD
Spatial interpolation of observational data and formation of spatial
images
DR
Data restoration
GTM
Gauss-type model
ETM
Euler-type model
CSDB
Choice of the spatial digitization grid and transfer to block modeling
RFDB
Removal from data base of information needed for modeling
ASI
Modeling the processes of pollutants
'
transport due to atmosphere-sea
interaction
APS
Modeling the processes of pollutants
'
transport with due regard to
functioning of the atmosphere-plant-soil system
MSF
Model of sulphur
fl
fluxes in the environment
CPMR
Cartographic presentation of modeling results
AMD
Analysis of modeling data and their visualization with MCL levels
taken into account
UI
User interfaceInformation
fluxes in the environment
MOB Model of oxygen balance in the natural-anthropogenic medium
MCC
Model of CO
2
cycle in the environment
CI Control and interaction of the ESPAP units
DMP Decision making procedure based on sequential analysis method
FOI Formation of output information
MCL is maximum (permissible) concentration level
MNF
Model of nitrogen
fl
sensors, lines of information communication, transported standard and non-standard
accumulators of observational data, direct input of data from the keyboard or
another compatible input unit. The base version of ESPAP is calculated for the
latter case. Switching of ESPAP to other regimes requires additional software
elements, adjusting the medium and providing its transformation into the
file unit.
The interaction between all elements of the ESPAP is schematically shown in
Fig.
5.20
.
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