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Winter Semester 2018/19
Modelling and Simulation of Environmental Pollution OM2056
lectures
First The essence of modeling and simulation
Second Modeling and simulation of pollutants in hydrological systems
3rd Concepts of mathematical modeling
4th Elements of the mathematical model
5th The criteria for allocation of hydrological models
6th Modeling and simulation of transport of pollutants in the aquatic environment
7th Overview of models of environmental pollution of soil
8th The use of multivariate statistical methods in simulation and modeling of pollutants in the environment
9th The use of expert systems and artificial neural networks in simulation and modeling of pollutants in water and soil
10th The importance of modeling and simulation in the monitoring and protection of the environment and ecology
Laboratory specialist
First Analysis and identification of the fundamental processes in surface waters
Second Create a database for model input
3rd Construction of the numerical model of the river basin
4th Building a model of surface runoff
5th Construction of a static spatial model of pollution in watercourses and by simulation. simulation scenario assumed
6th Construction of a static model of the spatial distribution of contaminants in surface soil
7th Create process models related to pollution of the environment with the use of certain methods of statistical inference
8th Understanding the basis of FA and PCA methods for modeling of environmental pollution
9th Learn the basics of CA and AAN methods for modeling of environmental pollution
10th Interpretation of the results of modeling and simulation.
(in Polish) Rodzaj przedmiotu
Course coordinators
Learning outcomes
Students define the concept of modeling and simulation,
lists and explains the hydrological models, and models for transport of pollutants in the environment
discusses the use of multivariate models in the modeling and simulation of environmental pollution
properly analyze and identify the basic processes in the natural environment
properly perform spatial database and static models of pollution in the watercourse and the land
interprets the results of calculations of multivariate statistical analyzes
can work in a team.
Assessment criteria
specialist workshop:
The assessment of adequate (3.0), the student:
First Know how to properly raise and adopt data to build databases and models.
Second Mastered the basics of modeling and simulation.
3rd Performs well each database and static spatial distribution patterns of pollutants in water and soil.
The assessment of good (4.0), the student:
4th Meets 1-3 points.
5th Correctly interprets and explains the spatial distribution of static models of pollution.
6th He can perform additional models (eg, surface runoff), extending the functionality of the already performed.
For a very good student (5.0):
7th Meets 1-6 points.
8th It can take additional opportunity program for modeling and simulation (eg, different interpolation methods - kriking, minimum curves, triangulation).
9th He can simulate the spatial migration of contamination by pre-established script.
Ratings of 3.5 and 4.5 will get students who meet the appropriate requirements of the points 1-3 and 4-6 in a very good partial, or in addition meet the requirements of a higher level.
lecture
Written test consists of 10 questions that verify learning outcomes-EK2 and EK1 EK3. Questions are rated on a scale 2,0-3,0-3,5-4,0-4,5-5,0. Credit prerequisite course is to obtain a minimum assessment of 3.0. Other evaluation depends on the quality of answers to selected questions.
Final assessment: 3.0 (6 points-questions), 3.5 (7 pts-questions), 4.0 (8 points-questions), 4.5 (9 point-questions), 5.0 10 (point-questions).
Assessment is carried out without the use of notes, other materials and support and without communicating with other people. The duration of completion of the lecture 45 minutes.
Bibliography
a) basic references: James A. 1986 - Mathematical modeling in wastewater treatment and water protection, Arkady, Warsaw
Soczyńska U. 1997 - Dynamic Hydrology, PWN, Warsaw.
b) supplementary references: www.epa site (U.S. Environmental Protection Agency)