470-8743/01 – Mathematical Modelling and FEM (MMMKP)

Gurantor departmentDepartment of Applied MathematicsCredits5
Subject guarantordoc. Ing. Dalibor Lukáš, Ph.D.Subject version guarantorprof. RNDr. Radim Blaheta, CSc.
Study levelundergraduate or graduateRequirementCompulsory
Year1Semestersummer
Study languageCzech
Year of introduction2010/2011Year of cancellation2020/2021
Intended for the facultiesUSPIntended for study typesFollow-up Master
Instruction secured by
LoginNameTuitorTeacher giving lectures
DOM0015 Ing. Simona Bérešová, Ph.D.
LUK76 doc. Ing. Dalibor Lukáš, Ph.D.
Extent of instruction for forms of study
Form of studyWay of compl.Extent
Full-time Credit and Examination 3+1
Part-time Credit and Examination 15+5

Subject aims expressed by acquired skills and competences

Students will be able to formulate the boundary value problems arising in mathematical modeling of heat conduction, elasticity, and other phenomena (diffusion, electro and magnetostatics, etc.). It will also be able to derive the differential and variational formulation of the task and numerical solution of the finite element method. They will know the principles of proper use of mathematical models for solving engineering problems.

Teaching methods

Lectures
Tutorials

Summary

The course should prepare the students to be able to formulate the boundary value problems arising in mathematical modelling of heat conduction, elasticity and other physical processes. The students should be also able to derive differential and variational formulation of these problems and understand the mathematical principles of their numerical solution, especially by the finite element method. The course will also touch the principles of proper use of mathematical modelling methods for solving engineering problems.

Compulsory literature:

R. D. Cook: Finite element modelling for stress analysis, J. Wiley, New York, 1995. C. Johnson: Numerical solution of partial differential equations by the finite element method, Cambridge Univ. Press, 1995

Recommended literature:

R. D. Cook: Finite element modelling for stress analysis, J. Wiley, New York, 1995. C. Johnson: Numerical solution of partial differential equations by the finite element method, Cambridge Univ. Press, 1995

Way of continuous check of knowledge in the course of semester

E-learning

Other requirements

Additional requirements for students are not.

Prerequisities

Subject has no prerequisities.

Co-requisities

Subject has no co-requisities.

Subject syllabus:

Mathematical modeling. Purpose and general principles of modeling. Benefits mathematical modeling. Proper use of mathematical models. Differential formulation of mathematical models. One-dimensional heat conduction problem and its mathematical formulation. Generalizing the model. The input linearity, existence and uniqueness of solutions. Discrete input data. One-dimensional task flexibility and other models. Multivariate models. Variational formulation of boundary problems. Weak formulation of boundary problems and its relationship to the classical solutions. Energy and energy functional formulation. Coercivity and boundedness. Uniqueness, continuous dependence of solutions input data. Existence and smoothness of the solution. Ritz - Galerkin (RG) method. RG method. Konenčných element method (FEM) as a special case of the RG method. History MLP. Algorithm finite element method. Assembling the stiffness matrix and vector load. Taking into account the boundary conditions. Numerical solution of linear systems algebraic equations. Different types of finite elements. The accuracy of finite element solutions. Priori estimate of the discretization error. Convergence, h-and p-version FEM. Posteriori estimates. Network design for MLP adaptive technology and optimal network. FEM software and its use for MM. Preprocessing and postprocessing. Commercial software systems. Solutions particularly difficult and special problems. Principles Mathematical modeling using FEM.

Conditions for subject completion

Full-time form (validity from: 2012/2013 Winter semester, validity until: 2020/2021 Summer semester)
Task nameType of taskMax. number of points
(act. for subtasks)
Min. number of pointsMax. počet pokusů
Exercises evaluation and Examination Credit and Examination 100 (100) 51
        Exercises evaluation Credit 30  15
        Examination Examination 70  21 3
Mandatory attendence participation:

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Conditions for subject completion and attendance at the exercises within ISP:

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Occurrence in study plans

Academic yearProgrammeBranch/spec.Spec.ZaměřeníFormStudy language Tut. centreYearWSType of duty
2019/2020 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2018/2019 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2017/2018 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2016/2017 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2015/2016 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2014/2015 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2014/2015 (N3942) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2013/2014 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2012/2013 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2011/2012 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2010/2011 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan

Occurrence in special blocks

Block nameAcademic yearForm of studyStudy language YearWSType of blockBlock owner

Assessment of instruction



2018/2019 Summer
2016/2017 Summer
2015/2016 Summer
2013/2014 Summer