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Information
| Unit | INSTITUTE OF NATURAL AND APPLIED SCIENCES |
| PHYSICS (MASTER) (WITH THESIS) | |
| Code | FK728 |
| Name | Numerical Methods in Electromagnetic Theory II |
| Term | 2018-2019 Academic Year |
| Term | Spring |
| Duration (T+A) | 4-0 (T-A) (17 Week) |
| ECTS | 6 ECTS |
| National Credit | 4 National Credit |
| Teaching Language | Türkçe |
| Level | Belirsiz |
| Type | Normal |
| Mode of study | Yüz Yüze Öğretim |
| Catalog Information Coordinator | Prof. Dr. FARUK KARADAĞ |
| Course Instructor |
The current term course schedule has not been prepared yet.
|
Course Goal / Objective
Implement a number of well known numerical methods in solving practical EM problems. Recognize main challenges encountered in the implementation of different numerical methods. Test and validate the output of a numerical method used in EM problems.
Course Content
B. Numerical methods (approximate solutions), method of weighted residuals (3) moment method (4) finite element method (5) transmission-line modeling (6) Monte Carlo method (7) method of lines
Course Precondition
Resources
Notes
Course Learning Outcomes
| Order | Course Learning Outcomes |
|---|---|
| LO01 | Use the analytical methodsfor solving EM problems. |
| LO02 | Implement a number of wellknown numerical methodsin solving practicalEM problems. |
| LO03 | Recognize main challenges encountered in the implementation of different numerical methods. |
| LO04 | Test and validate the output ofa numerical method used in EM problems. |
| LO05 | Determine the which numerical methodssolve the EM problem. |
| LO06 | Combine existing numerical methodsto arrive at a new hybrid technique. |
Relation with Program Learning Outcome
| Order | Type | Program Learning Outcomes | Level |
|---|---|---|---|
| PLO01 | - | Has sufficient infrastructure in various subjects of Physics. | |
| PLO02 | - | Demonstrate the knowledge of appropriate mathematical techniques used in physics. | |
| PLO03 | - | Interpret observational and experimental results. | |
| PLO04 | - | Makes use of the conceptual and practical knowledge acquired in the physics field at mastery level. | |
| PLO05 | - | Has a knowledge about the logic of scientific research. | |
| PLO06 | - | Report the solution of a physics problem, experimental results or projects in a written format or orally. | |
| PLO07 | - | Chooses and uses the necessary publications, books and methods for a scientific research. | |
| PLO08 | - | Accesses a knowledge about a subject in physics, does literature search and uses other sources for this purpose. | |
| PLO09 | - | Provides solutions to the problems encountered in the physics field applying research methods. | |
| PLO10 | - | Can perform an independent research. | |
| PLO11 | - | Can perform group work effectively in a research or industrial projects. | |
| PLO12 | - | Becomes conscious of the necessity of lifelong learning. | |
| PLO13 | - | To keep track of the developments in physics and updates himself/herself invariably. | |
| PLO14 | - | Shares his/her ideas and suggestions for solutions to the physical problems with experts and non-experts by supporting them with quantitative and qualitative data. | |
| PLO15 | - | Can make an effective written or oral presentation of the results obtained in a study. | |
| PLO16 | - | Makes use of the knowledge, problem solving and / or application skills acquired in the physics field in interdisciplinary studies. | |
| PLO17 | - | Has a foundation necessary to work in a research and development organizations. |
Week Plan
| Week | Topic | Preparation | Methods |
|---|---|---|---|
| 1 | Variational Methods, Operators in Linear Spaces, Calculus of Variations | Self-study, exercises | |
| 2 | Construction of Functionals from PDEs Rayleigh-Ritz Method Weighted Residual Method | Self-study, exercises | |
| 3 | Eigenvalue Problems Practical Applications | Self-study, exercises | |
| 4 | Moment Methods, Integral Equations, Green's Functions Applications I, Quasi-Static Problems | Self-study, exercises | |
| 5 | Applications II - Scattering Problems Applications III - Radiation Problems Application IV - EM Absorption in the Human Body | Self-study, exercises | |
| 6 | FINITE ELEMENT METHOD, Solution of Laplace's Equation, Solution of Poisson's Equation | Self-study, exercises | |
| 7 | Solution of the Wave Equation Automatic Mesh Generation I - Rectangular Domains | Self-study, exercises | |
| 8 | Mid-Term Exam | Mid-Term Exam | |
| 9 | Automatic Mesh Generation II - Arbitrary Domains Bandwidth Reduction Higher Order Elements | Self-study, exercises | |
| 10 | Three-Dimensional Elements Finite Element Methods for Exterior Problems | Self-study, exercises | |
| 11 | TRANSMISSION-LINE-MATRIX METHOD Transmission-Line Equations Solution of Diffusion Equation | Self-study, exercises | |
| 12 | Solution of Wave Equations Inhomogeneous and Lossy Media in TLM Three-Dimensional TLM Mesh | Self-study, exercises | |
| 13 | Error Sources and Correction Absorbing Boundary Conditions | Self-study, exercises | |
| 14 | MONTE CARLO METHODS Generation of Random Numbers and Variables Evaluation of Error Numerical Integration Solution of Potential Problems Regional Monte Carlo Methods | Self-study, exercises | |
| 15 | METHOD OF LINES, Solution of Laplace's Equation, Solution of Wave Equation, Time-Domain Solution | Self-study, exercises | |
| 16 | Term Exams | Term Exam | |
| 17 | Term Exams | Term Exam |