Course Objectives: |
To equip students with the practical skills and knowledge necessary to effectively utilize electromagnetic simulation software for the analysis, design, and optimization of electromagnetic systems and devices. |
Course Content: |
Basic Concepts in Electromagnetic Modeling, Use of Electromagnetic simulation sotware, Meshing Techniques, Boundary Conditions and Excitation Setup, Simulation Solvers and Algorithms. Post-Processing and Analysis of Simulation Results, Antenna Simulation and Design, RF and Microwave Circuit Simulation,
Transmission Line and Waveguide Simulation, Electromagnetic Compatibility (EMC) Analysis, Advanced Topics and Case Studies in Electromagnetic Simulation |
Week |
Subject |
Related Preparation |
1) |
Introduction to Electromagnetic Simulation Software |
None. |
2) |
Basic Concepts in Electromagnetic Modeling |
Read the relevant section of the textbook.
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3) |
Setting up Simulation Projects |
Read the relevant section of the textbook.
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4) |
Meshing Techniques for Electromagnetic Simulation |
Read the relevant section of the textbook.
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5) |
Boundary Conditions and Excitation Setup |
Read the relevant section of the textbook.
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6) |
Simulation Solvers and Algorithms |
Read the relevant section of the textbook.
|
7) |
Post-Processing and Analysis of Simulation Results |
Read the relevant section of the textbook.
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8) |
Antenna Simulation and Design |
Read the relevant section of the textbook.
|
9) |
Midterm |
Review |
10) |
RF and Microwave Circuit Simulation |
Read the relevant section of the textbook.
|
11) |
Transmission Line and Waveguide Simulation |
Read the relevant section of the textbook.
|
12) |
Electromagnetic Compatibility (EMC) Analysis |
Read the relevant section of the textbook.
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13) |
Advanced Topics and Case Studies in Electromagnetic Simulation |
Read the relevant section of the textbook.
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14) |
Final. |
Review |
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Program Outcomes |
Level of Contribution |
1) |
Reaches the information in the field of power electronics and clean energy systems in depth through scientific researches; evaluates the knowledge, interprets and implements. |
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2) |
Has the extensive information about current techniques and their constraints in the field of Power Electronics . |
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3) |
Using limited or missing data, completes the information through scientific methods and applies; integrates the information from different disciplines. |
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4) |
Aware of new and emerging applications of his/her profession; learn and examine them if needed. |
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5) |
Builds the Power Electronics problems, develops methods to solve and implements innovative ways for solution. |
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6) |
Develops new and/or original ideas and methods; develops innovative solutions for the design of a process, system or component. |
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7) |
Designs and implements the analytical, modeling and experimental-based researches; resolves the complex situations encountered in this process and interprets. |
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8) |
Leads multi-disciplinary teams, develops solution approaches to complex situations and takes responsibility. |
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9) |
Uses at least one foreign language at the general level of European Language Portfolio B2 and communicates effectively in oral and written language. |
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10) |
Presents the process and results of the work in national and international media systematically and clearly in written or oral language. |
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11) |
Describe the social and environmental dimensions of Power Electronics Engineering applications. |
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12) |
In the stages of data collection, interpretation and publication as well as all professional activities, he/she considers the social, scientific and ethical values. |
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