Difference between revisions of "CEM"
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* [[Lecture 4. - Assignment]] - Cable Harness Analysis | * [[Lecture 4. - Assignment]] - Cable Harness Analysis | ||
* <span style="color:red">'''[[Homework Assignment]] - Analysis of Solenoid Valve'''</span> | * <span style="color:red">'''[[Homework Assignment]] - Analysis of Solenoid Valve'''</span> | ||
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| + | {| width=100% border=1 | ||
| + | |- valign=top bgcolor=lightyellow | ||
| + | | width=50% | | ||
| + | * '''{{BFS pdf|Preface and Contents|bfs-frontmatter|14Sep14}}''' | ||
| + | * '''Chapter 1: {{BFS pdf|Introductory Concepts|bfs-intro|14Sep14}}''' | ||
| + | ** Systems Biology: Modeling, Analysis and the Role of Feedback | ||
| + | ** The Cell as a System | ||
| + | ** Control and Dynamical Systems Tools | ||
| + | ** Input/Output Modeling | ||
| + | ** From Systems to Synthetic Biology | ||
| + | * '''Chapter 2: {{BFS pdf|Core Processes|bfs-coreproc|14Sep14}}''' | ||
| + | ** Modeling Techniques | ||
| + | ** Transcription and Translation | ||
| + | ** Transcriptional Regulation | ||
| + | ** Post-Transcriptional Regulation | ||
| + | ** Cellular Subsystems | ||
| + | * '''Chapter 3: {{BFS pdf|Dynamic Behavior|bfs-dynamics|14Sep14}}''' | ||
| + | ** Analysis Near Equilibria | ||
| + | ** Robustness | ||
| + | ** Oscillatory Behavior | ||
| + | ** Bifurcations | ||
| + | ** Model Reduction Techniques | ||
| + | * '''Chapter 4: {{BFS pdf|Stochastic Modeling and Analysis|bfs-stochastic|14Sep14}}''' | ||
| + | ** Stochastic Modeling of Biochemical Systems | ||
| + | ** Simulation of Stochastic Systems | ||
| + | ** Input/Output Linear Stochastic Systems | ||
| + | | width=50% | | ||
| + | * '''Chapter 5: {{BFS pdf|Biological Circuit Components|bfs-circuits|14Sep14}}''' | ||
| + | ** Introduction to Biological Circuit Design | ||
| + | ** Negative Autoregulation | ||
| + | ** The Toggle Switch | ||
| + | ** The Repressilator | ||
| + | ** Activator-repressor Clock | ||
| + | ** An Incoherent Feedforward Loop (IFFL) | ||
| + | ** Bacterial Chemotaxis | ||
| + | * '''Chapter 6: {{BFS pdf|Interconnecting Components|bfs-modules|14Sep14}}''' | ||
| + | ** Input/Output Modeling and the Modularity Assumption | ||
| + | ** Introduction to Retroactivity | ||
| + | ** Retroactivity in Gene Circuits | ||
| + | ** Retroactivity in Signaling Systems | ||
| + | ** Insulation Devices: Retroactivity Attentuation | ||
| + | ** A Case Study on the Use of Insulation Devices | ||
| + | * '''Chapter 7: {{BFS pdf|Design Tradeoffs|bfs-tradeoffs|14Sep14}}''' | ||
| + | ** Competition for Shared Cellular Resources | ||
| + | ** Stochastic Effects: Design Tradeoffs in Systems with Large Gains | ||
| + | * '''{{BFS pdf|Bibliography and Index|bfs-backmatter|14Sep14}}''' | ||
| + | |} | ||
Revision as of 13:57, 17 March 2019
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Introduction to Computational Electromagnetics | |
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Instructors
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Teaching Assistants
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Course Description
Introduction to fundamentals and techniques of finite element method and modelling in electromagnetics. The course includes: basics of electromagnetics, equations of static magnetic, electrostatic, eddy current and time-dependent problems, Helmholtz-equation, basic of finite element method, nodal and edge shape functions, boundary conditions, mesh operations. The course participants meet the following automotive examples in practice, fuel injection solenoid, induction heating, permanent magnet motor and an automobile cable harness analysis.
Syllabus
- Lecture 1. - Basics of Electromagnetics / Static Magnetic and Electrostatic Field
- Lecture 1. - Assignment - Fuel Injection Solenoid
- Lecture 2. - Basics of Finite Element Method / Time-Harmonic Magnetic Field
- Lecture 2. - Assignment - Induction Heating
- Lecture 3. - Coupled Finite Element Method / Time-Dependent Magnetic Field
- Lecture 3. - Assignment - Permanent Magnet Motor
- Lecture 4. - Integral Equations Based Methods / Wave equations
- Lecture 4. - Assignment - Cable Harness Analysis
- Homework Assignment - Analysis of Solenoid Valve
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