Difference between revisions of "Curriculum on Self-Organizing Networked Systems"

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(Core Courses)
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* Part II: Case studies. A ring lecture with speakers from different universities and different fields.
 
* Part II: Case studies. A ring lecture with speakers from different universities and different fields.
  
====Dynamic Systems (Lecture and Lab)====
+
====Dynamic Systems====
 +
Lecture and Lab
 
Content: similar to "Nonlinear Dynamics and Chaos" by Steven H. Strogatz
 
Content: similar to "Nonlinear Dynamics and Chaos" by Steven H. Strogatz
  
====Network Theory (Lecture and Exercises)====
+
====Network Theory====
 +
Lecture and Exercises
 
Content: Networks from the real world. Network topology: Graph theory basics, random graphs, phenomena small wold and scale-freeness. Network functions/processes/algorithms: E.g. search, percolation.
 
Content: Networks from the real world. Network topology: Graph theory basics, random graphs, phenomena small wold and scale-freeness. Network functions/processes/algorithms: E.g. search, percolation.
  
====Information Theory and Coding (Lecture and Exercises)====
+
====Information Theory and Coding====
 +
Lecture and Exercises
  
====Advanced Stochastics (Lecture and Exercises) ====
+
====Advanced Stochastics====
 +
Lecture and Exercises
 
Content: Selected topics from the following fields: Stochastic Processes. Statistical Physics.
 
Content: Selected topics from the following fields: Stochastic Processes. Statistical Physics.
  

Revision as of 12:46, 16 July 2009

Curriculum

Core Courses

The following courses are mandatory:

Introduction to Self-Organizing Networked Systems

  • Part I: What is a self-organizing system? Methodology and theory. Links to following courses.
  • Part II: Case studies. A ring lecture with speakers from different universities and different fields.

Dynamic Systems

Lecture and Lab Content: similar to "Nonlinear Dynamics and Chaos" by Steven H. Strogatz

Network Theory

Lecture and Exercises Content: Networks from the real world. Network topology: Graph theory basics, random graphs, phenomena small wold and scale-freeness. Network functions/processes/algorithms: E.g. search, percolation.

Information Theory and Coding

Lecture and Exercises

Advanced Stochastics

Lecture and Exercises Content: Selected topics from the following fields: Stochastic Processes. Statistical Physics.

Intelligent Systems (?)

Content: Game theory, neural networks, machine learning

Modeling and Simulation

Algorithms

Control Theory

Catch-up Courses

Depending on the background of the student, she or he attends a subset of the following courses:

Specialization

Group Work

Group 1: Bauschert, Bettstetter, Pletzer, Quaritsch, Yanmaz

[[Curriculum-so-work.jpg]]


Group 2: Anton, Manfred, Felix, Johannes,Alain

All courses should specifically deal with applications towards SOS.

Curriculum table

Subject Type g2 und.grad g2 grad g2 grad spec. Var4
Dynamical Systems Lecture X 3ECTS
Information Theory Lecture X
Algorithms 1 & 2 Lecture & Lab X
Numerical Simulations Lecture & Labs X
Topics course SO in nature/society Lecture X
specified classes (choose two)
Network 1 & 2 X
Statistical physics 1 & 2 X
Embedded Systems X
Sensors and Robotics X
Undergraduate
Calculus 1 & 2 Lecture X
Statistics Lecture X
Diff. Equations Lecture X
Linear Algebra Lecture X
Programming Lecture X
Natural sciences Lecture X