|
|
|
| Module code: PIM-FSDN |
|
4V (4 hours per week) |
|
5 |
| Semester: 1 |
| Mandatory course: no |
Language of instruction:
German |
Assessment:
Written exam/paper
[updated 26.02.2018]
|
E2933 (P222-0090) Electrical Engineering and Information Technology, Master, ASPO 01.04.2019
, optional course, technical, course inactive since 30.09.2020
KI759 (P222-0090) Computer Science and Communication Systems, Master, ASPO 01.04.2016
, semester 1, optional course, informatics specific
KIM-FSDN Computer Science and Communication Systems, Master, ASPO 01.10.2017
, semester 1, optional course, informatics specific
PIM-WI68 (P222-0090) Applied Informatics, Master, ASPO 01.10.2011
, semester 1, optional course, informatics specific
PIM-FSDN Applied Informatics, Master, ASPO 01.10.2017
, semester 1, optional course, informatics specific
|
60 class hours (= 45 clock hours) over a 15-week period.
The total student study time is 150 hours (equivalent to 5 ECTS credits).
There are therefore 105 hours available for class preparation and follow-up work and exam preparation.
|
Recommended prerequisites (modules):
None.
|
Recommended as prerequisite for:
|
Module coordinator:
Prof. Dr. Damian Weber |
Lecturer:
Prof. Joberto Martins
[updated 02.10.2019]
|
Learning outcomes:
After successfully completing this course, students will be able to classify all of the consequences of adopting Software Defined Networking (SDN) to the applications development process. Students will be able to assess the impact of SDN for the TCP/IP architecture. They will also be capable of explaining and implementing openflow-based applications. In addition, students will be capable of designing control and monitoring frameworks and writing a concept for a deploying mechanism of such tools using advanced concepts such as federation.
[updated 26.02.2018]
|
Module content:
1. Networking Architectural Approaches and Issues:
- Actual IP architecture scenario and new requirements
- Software Defined Networking (SDN)
- Architectural issues: naming, addressing, mobility, scalability, autonomy and virtualization
2. OpenFlow Protocol:
- OpenFlow (OF) architecture
- OF protocol
- OF and virtualization
- OF use cases: virtual router, level 2 virtualization, other
- OF experimentation with MiniNet (hands-on exercises)
3. Experimental Networks (EN):
- Experimental Networks principles - user-defined, large and innovative experiments, users, reproducibility, scaling and monitoring:
. Experiment (project) requirements
. Experiment (project) planning
. Experiment (project) execution
. Experiment (project) monitoring
- CMF _ Control and Monitoring Framework _ model and components
- Experimental network OFELIA (OpenFlow in Europe: Linking Infrastructure and Applications) _ Architecture:
components, tools, experimentation facilities, monitoring
- Experimental Network OMF (Orbit Management Framework) _ Architecture:
components, tools, experimentation facilities, monitoring
- Experimental Network FIBRE EU-BR (Future Internet Testbed Experimentation between Brazil and Europe) _ Architecture:
components, tools, experimentation facilities, monitoring
- Experimental networks monitoring:
- Architecture, components and issues on monitoring an experiment using an "Experimental Network" (EN)
- Study case: FIBRE EU-BR I&M Architecture
- Experimental Networks Federation:
. Federation principles
. SFA (Slice-based Federation Architecture) approach
- Experimental Networks "hands-on" exercise:
Exercise: create a project/experiment on one of the above experimental networks (OFELIA, OMF or FIBRE)
4. Future Internet - Trends and Scenarios:
- QoS (Quality of Service) and QoE (Quality of Experience) in FI
- FI use cases
- FI research
[updated 26.02.2018]
|
Recommended or required reading:
[still undocumented]
|
Module offered in:
WS 2018/19,
WS 2017/18
|
