6 ECTS credits
160 h study time
Offer 1 with catalog number 4020327ENR for all students in the 2nd semester at a (E) Master - advanced level.
This course offers an introduction to optical communication systems, and covers a broad range of topics with special attention for the practical perspective of these systems. Physical understanding of the components and systems prepares students for designing optical links, including making design trade-offs in the practical implementation of those systems. After an introduction to the basic concepts of optical communications with an historical perspective, this course covers propagation in optical fibers, including attenuation and nonlinear effects, as well as the fabrication of optical fibers. It also covers chromatic and waveguide dispersion in optical fibers and dispersion compensation techniques. Additional topics include optical transmitters such as semiconductor lasers and LEDs, photodetectors (PIN, APD) and optical amplifiers such as Erbium-doped fiber amplifiers and semiconductor optical amplifiers. Students also gain an understanding of performance measures such as bit error ratio (BER), eye diagram, receiver sensitivity, optical power budget, as well as of optical network architectures and topologies. Finally, they gain insight in modulation and multiplexing techniques (WDM systems, WDM components, optical TDM). In the hands-on part, students learn how to design a long-haul telecom link using state-of-the-art simulation tools.
Lecturing team:
VUB: Prof. Jürgen Van Erps
UGent: Prof. Geert Morthier
Lecture (HOC): 36 hours
This includes guest lecture(s) by speaker(s) from industry, during which attendance is compulsory.
Tutorials and practical exercises (WPO): 16 hours
Attendance is compulsory. During these practical sessions, the operation of two commercially available state-of-the-art simulation software tools will be explained and a project assignment will be given.
Independent learning (ZELF): 108 hours.
The individual project assignment consists of the design of a long-haul link using the above-mentioned simulation tools (40 hours). The project files and a written report on the project should be handed in one week before the exam.
1.Aims and objectives:
Driven by the relentless increase in the demand for bandwidth, optical fiber communications have become ubiquitous for long-haul telecommunications. Therefore, the student should understand the basics of light propagation through optical fibers, and how these fibers can be fabricated and used as a fundamental building block in optical networks, together with optical transmitters, optical amplifiers and optical receivers. This should allow the student to understand the operation of optical networks, as well as enable them to design long-haul optical telecom systems.
2.Competences and Exam requirements:
The students have to prove that they master the principles of optical fiber networks, including e.g. attenuation, dispersion and nonlinear effects in optical fibers, how to mitigate those effects, how to make an optical power budget, how to choose the appropriate photodetector, and describe the operation of different types of optical amplifiers. In addition, the student should show insight in multiplexing techniques such as wavelength division multiplexing (WDM), the required components to realize such WDM networks, understand network topologies and performance monitoring of optical networks (through e.g. the eye diagram and the bit error rate).
Finally, the student should be able to design a point-to-point long-haul optical telecom link with dedicated commercial software packages (RSoft OptSim, Lumerical MODE Solutions) and show that they are able to find a cost-effective design solution by optimizing the interplay between attenuation, dispersion and nonlinear effects. After an in-depth introduction to the software tools, the students will receive a project assignment for which they have to make a written report describing their optical link, its performance, and the most important design choices they’ve made.
In conclusion, this course contributes to the following competences:
- Knowing and understanding the main components and system concepts that are used in optical communication.
- Apply Computer Aided Engineering (CAE) tools in a creative and target-oriented way to design long-haul optical communication links.
- Choose the most appropriate design and test methods for optical communication systems (and their components), understand their theoretical background and apply them accurately. This also includes the ability the correctly interpret the datasheet of the most commonly used optical communication components.
- Understand non-optical aspects of optical communication systems, such as electronics (modulation schemes, signal-to-noise ratio, performance monitoring, etc).
- Have an insight in the main evolutions of fundamental research and the recent innovation trends in the field of optical telecommunication.
The final grade is composed based on the following categories:
Oral Exam determines 100% of the final mark.
Within the Oral Exam category, the following assignments need to be completed:
The examination consists of an oral exam with written preparation (closed book).
The grading of the oral exam consists of:
50% theory part
50% project assignment (which is a combined score of the written report and the oral exam)
This offer is part of the following study plans:
Master of Photonics Engineering: Standaard traject (only offered in Dutch)