Digital Transmission & Signal Processing

Quick Links

• Introduction
• Prerequisites
• Course Structure
• Matlab
• Literature

Remark:

Our lectures and tutorials are designed for active participation in presence. To further support general measures as energy-saving periods we do, however, also offer remote participation. The course Digital Transmission & Signal Processing therefore is in a format considering the possibility for as well students as lecturer and tutors to give and / or consume parts of the course online using web-conference tools:

• Course material, quizzes and assignments will be done in Moodle.
• Lectures will be offered in MS-Teams in a hybrid fashion (lecture hall plus Teams).
• The content will be based on our DTSP-book that is available in various formats (ipynb, pdf, html).

Course Details

Classroom

The lecture will be offered in a hybrid format (classroom plus remote participation via MS Teams). Under special circumstances it might be advantageous or even required to omit the classroom and switch to fully remote. This will be announced on time.

For participating remotely please join the MS-Teams Team by sending a join request under the following link: DTSP WS 2023/24 Team

Introduction

Digital Transmission & Signal Processing is the basic course on telecommunications. It refreshes foundations laid in "Signals and Systems / Signale und Systeme" but will also include current developments on using Artificial Intelligence / Neural Networks in Telecommunicaiton.

To establish a strong foundation, the course will give an introduction into the various building blocks modern telecommunication systems incorporate. Sources, sinks, source and channel coding, modulation and multiplexing are the major keywords, but we will also deal with dedicated concepts like A/D- and D/A-converters and quantizers in a little bit more depth.

The course will refresh the basic transformations (Fourier, Laplace) that give access to system analysis in the frequency domain, it will introduce derived transformations (Z, Hilbert) for the analysis of discrete systems and modulation schemes. It will also introduce algebra on finite fields to systematically deal with error detection and correction schemes that play an important and ubiquitous role in modern communication systems.

Prerequisites

"Digital Transmission and Signal Processing" is a course during the main study period and by such requires a solid foundation of mathematics (differential and integral calculus) and probability theory. The course will, however, refresh those areas indispensably necessary for telecommunications and potential intensification courses and by this open this potential field of intensification to all participants.

Course Structure

Basic Rules

• Please note that small changes and corrections will be applied to the lecture notes throughout the semester. If you find mistakes or have suggestions how to enhance the lecture notes we appreciate your input!
• Please don’t hesitate to tell us if you have any comments or suggestions related to the DTSP-Book, the Quizzes, the Tutorials or organisational issues. We will improve it soon so you can benefit from it, not only future students.
• There will be online weekly quizzes with 5 questions for 15 minutes every week. These quizzes are graded individually and the points will be published online.

Lectures

• Place: Campus E1.3, Room: HS001 (possible to join remotely via Teams)
• Time: Tuesday 12:15–13:45 and Wednesday 08:30–10:00 (start October 24^th)

Quizzes

• Place: Campus C6.3, Room: 9.05 (or online via Moodle)
• Time: Friday 10:00–10:30
• Tutor: Robin Kremer

Tutorials

• Place: Campus C6.3, Room: 9.05 (in presence)
• Time: Friday 10:30–11:45
• Tutor: Robin Kremer

Exam Dates

• The exams will be held as WRITTEN exams
• Main Exam - 20. Feb. 2024, 09:30–11:30, E1 3 HS002
• Re-Exam - 20. Mar. 2024, 09:30–11:30, E1 3 HS001

Task Sheets

• Task sheets are published on the day succeeding the tutorials and are available online.
• You submit your solution and work on the tasks up to and including the following tutorial.
• During the tutorial you can discuss and evolve your solutions and get up to three additional points.

Correction

• The quizzes and task sheets for this course will be divided into two parts (6+6 in blocks A&B respectively). It is necessary to pass both the blocks individually to be eligible for the exam.
• Weekly Quizzes and Task Sheets:
  • Each weekly quiz are worth 5 points total, which adds up to 30/30 points total for Blocks A/B. These points can be earned individually by everyone.
  • Each task sheet contains minimum 3 tasks, which adds up to 18/18 points total for Blocks A/B. These points can be earned if you individually can demonstrate your understanding on the task during the tutorial and by your submitted solutions.
  • Final points are calculated by adding up over all quizzes and task sheets within a block.
  • You need minimum 40% in total to pass a block and must pass both block A&B to be eligible for the exam.

Exam

• The exam contains 5 problems (each 10 points), solving 4 of them is sufficient for a 100% passing grade.
• Minimum point threshold per exam task is 3 points.
• (Near to) complete solutions are rewarded with 3 bonus points.

Matlab

• UdS has a MATLAB campus license which can be used by all university students for non-commercial purposes.

Literature (potentially helpful but not required)

Proakis, John G. and Salehi, Masoud: "Communications Systems Engineering", 2^nd Edition, 2002, Prentice Hall, ISBN = {0-13-061793-8}

Oppenheim, Alan and Willsky, Alan: "Signals & Systems", 2^nd Edition, 1997, Prentice Hall, ISBN = {0-13-814757-4}

Göbel, J.: "Kommunikationstechnik", Hüthig Verlag Heidelberg, 1999, ISBN = {3-82-665011-5}

Ohm, J.-R. und Lüke H.D.: "Signalübertragung", 2004, Springer, ISBN = {3-54-022207-3}

John G. Proakis: "Digital Communications", McGraw Hill Higher Education, 2001, ISBN = {0-07-118183-0}

Bernd Friedrichs: "Kanalcodierung", Springer, 1995, ISBN = {3-54-059353-5}

Papoulis, A.: "Probability, Random Variables and Stochastic Processes", 1965, McGraw-Hill, ISBN = {0-07-119981-0}

Claude E. Shannon, Warren Weaver: "The Mathematical Theory of Communication", University of Illinois Press, 1963, ISBN = {0-25-272548-4}