Seminar Computer Engineering

Study programs: Elektrotechnik, Informatik, IST, Elektronische Systeme, Elektromobilität, CSE.

Students are expressly encouraged to suggest their own topics! Please send a short synopsis of your seminar topic to ‘seminar@ida.ing.tu-bs.de’ by 7 April. The proposed topic should of course correspond to the general subject areas of the seminar.

Computer science:
via the central seminar allocation
+ e-mail (possibly with your own topic request) to the seminar organiser seminar@ida.ing.tu-bs.de

All other degree programmes:
Registration takes place from 10.03.2025, 10:00 via StudIP using the link above.

Some possible topic suggestions are listed below without obligation. There is no entitlement to a specific topic. An English-language title does not mean that the lecture must be held in English.

• 5G Core: Architecture and Functions
• Network Slicing for TSN based Networks
• 5G RedCap: Discover the Future of Connectivity That People Don't Know About Yet
• Sematic Communication: A new Communication Paradigm for Information Transfer

Please provide additional information such as MatrNr, degree programme, BA/MA, comments/topic requests when registering. Registrations from ET Bachelor or Electromobility students (seminar optional) will only be accepted subject to availability.

The allocation of seminar topics will take place during the "Kick-Off"
                   on 10.04.2025, 16:15 to approx. 16:45,
                   in room 1218, on the 12th floor of Hans-Sommer-Straße 66

Participation in this "Kick-Off" is mandatory for all participants and possible replacements of the study seminar! Students who do not attend the preliminary seminar meeting without an excuse, but are on the Stud.IP participant and waiting list, lose their right to a seminar place.

Topics will only be allocated on this date. A binding submission of an outline by xx.xx.2025 is required! The seminar dates will then be finalised.

Seminar preliminary discussion/topic allocation
Students who have registered in StudIP must take part in a preliminary seminar discussion/topic allocation (kick-off). The number of seminar places is flexible and can be adapted to demand. Subsequently, the documents (literature) for preparation will be made available at short notice. The further procedure (content-related questions, slide design, trial presentation) is then coordinated with the individual topic supervisor.

Seminar
The seminar takes place on 3-5 dates, each in blocks with several lectures. Students must attend all presentations. The presentations last approx. 30 minutes. This is followed by a longer discussion (15 - 20 minutes) with the supervisors and the students of the seminar, in which the content is dealt with first and then possible improvements to the presentation (slides, oral presentation, discussion) are discussed. The language of presentation and discussion is German or English, depending on the lecturer's preference. If required by the degree programme (Computer Science), a written elaboration is to be prepared in addition to the presentation slides (approx. 10 A4 pages, font size 12 pt, line spacing 1.2 lines).

Test presentation
At the latest one week before your seminar presentation, the supervisors will decide whether the presentation can be given after a trial presentation in presence. The mock presentation should largely correspond to the final presentation and will decide whether you fail the seminar!

The following seminar presentations are stored on the fileserver (after the end of the corresponding semester) and can be accessed with a suitable user account after registration. If you have any questions, please contact the secretariat.

• USB Power Delivery - Vor-, Nachteile und Einsatzmöglichkeiten
• Digital Twin - Why do we clone our physical environment?
• How to Harmonize Conflicting Beliefs in a Heterogeneous Multiagent System
• The Future of Vehicular Communication: Analysis and Comparison of Key V2X Communication Technologies
• Wireless Time Sensitive Networking
   

• Vehicle-To-Everything (V2X)
• Time Synchronization Protocols
• Embedded real-time operating systems - scheduling algorithms compared
• Hypervisors: From Virtualization to Reconfiguration
• Controlling a Kitchen Robot with natural language
• Visible optical camera communication
• The autonomous driving perception pipeline: Design principles and challenges
   

• Wireless Communication:
  - Handover in 5G systems 
  - Cell-Free Networking: A Next Generation Paradigm
• Time Sensitive Networking:
  - Basic concepts and industrial application 
  - Resource Management in TSN: 802.1qcc
• Object Recognition: The differences of one-stage and two-stage detectors
• Hyperspectral Data Compression: The near lossless CCSDS-123.0-B-2 standard
• FDM 3D Drucker: Neue Features der letzten Jahre
• Entstehung und Beseitigung von Weltraumschrott
• Trends and Technology:
  - Future Mobility - The AUTOtech.agil Approach 
  - How does Intel manufacture and test chips
   

• Wireless Communication:
  - Towards sustainable (green) V2X communication 
  - Long Range Communication in Wireless Sensor Networks
• Deep Learning:
  - How does ChatGPT work? 
  - Principles, Deployment and Applications of Neural Networks in cyber-physical systems
• High-Speed, Low-Latency Data Transfer for Distributed Data Bases and Data Center Applications:
  - Indepth Insight into RDMA Protocols and specialized HW
• Trends & Areas in Computer Industry:
  - HW/SW Architektur in Avionics 
  - Unique embedded applications
• AUTOSAR and Space:
  - Introduction to the AUTOSAR Adaptive Platform Design 
  - Die ESA JUICE (Jupiter Icy Moons Explorer) Raumsonde zum Jupiter
   

• Robustness in cause-effect chains:
  - TORO Tool Überblick 
  - Weiterentwicklung und Perspektive TORO Tool
• Aktuelle Trends in AUTOSAR:
  - AUTOSAR platform overview 
  - Timing in AUTOSAR 
  - Interaction between AUTOSAR adaptive and classic platform
• Evolution technischer Automobil-Architekturen im Trend des 'Software-Oriented Architecture' Paradigmas
• Notion of time in wireless communication, real-time in wireless
• Future of programming languages:
  - Why are there so many progamming languages?
  - Challenges in programming safety-critical systems
• Evaluation and benchmarking in theses and papers:
  - Concept of benchmarking and why good benchmarks advance the state of research
  - Benchmarking crimes that hinder/threat advancements in scientific research
• James Webb Teleskop:
  - Mission und Ziele, erste Ergebnisse
  - Aufbau und das Hauptinstrument MIRI
• Rechenzentren:
  - Überblick der Energieversorgung in Rechenzentren
  - Effiziente Energieversorgung von Hochleistungsrechnern mit 48V DC
   

• Aerospace Data Processing:
  - ExoMars2022 camera system: basics and concept 
  - CCSDS 122.0: Image pre-processing and compression for aerospace missions
  - Survey of current FPGA families for Space 2.0 and Automotive
• Introduction to E/E Architectures:
  - Overview and Requirements of future E/E Architectures
• Rechnerarchitekturen für autonome Fahrzeuge:
  - Grundlagen / Anforderungen an die Rechnerarchitektur
  - Vorstellung von Praxisbeispielen
• Abstract notion of time and data version management:
  - Concepts of distributed database transactions
  - In-Memory Databases: Processing Data in Real-Time
• High performance processing hardware:
  - General Purpose CPUs (Apple M1 and Intel Adler Lake)
  - Carbon Nanotube Field-Effect Transistor (CNTFET)
• High performance interconnects:
  - V2X communication
  - Intelligent network management
• Analyzing safety critical systems:
  - Compositional Performance Analysis for timing in E/E Architectures
  - Depedendency anlysis in safety critical systems
   

• Video Interfaces, Einführung und Details (z.B. Display Port)
• Xilinx Versal with integrated High Bandwith Memory
• Open RISC Architekturen
• Handling experimental data with Python Pandas
• Overview of V2X applications and communication technologies
• An Overview and Comparision of Cloud and Edge Computing for V2X and their respective Fields of Application
• V2X-Connectivity based on WIFI Communication
• V2X-Connectivity based on Cellular Communication
• Von CubeSats zu DiskSats
• Xilinx XRQ Versal for Space 2.0 Applications
• Einführung von Real-Time, WCET, WCRT, Übersicht WCET Verfahren (statisch, probabilisitc, hybrid)
• Tiefergehende Beschäftigung mit MBPTA und Extrem Value Theory [EVT]

• Laserdatenkommunikation (Tesat-Spacecom und Mynaric)
• Architekturen verteilter Systeme
• Kommunikation in verteilten Systemen
• Threads und Prozesse in verteilten Systemen
• Xilinx Versal FPGAs: Einführung und Kommunikationsarchitektur
• Software-Hardwareintegration für einen MPSoC (Xilinx UltraScale+)
• Echtzeitfähige Middleware für verteilte Systeme
• Power optimization for many-core hard real-time systems
• Powermanagement von Off-Chip Netzwerken
• High Bandwidth Memory
• Der TileLink Standard: Einführung
• Der TileLink Standard: TileLink vs. AXI4
• Mastcam-Z (mast-mounted camera system with zoom function on the Mars Perseverance rover)
• Vorstellung PRo3D (Planetary Robotics 3D Viewer, Marsoberfläche)
• AutowareAuto: ROS2 Open Source Project for automated driving
• Challenges of ROS2 scheduling policy considering real-time constraints
   

• CARLA-Simulator: Systemübersicht
• CARLA-Simulator: Anwendungsbeispiel
• Funktionale Sicherheit: Definition und Einführung
• Funktionale Sicherheit im Weltraum
• Funktionale Sicherheit in der Avionik
• Funktionale Sicherheit im Automobilbereich
• OSIRIS-REx: Struktur der Sonde
• OSIRIS-REx: Missionsbeschreibung
• cPCI Serial Space: Overview
• cPCI Serial Space: PCI Express
• Vorstellung des IPMI-Standards
• Radar-based Data Transmission
• Deep Neural Networks -Überblick-
• Deep Neural Networks -Hardware-
• V2X Kommunikationsstandards im Vergleich
• Vehicular Ad Hoc Networks (VANETS)
   

• Echtzeit-Betriebssystem für µ-Controller
• Fehlertolerante RISC-V Implementierung
• High-speed Schnittstelle für FPGAs
• Die Zukunft von 'Moore's Law
• Übersicht über die TSN Standards
• Synthese von TSN Konfigurationsparametern
• ERIKA: Kommunikationsarchitektur im Fahrzeug
• Powerline-Kommunikation (PLC) und Ressourcen Manager: Konzepte und Übersicht
• SL-LET und Reaktor Konzept
• Virtualisierung von Ausführung und Kommunikation mit Fokus auf ARMv8
• Mars 2020 Perseverance Rover -Übersicht-
• Mars 2020 Perseverance Rover -Helikopter-
   

• Resistive Random Access Memory
• PanCam on ExoMars2020 Rover
• ExoMars2020 Rover -Übersicht
• Mond VPU
• ESP32
• Solar Orbiter
• Fehlertolerante RISC-V Implementierungen
• Fehlertolerante Systemarchitektur gegen Hardwarefehler
• Arduino als Entwicklungsumgebung
• Gigatron
• Fehlertoleranz in verteilten eingebetteten Ethernet Systemen
• Industrie 4.0 - Neue Anforderungen an die Kommunikation
   

• Open-Source Software I
• Open-Source Software II
• Flash Memory Storage Technologie I
• Flash Memory Storage Technologie II
• MEMS Sensorprinzipien und Sensoren für SmartHome Anwendungen
• BEM: Building Energy Management in BASIS System
• Dynamische Kommunikation mittels DDS
• Automated HDL Code Generation
• Mission to the Moon
• Robot Operating System II
   

• Übersicht Mars Reconnaissanse Orbiter (MRO)
• HiRise Camera des MRO
• Grundlagen CORDIC
• Möglichkeiten zur Implementierung von faltenden neuronalen Netzwerken auf FPGAs: Übersicht und Ausblick
• Neuronale Netze: Einführung, Trainingsphase und Realisierungsmöglichkeiten
• Modellbasierte Entwicklung von E/E - Architekturen
• Projekt UNICARagil - Überblick
• Funkstandard: LoRaWan (Long Range Wide Area Network)
• 3-D-Druckverfahren
• Materialien für den FDM-3D-Druck
• Xilinx Versal ACAP Architecture
• CPU-FPGA System on Chips (SoCs)
   

• Grundlagen von Systemen zur Objektmanipulation auf einem Roboter
• Anwendungen von Systemen zur Objektmanipulation auf einem Roboter
• Forschungshaus "Bochumer Straße"
• Assistentsysteme im Smart Home
• Beschreibung der geometrischen Beziehung zweier Kameras mittels Epipolargeometrie
• Vom Kameramodell der Lochkamera zur projektiven Kamera
• Slack-based Traffic Shaping for Real-time Ethernet Networks
• Scheduling Problem and Optimality Metrics
• Rechnerarchitektur des AMD-Ryzen
• New Space: Der neue Aufbruch ins All
• Spectre und Meltdown
   

• Overview of Technologies for Automotive In-Vehicle Networks
• Overview of Strategies for Time-Sensitive Traffic in Ethernet Networks (TSN)
• Concepts and Perspective of Energy-Efficient Ethernet
• RISC V: Instruction Set Architecture
• RISC V Architektur versus ARM-Architektur
• Von SIFT  zu SURF
• GPU: Graphics Processing Unit
• DDRx DRAM - Operation Details and Performance Trends
• Reliability Issues in High-Density DRAMs
• Software Debugging in eingebetteten Echtzeitsystemen
• Wetterballons als Transportvehikel für Kleinsatelliten
• Übersicht Multicore Architekturen
• Strategies for handling transient transmission faults in Real-time Ethernet networks
• Randbedingungen für eine echtzeitfähige Inter-Core Kommunikation
• Anforderungen an einen Benchmark für Netzwerke im Automobil-Bereich
   

• Sensordatenfusion im Automobilbereich
• WCET(m) Estimation in Multi-core Systems using Single Core Equivalence
• Renesas R-Car H2/H3-Familie
• CAmKES: A Component Architecture for Microkernel-bases Embedded Systems
• Basisarchitektur/Basismerkmale der Infineon AURIXTM-TC3xx-Familie
• TRUCK-PLATOONING - technische Voraussetzungen und Anforderungen
• NXP - S32V23x Family of Processors for ADAS
• Herausarbeitung von Problemstellungen zum Einsatz von GPU basierten Rechnerarchitekturen im Forschungsfeld des autonomen Fahrens am Beispiel der NVIDIA Drive PX Plattform (Ausgangsbasis für das geplante "Artifical car computer system" von Bosch)
• Kinematik mobiler Roboter
• Convolutional neural network for Self-Driving Cars
• Sensordatenfusion bei mobilen Robotern (Bayes-/Kalman-Filter)
• CCSDS 123 - Standard
• CCSDS 121 - Standard