6G Open Lab Day Event Map
- 5G Campus Network @ TUM TUM-LKN and CampusGenius - 6G-life
- Technical Sovereignty - an end-to-end startup-product based 5G system TUM and TUD - 6G-life
- 6G Mobility Metaverse (6G-ANNA) TUM-LKN and Nokia - 6G-ANNA
The TUM 5G Campus Network spans parts of the inner city campus, the informatics building in Garching, an outdoor environment in the Garching campus and a robot hall at Georg-Brauchle-Ring. The core network is hosted in the inner city campus and the chair of communication networks (LKN).
Three startups show an end-to-end 5G communication solution to demonstrate technology sovereignty in Germany.
Demonstration of digital twinning as well as in-vehicle subnetworks.
- Molecular Communication TUM-LKN - 6G-life
- Electrical Nose TUD
This testbed showcases how molecules could be used to transmit information in future networks that extend to biological environments, e.g. for laboratory processes or inside the human body.
Demonstration of the detection of smells with a nanomaterial based electrical nose.
- Robot Teleoperation over 5G/6G networks TUM-LKN, TUM-LMT and OliveRobotics - 6G Future Lab Bavaria
- Digital Twin-enabled Seamless Connectivity TUM-LKN, TUM-LMT and aeroLiFi - 6G Future Lab Bavaria
- Robot Teaching via Teleoperation TUM-LMT, CeTI - 6G-life
This demo shows how 6G resource management and network slicing enable a reliable and low latency communication for medical robots.
The demo shows how 6G enables reliable connectivity for industrial robots by using environmental data from a digital twin to dynamically switch between LiFi and RF, preventing communication loss when obstacles like larger robots block access of one technology.
The demo shows a tele-teaching platform for a contact rich robotic skill (rubber band placement), where the bilateral teleoperation with haptic feedback under simulated delay is used as the method to provide the demonstrations, from which the robot learns and performs the task autonomously.
Corridor 1st Floor (1.OG) or outdoor
- Teleoperated mobile sensor platform based on modular robotics components TUM-LKN, TUM-LMT and OliveRobotics - 6G-life
Advanced interoperable embedded sensor system mounted on a legged robot platform enabling immersive teleoperation with low latency sensory data accusiation over 5G communication network powered by Olive Robotics.
- Semantic traffic filtering for robust control TUM-LKN - 6G-life
- EIT-Sleeve for motion profiling TUM-LMT - 6G-life
- Dynamic Environmental Digital Twin TUM-LMT - 6G Future Lab Bavaria
- Context-aware Mobility Management TUM-LKN - 6G Future Lab Bavaria
- mmWave Radar-based Indoor Sensing TUM-LMT - 6G-life
- Cutting the Cord: XR Connectivity with LiFi aeroLiFi, CADAMI and TUM-LKN - 6G-life
Demonstrating that network- and application-aware semantic filtering at the transport layer can ensure the stability of real-time control loops even if they are closed over a congested wireless network.
The demo shows a wearable system that allows monitoring of muscle activites and profiling of human motion. It combines video, electrical impedance tomography and myography.
Our demo shows the ability of our model to reconstruct the environment and adapt to changes accordingly.
We demonstrate the benefits of using context-awareness for mobility management in wireless networks.
In this demostration we provide indoor positioning and non-invasive perception using mmWave radar sensors.
Explore seamless connectivity with our innovative VR headset that integrates both LiFi and WiFi technologies for ultra-fast, low-latency data transmission. Experience enhanced virtual reality performance, combining the best of light and radio wave communication.
- Telemedical Examination and Patient Monitoring in Shared 6G Network Testbed TUM-MITI and TUM-LKN - 6G-life
- Tele-surgical platform at MIRMI TUM-MIRMI - 6G-life
- Wireless Exoskeleton Control - Influences of Communication Networks TUM-ITR - 6G-life
- Telesurgery testbed for robot-assisted surgery: EndoMersion (NCT) TUD - 6G-life
- RGB-D Recording and Evaluation of Robot-Assisted Surgery TUD - 6G-life
Our demonstrator showcases two medical applications, namely the Semiautonomous Examination Suite and Context-Aware Patient Monitoring, using the 6G network and in-network processing capabilities.
The MIRMI telesurgical platform includes patient station with robots around the bed and doctor station with haptic consols. This is a platofm which we would like to illiustrate the perfomance of tactile telesugery over different (wireless) comunication settings.
In this demonstration of a wirelessly controlled elbow exoskeleton, we show how communication networks can significantly influence the performance of robotic systems.
The robotic arm (locaded in Dresden) can be remotely controlled through head movements detected by VR glasses (in Munich), enabling remote surgical procedures and expert consultations.
We show our RGB-D recordings of surgeries and how we will improve robot-assisted surgery with them.
- AI-assisted Load-aware Service Migration in 6G Edge Networks TUM-LIS - 6G Future Lab Bavaria
Reducing processing overloads and high latencies incurred by user mobility and load fluctuations with AI-assisted, load-aware service migration.
- Improving Common Randomness rate using Software Defined Radios TUD - 6G-life
- Adaptive Energy-efficient Computing for Controlling Applications in Network-assisted Driving TUD - 6G-life
- Touch the Metaverse: Demonstration of Haptic Feedback in Network-Assisted Augmented Reality TUD- 6G-life
Using novel filter design, we demonstrate how common randomness (CR), a crucial future communication resource, can be generated at a near capacity level in future communication systems.
Demonstration of adaptive, energy-efficient self-driving car control enabled by in-network computing.
Demonstration of Haptic Feedback in Network-Assisted AR.
- Anomaly detection in 6G core networks UniBW - 6G-life
- Circuit Sabotage: Demonstrating the Impact of Hardware Trojan Attacks TUM-SEC - 6G Future Lab Bavaria
- Physical Layer Security TUM-LTI - 6G-life and 6G Future Lab Bavaria
- ComplAIn: Using AI to Talk to Industrial Robots, Simulations and Communication Equipment TUM-LTI - 6G-life
- DTain: Monitoring and Controlling Robotic Fleets in Both Real and Digital Worlds TUM-LTI - 6G-life
- Scalable Wideband ISAC Implementation With RFSoC TUM-LTI - 6G-life
- NeuroWireless: Power-Efficient Neuromorphic Algorithms for Wireless Signal Processing TUM-LTI - 6G-life
The demo shows the automatic deployment of a 6G core network and the simulation of user equipment, attacks on the 6G core network and the detection of these attacks with temporal graph neural networks.
Log in to our ASIC-IoT microcontroller without knowing the right password, spy the cryptographic key, and perform a DoS-Attack using tiny hardware implants.
This demo shows physical layer security in a wiretap channel using a seeded modular coding scheme.
We demonstrate how state-of-the-art LLMs can help in planning experiments, instructing robots and analyzing PHY-layer data via natural language.
We demonstrate how AI-and sensing assisted digital twins can help in controlling future industrial robots.
We implement a scalable wideband integrated sensing and communication (ISAC) system with OFDM and FMCW signaling on RFSoC, and demonstrate its performance under a high-mobility scenario with an FPGA-based channel emulator.
We investigate the energy-and power-saving potential of neuromorphic computing by comparing the novel, lightweight Spinnaker2 board with an NVIDIA embedded GPU.
- mmWave Physical Layer Security TUM-LTI - 6G-life and 6G Future Lab Bavaria
- JCAS From the Sky TUM-LTI - 6G-life
- Post-Shannon Communications TUM-LTI - 6G-life and 6G Future Lab Bavaria
- Absorberkammer TUM-LTI - 6G-life
We demonstrate physical layer security in a mmWave frequency range.
The simulation shows how a drone can increase the functionality and efficiency of 6G networks by capturing and transmitting real-time environmental data while following a flexible mission plan.
We demonstrate an implementation of randomized and deterministic identification codes.
Anechoic chamber for undisturbed radio signal measurements.