During RP1, the project achieved significant scientific and technical progress across all WPs.
-Data-driven analysis of spatial and temporal traffic demands in representative 6G NTC scenarios. Traffic hotspots and environment types have been automatically identified from GIS data, satellite imagery, and operator traffic traces using machine-learning-based semantic segmentation and clustering techniques. These spatial-temporal predictions will be used to identify where UAVs should be positioned, based on where traffic demand is expected to increase.
- Realistic 3D channel and sensing models for both NTC and NTS combining deterministic ray-tracing, measurement-driven simulations, mathematical methods, and machine-learning-assisted stochastic models. The resulting models capture different UAV altitudes, mobility patterns, channel conditions, as well as clutter, Doppler, delay spread, and multi-path effects for sub-6 GHz, mmWave, and sub-THz bands.
- Efficient standalone designs for NTC and NTS. For communications, reliable transmission strategies have been evaluated using the newly established channel models. In parallel, UAV-assisted sensing designs have exploited bi-static UAV-ground geometries, mobility-aware waveform selection, metasurface/RIS systems, and computer-vision perception data to accurately characterize targets and environments.
- Algorithms and signal-processing techniques for integrated NTC and NTS. Dual-functional ISAC waveforms and beamforming strategies have been designed to jointly satisfy communication and sensing performance requirements in mixed near- and far-field scenarios, possibly using RIS systems. The results have demonstrated the feasibility of robust NTC-NTS ISAC operations.
- Sensing-assisted communication. Early designs have demonstrated how UAV-based sensing information can be exploited to enhance communication decisions, for example adapt beamforming, resource allocation, scheduling, and handover in integrated NTC-NTS systems, laying the groundwork for closed-loop sensing-driven communication architectures to be completed in the second half of the project.