EMPOWER-6G proposes a break-through converged optical-wireless architecture that makes reality an efficient 6G Cell-Free (CF)-based access network for enabling the requested 1 Tb/s peak data rate and deployments with over 10 million devices/km2 and for supporting new advanced user-services (e.g. holographic telepresence, advanced AR/VR, massive digital twinning, flying networks, etc.). The EMPOWER-6G efforts are channeled towards three ambitious objectives, corresponding to three inter-disciplinary but inter-connected research areas that are further decomposed to 9 specific research challenges:
At the radio edge network level, EMPOWER-6G aims to develop:
1. a scalable CF architecture that offers best-in-class Spectral Efficiency (SE) (within 1dB of the optimum), improved throughput, security, and latency, while maximally exploiting all available distributed resources;
2. a flexible wireless point-to-multipoint mmWave fronthaul solution based on novel hybrid beamforming and beam multicasting schemes, achieving at least double SE due to network densification,
3. a virtualized CF RAN that is aligned with the O-RAN alliance, by considering joint radio and computing resource optimization at the radio edge network, thus achieving at least double per-user UL throughput compared to traditional CF networks
At the regional-edge network level, EMPOWER-6G aims to develop:
1. an optical regional edge network with FTTH support with a significant reduction of the fronthaul cost,
2. regional network configurations based on optimum functional splitting options, that maximize energy efficiency,
3. control-plane protocols at the regional edge for CF networking support that are aligned with the O-RAN, that achieve 20% OPEX reduction
At the network management level, EMPOWER-6G aims to develop solutions for:
1.the orchestration and management of multiple DUs through the design of an efficient resource scheduler, targeting improved user data-rate by a factor of 3,
2. SDN-enabled intelligent traffic management methods and ML-based slice reconfiguration mechanisms, targeting at least 20% energy savings via traffic aggregation;
3. a self-driven virtual elastic infrastructure, based on a novel ETSI-compliant MEC platform and a blockchain-enabled multi-tenant orchestration system¸ targeting zero perceived latency due to multi-domain disaggregation of MEC apps