Task Offloading Optimization in NOMA-Enabled Multi-hop Mobile Edge Computing System Using Conflict Graph
Resource allocation is investigated for offloading computational-intensive tasks in multi-hop mobile edge computing (MEC) system. The envisioned system has both the cooperative access points (AP) with the computing capability and the MEC servers. A user-device (UD) therefore first uploads a computing task to the nearest AP, and the AP can either locally process the received task or offload to MEC server. In order to utilize the radio resource blocks (RRBs) in the APs efficiently, we exploit the non-orthogonal multiple access for offloading the tasks from the UDs to the AP(s). For the considered NOMA-enabled multi-hop MEC computing system, our objective is to minimize both the latency and energy consumption of the system jointly. Towards this goal, a joint optimization problem is formulated by taking the offloading decision of the APs, the scheduling among the UDs, RRBs, and APs, and UDs' transmit power allocation into account. To solve this problem efficiently, (i) a conflict graph-based approach is devised that solves the scheduling among the UDs, APs, and RRBs, the transmit power control, and the APs' computation resource allocation jointly, and (ii) a low-complexity pruning graph-based approach is also devised. The efficiency of the proposed graph-based approaches over several benchmark schemes is verified via extensive simulations.
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