Abstract
Coordinated Multipoint (CoMP) is one of the key technologies identified for future wireless networks to mitigate inter-cell interference, especially in a dense deployment scenario. However, CoMP can’t be realized for the whole network due to its computational complexity, synchronization between coordinating base stations (BSs) and high backhaul (BH) capacity requirement. BSs need to be clustered into smaller groups and CoMP can be activated within these smaller clusters. In this paper, we develop a multi-objective, dynamic clustering model for multi-user, joint-transmission CoMP to jointly optimize spectral efficiency (SE), radio access network (RAN) load and BH load. We formulate our load-aware model as two coalitional sub-games for small cell and user equipment clustering, respectively. Merge/split/transfer actions for each sub-game are defined and a complexity and stability analysis is provided. Extensive simulation results show that our model provides as good SE in low load when compared to a greedy model, and significantly better load balancing with a reduced number of unsatisfied users and increased throughput in high load scenario. On average 49% increase in the overall system throughput is observed in our simulations when compared to the greedy model.
Highlights
T HE fifth generation (5G) cellular systems are being deployed aiming at 1000 times more capacity than the fourth generation (4G) to cope with increasing mobile data traffic [1]
We have presented a novel low-complexity, multi-objective clustering model in the multi-user joint transmission (MU) joint transmission (JT)-Coordinated Multipoint (CoMP) scenario where spectral efficiency (SE), radio access network (RAN) load and BH load are optimized collectively
Simulation results are compared to a RAN load-aware model (L-GA) and an SE based greedy (SE-GR) algorithm to show the impact of BH awareness
Summary
T HE fifth generation (5G) cellular systems are being deployed aiming at 1000 times more capacity than the fourth generation (4G) to cope with increasing mobile data traffic [1]. Interference mitigation plays an important role in improving the much needed overall capacity, especially in highly interferencelimited 5G dense deployment scenarios [2]. Manuscript received April 3, 2020; revised August 21, 2020 and January 15, 2021; accepted March 15, 2021. Date of publication April 5, 2021; date of current version June 9, 2021. The review of this article was coordinated by Dr S.
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