Abstract
Multicasting in wireless systems is a natural way to exploit the redundancy in user requests in a content centric network. Power control and optimal scheduling can significantly improve the wireless multicast network’s performance under fading. However, the model-based approaches for power control and scheduling studied earlier are not scalable to large state spaces or changing system dynamics. In this paper, we use deep reinforcement learning, where we use function approximation of the Q-function via a deep neural network to obtain a power control policy that matches the optimal policy for a small network. We show that power control policy can be learned for reasonably large systems via this approach. Further, we use multi-timescale stochastic optimization to maintain the average power constraint. We demonstrate that a slight modification of the learning algorithm allows tracking of time varying system statistics. Finally, we extend the multi-time scale approach to simultaneously learn the optimal queuing strategy along with power control. We demonstrate the scalability, tracking and cross-layer optimization capabilities of our algorithms via simulations. The proposed multi-time scale approach can be used in general large state-space dynamical systems with multiple objectives and constraints, and may be of independent interest.
Highlights
Content services, such as Netflix, Prime Video, etc., have dramatically increased the demand for high-definition videos over mobile networks
We propose a constrained optimization variant of deep Q network (DQN) based on multi-timescale stochastic gradient descent [9] for power control, which can track the system statistics
We show that the deep learning algorithm, adaptive constrained DQN (AC-DQN), achieves the global optimum obtained by the mesh adaptive direct search (MADS)
Summary
Content services, such as Netflix, Prime Video, etc., have dramatically increased the demand for high-definition videos over mobile networks. Almost 78% of mobile data traffic is expected to be due to these mobile videos [1]. It is observed that the request traffic for these contents have multiple redundant requests [2]. Generation wireless networks are being constantly upgraded to satisfy these exploding demands by exploiting the nature of the request traffic. Serving the redundant requests simultaneously is a natural way to utilize network resources efficiently. Efficient multicasting is studied widely in the wireless networking community
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