Eavesdropping and jamming attacks pose significant security threats to the integrity and availability of 5G mm Wave wireless networks. Although reinforcement learning (RL)-based schemes are considered viable solutions, the most challenging aspect is obtaining accurate training data. This paper proposes a big data-driven, secrecy-aware achievable data rate maximization scheme for a two-tier fifth-generation heterogeneous network (5G-HetNet) to defend against simultaneous eavesdropping and jamming attacks. By leveraging massive data generated in real-time from 5G networks, the proposed approach efficiently handles large-scale optimization challenges. We present a joint optimization problem on power allocation and beamforming for SUs placement, given minimum requirements for secrecy and data rates. We, then transfrom the resulting non-convex problem as a multi-agent reinforcement learning (MARL) problem by utilizing the Markov decision process (MDP). In order to tackle the MDP's large state and action spaces that are inherent in two discrete event-dynamic 5G HetNets, we propose the multiagent deep reinforcement learning (MADRL) scheme in order to jointly optimize data rate and secrecy rates. The proposed approach utilizes a double Q-architecture based double Deep Q Network (DDQN) to jointly solve the beamforming and power allocation vectors for the SUs. We compare our proposed DDQN approach to both Q-learning and DQN in terms of data and secrecy rate performance. The results of our simulations show that our proposed approach significantly improves the attainable secrecy rate by 22 % and 33% compared to DQN and Q-Learning, respectively.
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