With the rising of green communication and the upgrading of battery technology, using energy harvesting (EH) nodes as cooperative relays is a promising solution to perpetually power-up wireless sensor networks. In this thesis, we investigate the optimal transmission policies for decode-and-forward (DF) relay networks in which the two-user pairs capable of energy harvesting and a user which has sufficient energy for transmission serving as a relay to the other user whose channel condition is worse. In order to maximize the long-term reward of the system and find out the optimal policies, we formulated this problem as a discounted Markov decision process (MDP) and Q-learning framework. Through designing and adjusting the parameters, we discover that the outage probability is inversely proportional to the solar cell size and battery size. In addition, the numerical results provide that the system tends to do non-cooperation when the signal-to-noise ratio (SNR) approaches to infinity, and at last it also indicate that we could improve the diversity orders to obtain better performance and stimulate the cooperative communication via the reducing the size of energy quantum size.