Teleconsultation dynamic scheduling with a deep reinforcement learning approach

In this study, the start time of teleconsultations is optimized for the clinical departments of class A tertiary hospitals to improve service quality and efficiency. For this purpose, first, a general teleconsultation scheduling model is formulated. In the formulation, the number of services (NS) is one of the objectives because of demand intermittency and service mobility. Demand intermittency means that demand has zero size in several periods. Service mobility means that specialists move between clinical departments and the National Telemedicine Center of China to provide the service. For problem -solving, the general model is converted into a Markov decision process (MDP) by elaborately defining the state, action, and reward. To solve the MDP, deep reinforcement learning (DRL) is applied to overcome the problem of inaccurate transition probability. To reduce the dimensions of the state-action space, a semi -fixed policy is developed and applied to the deep Q network (DQN) to construct an algorithm of the DQN with a semi -fixed policy (DQN-S). For efficient fitting, an early stop strategy is applied in DQN-S training. To verify the effectiveness of the proposed scheduling model and the model solving method DQN-S, scheduling experiments are carried out based on actual data of teleconsultation demand arrivals and service arrangements. The results show that DQN-S can improve the quality and efficiency of teleconsultations by reducing 9%-41% of the demand average waiting time, 3%-42% of the number of services, and 3%-33% of the total cost of services.