Distributed DDPG-Based Resource Allocation for Age of Information Minimization in Mobile Wireless-Powered Internet of Things
Kechen Zheng, Rongwei Luo, Xiaoying Liu, Jiefan Qiu, Jia Liu
Abstract
As a vital metric of information timeliness, age of information (AoI) is important for real-time applications in Internet of Things (IoT), such as health monitoring. To satisfy these requirements, we study a wireless-powered IoT (WPIoT), where a static hybrid access point (HAP) coordinates the wireless energy transfer to mobile IoT nodes, and mobile IoT nodes transmit data to the HAP or static IoT nodes. We minimize the AoI of mobile IoT nodes by optimizing the selection of the HAP or static IoT node for transmission, the channel selection, the duration of data transmission, and the transmit power, and prove the AoI minimization problem as NP-hard. To tackle it, we propose a deep deterministic policy gradient (DDPG)-based distributed multi-node resource allocation (DDMRA) algorithm, which combines the advantages of distributed algorithms and centralized algorithms, and combines the selection of discrete actions in the DQN algorithm into the DDPG algorithm. In the DDMRA algorithm, mobile IoT nodes save the energy consumption of transmitting state information to the HAP. Numerical results validate the superior performance of the DDMRA algorithm compared with baseline algorithms.