Abstract
As the 4th industrial revolution using information becomes an issue, wireless communication technologies such as the Internet of Things have been spotlighted. Therefore, much research is needed to satisfy the technological demands for the future society. A LPWA (low power wide area) in the wireless communication environment enables low-power, long-distance communication to meet various application requirements that conventional wireless communications have been difficult to meet. We propose a method to consume the minimum transmission power relative to the maximum data rate with the target of LoRaWAN among LPWA networks. Reinforcement learning is adopted to find the appropriate parameter values for the minimum transmission power. With deep reinforcement learning, we address the LoRaWAN problem with the goal of optimizing the distribution of network resources such as spreading factor, transmission power, and channel. By creating a number of deep reinforcement learning agents that match the terminal nodes in the network server, the optimal transmission parameters are provided to the terminal nodes. The simulation results show that the proposed method is about 15% better than the existing ADR (adaptive data rate) MAX of LoRaWAN in terms of throughput relative to energy transmission.
Highlights
As the 4th industrial revolution using information becomes an issue, information and communication technologies such as the IoT (Internet of Things), big data, and AI have become popular around the world
The contributions of our proposed method are as follows: (1) we considered the throughput of nodes and the energy efficiency of nodes; (2) we considered the distances among the nodes and gateway, and we grouped the nodes by distance and their samples are learned on the same agent; and (3) if the sufficient learning is done, our methods provide the appropriate parameters immediately
In Algorithm 1, adaptive data rate (ADR) collects approximately 20 packets and determines spreading factor (SF) and transmission power (TP) based on the collected signal-to-noise ratio (SNR)
Summary
As the 4th industrial revolution using information becomes an issue, information and communication technologies such as the IoT (Internet of Things), big data, and AI (artificial intelligence) have become popular around the world. The scale of the IoT will increase in the few years, and the current wireless communication environment will not be able to meet the demands of society. It is necessary to research the Internet of Things to meet the demands of the future society. Even if the number of connected devices is large, there is an IoT environment in which the amount of data generated by each device is relatively small.
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