Generalization Investigation for Artificial Intelligence-Based Positioning in IIoT

Abstract

In recent years, IIoT scenarios show increasing demand for high-precision positioning. Cellular-based positioning plays a very important role in this application area. The cellular-based positioning system can be categorized as an asymmetric processing system. In this system, multiple base stations transmit positioning reference signaling to one device and the device derives its coordinates based on the measurement of the positioning reference signal by using certain positioning algorithms. The classical positioning algorithms encounter great challenges in satisfying the stringent precision requirement. Meanwhile, artificial intelligence (AI)-based positioning solutions draw great attention due to their strong ability in improving positioning accuracy in IIoT scenarios. For AI-based algorithms, generalization capability is one important metric. It demonstrates the ability to adapt to different environments. However, there is little literature touching on the investigation of generalization capability. In this article, we will tackle this issue by considering typical features in IIoT scenarios including the clutter distribution, network synchronization error, and receiving timing error. The impact of these typical features on the generalization capability is firstly evaluated and then the feasibility of existing popular generalization improvement solutions, i.e., optimized training data set and fine-tuning are tested under different cases. At last, directions to further guarantee the generalization capability are presented. The results of this article provide useful experience for developing AI models for positioning in realistic IIoT scenarios.