The railway system will continue to integrate global positioning system (GPS), artificial intelligence (AI) and other technologies to improve safety, comfort, affordability and eco-friendliness. This puts forward higher requirements for railway wireless communication network. As a digital counterpart of the virtual railway wireless network, digital twin (DT) can be used as a new paradigm for the construction, operation and maintenance of the railway wireless network. However, the implementation of DT faces many challenges.
Credit: Ke Guan, Xinghai Guo, Danping He, et al.
The railway system will continue to integrate global positioning system (GPS), artificial intelligence (AI) and other technologies to improve safety, comfort, affordability and eco-friendliness. This puts forward higher requirements for railway wireless communication network. As a digital counterpart of the virtual railway wireless network, digital twin (DT) can be used as a new paradigm for the construction, operation and maintenance of the railway wireless network. However, the implementation of DT faces many challenges.
“Accurate and efficient modeling of radio wave propagation and wireless channel over a wide range of frequency bands is the primary challenge in achieving DT,” explains Professor Ke Guan, lead author of a recent review published in High-speed Railway. “In this study, we summarized the key technologies to overcome the challenges, which are mainly divided into scenario modeling, radio wave propagation characterization and integrated operation platform.”
In terms of scenario modeling, three-dimensional (3D) automatic scenario reconstruction can be realized by using point cloud, grid dataset, satellite imaging and oblique photography technology, and the cognition of scenario features can be realized by utilizing deep neural network (DNN). The electromagnetic parameters of the materials in the scenario can be measured by the network parameter method.
For radio wave propagation characterization, the method of ray tracing (RT) technology has been introduced to achieve accurate deterministic modeling of wireless channel, and introduce the environment discretization, visibility preprocessing and geometry-based ray-trajectories derivation methods to deal with the problem of excessive computation. In addition, AI-based super-resolution (SR) was combined with RT to generate a large amount of channel information based on a small amount of simulation dataset, further improving the simulation efficiency.
When it comes to integrated operation platform, a high-performance RT simulation platform named CloudRT has been developed. It supports the simulation of various scenarios, frequency bands, and radio wave propagation mechanisms. Based on the CloudRT, an integrated platform for wireless network planning and optimization has also been introduced, which supports the evaluation of existing deployment solution and the planning of wireless network deployment solution in specific scenarios.
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Contact the author: Ke Guan, State Key Laboratory of Advanced Rail Autonomous Operation & School of Electronic and Information Engineering, Beijing Jiaotong University, 100044, Beijing, China, Email: [email protected]
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Journal
High-speed Railway
DOI
10.1016/j.hspr.2024.01.004
Method of Research
Survey
Subject of Research
Not applicable
Article Title
Key technologies for wireless network digital twin towards smart railways
COI Statement
The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.