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Volume 10 Issue 10
Oct.  2023

IEEE/CAA Journal of Automatica Sinica

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Z. X. Li, I. Korovin, X. L. Shi, S. Gorbachev, N. Gorbacheva, W. Huang, and  J. D. Cao,  “A data-driven rutting depth short-time prediction model with metaheuristic optimization for asphalt pavements based on RIOHTrack,” IEEE/CAA J. Autom. Sinica, vol. 10, no. 10, pp. 1918–1932, Oct. 2023. doi: 10.1109/JAS.2023.123192
Citation: Z. X. Li, I. Korovin, X. L. Shi, S. Gorbachev, N. Gorbacheva, W. Huang, and  J. D. Cao,  “A data-driven rutting depth short-time prediction model with metaheuristic optimization for asphalt pavements based on RIOHTrack,” IEEE/CAA J. Autom. Sinica, vol. 10, no. 10, pp. 1918–1932, Oct. 2023. doi: 10.1109/JAS.2023.123192

A Data-Driven Rutting Depth Short-Time Prediction Model With Metaheuristic Optimization for Asphalt Pavements Based on RIOHTrack

doi: 10.1109/JAS.2023.123192
Funds:  This work was supported by the Analytical Center for the Government of the Russian Federation (IGK 000000D730321P5Q0002) and Agreement Nos. (70-2021-00141)
More Information
  • Rutting of asphalt pavements is a crucial design criterion in various pavement design guides. A good road transportation base can provide security for the transportation of oil and gas in road transportation. This study attempts to develop a robust artificial intelligence model to estimate different asphalt pavements’ rutting depth clips, temperature, and load axes as primary characteristics. The experiment data were obtained from 19 asphalt pavements with different crude oil sources on a 2.038 km long full-scale field accelerated pavement test track (Road Track Institute, RIOHTrack) in Tongzhou, Beijing. In addition, this paper also proposes to build complex networks with different pavement rutting depths through complex network methods and the Louvain algorithm for community detection. The most critical structural elements can be selected from different asphalt pavement rutting data, and similar structural elements can be found. An extreme learning machine algorithm with residual correction (RELM) is designed and optimized using an independent adaptive particle swarm algorithm. The experimental results of the proposed method are compared with several classical machine learning algorithms, with predictions of average root mean squared error (MSE), average mean absolute error (MAE), and average mean absolute percentage error (MAPE) for 19 asphalt pavements reaching 1.742, 1.363, and 1.94% respectively. The experiments demonstrate that the RELM algorithm has an advantage over classical machine learning methods in dealing with non-linear problems in road engineering. Notably, the method ensures the adaptation of the simulated environment to different levels of abstraction through the cognitive analysis of the production environment parameters. It is a promising alternative method that facilitates the rapid assessment of pavement conditions and could be applied in the future to production processes in the oil and gas industry.

     

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    Highlights

    • Louvain algorithm is used for community detection to build an equivalent training set
    • A residual correction method is proposed for the Extreme learning machines algorithm
    • Complex network and artificial intelligence algorithms are applied to predict rutting depth

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