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Time series forecasting for nonlinear and non-stationary processes: a review and comparative study

Author

Listed:
  • Changqing Cheng
  • Akkarapol Sa-Ngasoongsong
  • Omer Beyca
  • Trung Le
  • Hui Yang
  • Zhenyu (James) Kong
  • Satish T.S. Bukkapatnam

Abstract

Forecasting the evolution of complex systems is noted as one of the 10 grand challenges of modern science. Time series data from complex systems capture the dynamic behaviors and causalities of the underlying processes and provide a tractable means to predict and monitor system state evolution. However, the nonlinear and non-stationary dynamics of the underlying processes pose a major challenge for accurate forecasting. For most real-world systems, the vector field of state dynamics is a nonlinear function of the state variables; i.e., the relationship connecting intrinsic state variables with their autoregressive terms and exogenous variables is nonlinear. Time series emerging from such complex systems exhibit aperiodic (chaotic) patterns even under steady state. Also, since real-world systems often evolve under transient conditions, the signals obtained therefrom tend to exhibit myriad forms of non-stationarity. Nonetheless, methods reported in the literature focus mostly on forecasting linear and stationary processes. This article presents a review of these advancements in nonlinear and non-stationary time series forecasting models and a comparison of their performances in certain real-world manufacturing and health informatics applications. Conventional approaches do not adequately capture the system evolution (from the standpoint of forecasting accuracy, computational effort, and sensitivity to quantity and quality of a priori information) in these applications.

Suggested Citation

  • Changqing Cheng & Akkarapol Sa-Ngasoongsong & Omer Beyca & Trung Le & Hui Yang & Zhenyu (James) Kong & Satish T.S. Bukkapatnam, 2015. "Time series forecasting for nonlinear and non-stationary processes: a review and comparative study," IISE Transactions, Taylor & Francis Journals, vol. 47(10), pages 1053-1071, October.
    • Handle: RePEc:taf:uiiexx:v:47:y:2015:i:10:p:1053-1071
    DOI: 10.1080/0740817X.2014.999180
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    Cited by:

    1. Fu, Ke & Li, He & Deng, Pengfei, 2022. "Chaotic time series prediction using DTIGNet based on improved temporal-inception and GRU," Chaos, Solitons & Fractals, Elsevier, vol. 159(C).
    2. Kristof Lommers & Ouns El Harzli & Jack Kim, 2021. "Confronting Machine Learning With Financial Research," Papers 2103.00366, arXiv.org, revised Mar 2021.
    3. Jie Fang & Shutao Xia & Jianwu Lin & Yong Jiang, 2019. "Automatic Financial Feature Construction," Papers 1912.06236, arXiv.org, revised Oct 2020.
    4. Iraj Daizadeh, 2021. "Leveraging latent persistency in United States patent and trademark applications to gain insight into the evolution of an innovation-driven economy," Papers 2101.02588, arXiv.org, revised May 2021.
    5. Hyunsoo Lee, 2019. "Development of Sustainable Recycling Investment Framework Considering Uncertain Demand and Nonlinear Recycling Cost," Sustainability, MDPI, vol. 11(14), pages 1-18, July.
    6. Wang, Chao & Zhang, Xinyi & Wang, Minggang & Lim, Ming K. & Ghadimi, Pezhman, 2019. "Predictive analytics of the copper spot price by utilizing complex network and artificial neural network techniques," Resources Policy, Elsevier, vol. 63(C), pages 1-1.
    7. Vaia I. Kontopoulou & Athanasios D. Panagopoulos & Ioannis Kakkos & George K. Matsopoulos, 2023. "A Review of ARIMA vs. Machine Learning Approaches for Time Series Forecasting in Data Driven Networks," Future Internet, MDPI, vol. 15(8), pages 1-31, July.
    8. Ozdemir, Ali Can & Buluş, Kurtuluş & Zor, Kasım, 2022. "Medium- to long-term nickel price forecasting using LSTM and GRU networks," Resources Policy, Elsevier, vol. 78(C).
    9. Zhou, Hanchu & Chang, Fangrong, 2022. "The long-memory temporal dependence of traffic crash fatality for different types of road users," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 607(C).
    10. Shree Krishna Acharya & Hwanuk Yu & Young-Min Wi & Jaehee Lee, 2024. "Multihousehold Load Forecasting Based on a Convolutional Neural Network Using Moment Information and Data Augmentation," Energies, MDPI, vol. 17(4), pages 1-18, February.
    11. Massimiliano Giacalone, 2022. "Optimal forecasting accuracy using Lp-norm combination," METRON, Springer;Sapienza Università di Roma, vol. 80(2), pages 187-230, August.
    12. George Kosgei Kiptum, 2022. "Relationship between Kenya’s economic growth and inflation," SN Business & Economics, Springer, vol. 2(12), pages 1-16, December.
    13. Tasquia Mizan & Sharareh Taghipour, 2021. "A causal model for short‐term time series analysis to predict incoming Medicare workload," Journal of Forecasting, John Wiley & Sons, Ltd., vol. 40(2), pages 228-242, March.
    14. Jia, Xiongjie & Sang, Yichen & Li, Yanjun & Du, Wei & Zhang, Guolei, 2022. "Short-term forecasting for supercharged boiler safety performance based on advanced data-driven modelling framework," Energy, Elsevier, vol. 239(PE).
    15. Du, Pei & Wang, Jianzhou & Yang, Wendong & Niu, Tong, 2020. "Point and interval forecasting for metal prices based on variational mode decomposition and an optimized outlier-robust extreme learning machine," Resources Policy, Elsevier, vol. 69(C).
    16. Lagomarsino-Oneto, Daniele & Meanti, Giacomo & Pagliana, Nicolò & Verri, Alessandro & Mazzino, Andrea & Rosasco, Lorenzo & Seminara, Agnese, 2023. "Physics informed machine learning for wind speed prediction," Energy, Elsevier, vol. 268(C).

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