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Predictive Analytics of Air Temperature in Alaskan Permafrost Terrain Leveraging Two-Level Signal Decomposition and Deep Learning

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  • Aymane Ahajjam

    (School of Electrical Engineering and Computer Science, University of North Dakota, Grand Forks, ND 58202, USA)

  • Jaakko Putkonen

    (Harold Hamm School of Geology and Geological Engineering, University of North Dakota, Grand Forks, ND 58202, USA)

  • Emmanuel Chukwuemeka

    (Research Institute for Autonomous System, University of North Dakota, Grand Forks, ND 58202, USA)

  • Robert Chance

    (Harold Hamm School of Geology and Geological Engineering, University of North Dakota, Grand Forks, ND 58202, USA)

  • Timothy J. Pasch

    (Department of Communication, University of North Dakota, Grand Forks, ND 58202, USA)

Abstract

Local weather forecasts in the Arctic outside of settlements are challenging due to the dearth of ground-level observation stations and high computational costs. During winter, these forecasts are critical to help prepare for potentially hazardous weather conditions, while in spring, these forecasts may be used to determine flood risk during annual snow melt. To this end, a hybrid VMD-WT-InceptionTime model is proposed for multi-horizon multivariate forecasting of remote-region temperatures in Alaska over short-term horizons (the next seven days). First, the Spearman correlation coefficient is employed to analyze the relationship between each input variable and the forecast target temperature. The most output-correlated input sequences are decomposed using variational mode decomposition (VMD) and, ultimately, wavelet transform (WT) to extract time-frequency patterns intrinsic in the raw inputs. The resulting sequences are fed into a deep InceptionTime model for short-term forecasting. This hybrid technique has been developed and evaluated using 35+ years of data from three locations in Alaska. Different experiments and performance benchmarks are conducted using deep learning models (e.g., Time Series Transformers, LSTM, MiniRocket), and statistical and conventional machine learning baselines (e.g., GBDT, SVR, ARIMA). All forecasting performances are assessed using four metrics: the root mean squared error, the mean absolute percentage error, the coefficient of determination, and the mean directional accuracy. Superior forecasting performance is achieved consistently using the proposed hybrid technique.

Suggested Citation

  • Aymane Ahajjam & Jaakko Putkonen & Emmanuel Chukwuemeka & Robert Chance & Timothy J. Pasch, 2024. "Predictive Analytics of Air Temperature in Alaskan Permafrost Terrain Leveraging Two-Level Signal Decomposition and Deep Learning," Forecasting, MDPI, vol. 6(1), pages 1-26, January.
    • Handle: RePEc:gam:jforec:v:6:y:2024:i:1:p:4-80:d:1315923
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    References listed on IDEAS

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    1. Kwiatkowski, Denis & Phillips, Peter C. B. & Schmidt, Peter & Shin, Yongcheol, 1992. "Testing the null hypothesis of stationarity against the alternative of a unit root : How sure are we that economic time series have a unit root?," Journal of Econometrics, Elsevier, vol. 54(1-3), pages 159-178.
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    1. Chen, Jie & Peng, Tian & Qian, Shijie & Ge, Yida & Wang, Zheng & Nazir, Muhammad Shahzad & Zhang, Chu, 2025. "An error-corrected deep Autoformer model via Bayesian optimization algorithm and secondary decomposition for photovoltaic power prediction," Applied Energy, Elsevier, vol. 377(PD).

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