Bibliographic Information: Urettini, E., Atzeni, D., Ramjattan, R. J., & Carta, A. (2024). GAS-Norm: Score-Driven Adaptive Normalization for Non-Stationary Time Series Forecasting in Deep Learning. In Proceedings of the 33rd ACM International Conference on Information and Knowledge Management (CIKM ’24), October 21–25, 2024, Boise, ID, USA. ACM, New York, NY, USA, 10 pages. https://doi.org/10.1145/3627673.3679822
Research Objective: This paper investigates the challenge of applying deep neural networks (DNNs) to non-stationary time series forecasting and proposes a novel normalization method, GAS-Norm, to improve their performance.
Methodology: The authors first demonstrate the vulnerability of DNNs to non-stationary data through a simple experiment with a Lorenz attractor. They then introduce GAS-Norm, which combines a Generalized Autoregressive Score (GAS) model with DNNs. The GAS model filters and predicts time-varying means and variances, enabling adaptive normalization of the input data and denormalization of the DNN's predictions. The authors evaluate GAS-Norm's performance against other normalization techniques on synthetic and real-world datasets using various DNN architectures.
Key Findings: GAS-Norm consistently outperforms other normalization methods, including Global Norm, Local Norm, Batch Normalization, and RevIN, across various datasets and DNN architectures. The method proves particularly effective in handling non-stationary data with changing means and variances, leading to more accurate forecasts.
Main Conclusions: GAS-Norm effectively addresses the limitations of DNNs in handling non-stationary time series data by providing adaptive normalization and denormalization capabilities. This approach leverages the strengths of both statistical modeling (GAS) and deep learning, resulting in improved forecasting accuracy.
Significance: This research contributes a novel and effective method for improving the performance of deep learning models in time series forecasting, particularly in challenging non-stationary environments.
Limitations and Future Research: While GAS-Norm demonstrates significant improvements, the authors acknowledge that further enhancements are possible. Future research could explore incorporating seasonal GAS models and tailoring distributional assumptions for specific data characteristics.
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by Edoardo Uret... في arxiv.org 10-08-2024
https://arxiv.org/pdf/2410.03935.pdfاستفسارات أعمق