TimeAPN: Adaptive Amplitude-Phase Non-Stationarity Normalization for Time Series Forecasting
arXiv:2603.17436v1 Announce Type: new Abstract: Non-stationarity is a fundamental challenge in multivariate long-term time series forecasting, often manifested as rapid changes in amplitude and phase. These variations lead to severe distribution shifts and consequently degrade predictive performance. Existing normalization-based methods primarily rely on first- and second-order statistics, implicitly assuming that distributions evolve smoothly and overlooking fine-grained temporal dynamics. To address these limitations, we propose TimeAPN, an Adaptive Amplitude-Phase Non-Stationarity Normalization framework that explicitly models and predicts non-stationary factors from both the time and frequency domains. Specifically, TimeAPN first models the mean sequence jointly in the time and frequency domains, and then forecasts its evolution over future horizons. Meanwhile, phase information is extracted in the frequency domain, and the phase discrepancy between the predicted and ground-truth
arXiv:2603.17436v1 Announce Type: new Abstract: Non-stationarity is a fundamental challenge in multivariate long-term time series forecasting, often manifested as rapid changes in amplitude and phase. These variations lead to severe distribution shifts and consequently degrade predictive performance. Existing normalization-based methods primarily rely on first- and second-order statistics, implicitly assuming that distributions evolve smoothly and overlooking fine-grained temporal dynamics. To address these limitations, we propose TimeAPN, an Adaptive Amplitude-Phase Non-Stationarity Normalization framework that explicitly models and predicts non-stationary factors from both the time and frequency domains. Specifically, TimeAPN first models the mean sequence jointly in the time and frequency domains, and then forecasts its evolution over future horizons. Meanwhile, phase information is extracted in the frequency domain, and the phase discrepancy between the predicted and ground-truth future sequences is explicitly modeled to capture temporal misalignment. Furthermore, TimeAPN incorporates amplitude information into an adaptive normalization mechanism, enabling the model to effectively account for abrupt fluctuations in signal energy. The predicted non-stationary factors are subsequently integrated with the backbone forecasting outputs through a collaborative de-normalization process to reconstruct the final non-stationary time series. The proposed framework is model-agnostic and can be seamlessly integrated with various forecasting backbones. Extensive experiments on seven real-world multivariate datasets demonstrate that TimeAPN consistently improves long-term forecasting accuracy across multiple prediction horizons and outperforms state-of-the-art reversible normalization methods.
Executive Summary
TimeAPN is a novel adaptive amplitude-phase non-stationarity normalization framework proposed to address the challenges of non-stationarity in multivariate long-term time series forecasting. The framework explicitly models and predicts non-stationary factors from both the time and frequency domains, incorporating amplitude and phase information to account for abrupt fluctuations and temporal misalignment. TimeAPN demonstrates improved long-term forecasting accuracy across multiple prediction horizons and outperforms state-of-the-art reversible normalization methods in extensive experiments on seven real-world multivariate datasets. Its model-agnostic design enables seamless integration with various forecasting backbones, rendering it a promising solution for tackling non-stationarity in time series forecasting. The framework has significant implications for applications in finance, energy, and climate modeling, where accurate long-term forecasting is crucial.
Key Points
- ▸ TimeAPN explicitly models and predicts non-stationary factors from both the time and frequency domains.
- ▸ The framework incorporates amplitude and phase information to account for abrupt fluctuations and temporal misalignment.
- ▸ TimeAPN demonstrates improved long-term forecasting accuracy across multiple prediction horizons.
Merits
Strength in Addressing Non-Stationarity
TimeAPN's explicit modeling of non-stationary factors from both the time and frequency domains enables effective handling of abrupt fluctuations and temporal misalignment, enhancing long-term forecasting accuracy.
Model-Agnostic Design
The framework's model-agnostic design allows for seamless integration with various forecasting backbones, making it a versatile solution for tackling non-stationarity in time series forecasting.
Improved Forecasting Accuracy
TimeAPN's incorporation of amplitude and phase information and its collaborative de-normalization process enable improved long-term forecasting accuracy across multiple prediction horizons.
Demerits
Computational Complexity
TimeAPN's explicit modeling of non-stationary factors and its collaborative de-normalization process may introduce additional computational complexity, potentially impacting its scalability and efficiency.
Assumption of Stationarity in Frequency Domain
The framework's assumption of stationarity in the frequency domain may not hold in all cases, potentially affecting the accuracy of its predictions.
Expert Commentary
TimeAPN is a significant contribution to the field of time series forecasting, addressing the fundamental challenge of non-stationarity in multivariate long-term forecasting. The framework's explicit modeling of non-stationary factors from both the time and frequency domains, its incorporation of amplitude and phase information, and its collaborative de-normalization process enable improved long-term forecasting accuracy. While TimeAPN's computational complexity and assumption of stationarity in the frequency domain represent potential limitations, its model-agnostic design and versatility make it a promising solution for tackling non-stationarity in time series forecasting. As the field continues to evolve, it will be essential to explore the applicability of TimeAPN to other domains and to further develop its potential for real-world applications.
Recommendations
- ✓ Future research should focus on exploring the applicability of TimeAPN to other domains and on developing more efficient and scalable implementations of the framework.
- ✓ The development of more effective normalization techniques, such as those that account for non-linear relationships and non-stationarity in the frequency domain, is essential for improving the accuracy of time series forecasting models.
