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StiefelGen: Time Series Data Augmentation Approach


Kernekoncepter
StiefelGen proposes a novel approach to time series data augmentation by leveraging the Stiefel manifold, allowing for precise control over signal perturbations. The method offers flexibility in emphasizing noise or basis function deformations, tailored to specific data generation needs.
Resumé

StiefelGen introduces a unique methodology for time series data augmentation, addressing limitations in existing approaches. By traversing geodesic paths on the Stiefel manifold, the method enables controlled signal perturbations for both data augmentation and outlier detection tasks. The framework's interpretability and customization options make it a valuable tool for various applications, including structural health monitoring.

Data sets like SteamGen and New York Taxi are used to demonstrate the effectiveness of StiefelGen in generating synthetic data. The method's ability to separate noise and basis-driven deformations allows for precise adjustment of signals, avoiding trivial or catastrophic changes. Applications in structural health monitoring showcase how StiefelGen can enhance robustness analysis and adversarial data generation tasks.

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Statistik
Substantial data currently exists within these sub-fields. For instance, in CV, common techniques include stretching, flipping, cropping. More recently, there have been innovations seen in mix-up strategies for data augmentation. Despite the recent success of the aforementioned approaches for synthetic data generation. This lack of focus can be partially attributed to the difficulties within the inherent temporal dependency structures within the time series tasks.
Citater
"StiefelGen introduces a novel approach to time series data augmentation by leveraging matrix differential geometry." "The method offers flexibility in emphasizing noise or basis function deformations based on specific needs."

Vigtigste indsigter udtrukket fra

by Prasad Cheem... kl. arxiv.org 03-01-2024

https://arxiv.org/pdf/2402.19287.pdf
StiefelGen

Dybere Forespørgsler

How does StiefelGen compare to traditional methods of time series data augmentation

StiefelGen offers a unique approach to time series data augmentation compared to traditional methods. Traditional approaches often involve direct modifications to the underlying signal in either the time or frequency domains, such as jittering, magnitude alterations, signal warping, and signal flipping. However, these methods have limitations that StiefelGen aims to address. StiefelGen leverages the matrix differential geometry of the Stiefel manifold to provide tailored levels of aleatoric and epistemic uncertainty by traversing geodesic curves in matrix space. This allows for precise control over signal perturbations while maintaining interpretability and model-agnostic nature. Unlike traditional methods that may focus on adding noise or altering magnitudes without considering the underlying structure of the data, StiefelGen works with structured matrices and separates noise-driven deformations from basis function-driven deformations. In essence, StiefelGen provides a more nuanced and flexible approach to time series data augmentation by leveraging geometric properties and offering fine-grained control over signal perturbations based on specific requirements.

What are the implications of using geodesics on the Stiefel manifold for signal perturbations

Using geodesics on the Stiefel manifold for signal perturbations has significant implications for controlling deviations in time series signals. Geodesics represent paths of shortest distance between two points on a curved surface like the Stiefel manifold. By traversing geodesics over this manifold, one can smoothly adjust deformations in signals without leaving the manifold's constraints. This means that when applying StiefelGen for generating synthetic data or augmenting existing datasets, users can precisely control how much deviation is introduced into their signals along well-defined paths on the manifold. The ability to smoothly transition between different states of a signal ensures that generated instances are realistic yet distinct from original data points. Furthermore, working with geodesics allows for incremental adjustments along these paths, enabling fine-tuning of signal perturbations until reaching desired outcomes. This level of precision and flexibility in manipulating signals sets StiefelGen apart from conventional methods where deviations may not be as controlled or interpretable.

How can StiefelGen be applied to other fields beyond structural health monitoring

StiefelGen's application extends beyond structural health monitoring (SHM) into various other fields due to its versatile nature and unique capabilities in generating synthetic data over Riemannian manifolds like the Stiefel manifold. One potential application is in natural language processing (NLP), where time series analysis plays a crucial role in tasks such as sentiment analysis or text generation. By using StiefenlGen to generate diverse variations of textual sequences while preserving semantic meaning through controlled perturbations along geodesics, NLP models could benefit from enhanced training datasets leading to improved performance. Additionally, applications in financial forecasting could leverage Stieflgen's ability to create novel instances within historical stock price movements or economic indicators' trends while ensuring realistic fluctuations align with market dynamics accurately. Overall, the versatility and robustness of Steifgen make it applicable across various industries seeking innovative ways to enhance their machine learning models through sophisticated data augmentation techniques.
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