toplogo
سجل دخولك
رؤى - Computational Complexity - # Evaluating two-sample tests for validating generative models

Evaluating Two-Sample Tests for Validating Generative Models in Precision Sciences


المفاهيم الأساسية
This work proposes a robust methodology to evaluate the performance and computational efficiency of non-parametric two-sample tests for validating high-dimensional generative models in scientific applications such as particle physics.
الملخص

The paper proposes a robust methodology to evaluate the performance and computational efficiency of non-parametric two-sample tests for validating high-dimensional generative models in scientific applications.

The study focuses on tests built from univariate integral probability measures: the sliced Wasserstein distance, the mean of the Kolmogorov-Smirnov statistics, and a novel sliced Kolmogorov-Smirnov statistic. These metrics can be evaluated in parallel, allowing for fast and reliable estimates of their distribution under the null hypothesis.

The authors also compare these metrics with the recently proposed unbiased Fréchet Gaussian Distance and the unbiased quadratic Maximum Mean Discrepancy, computed with a quartic polynomial kernel.

The proposed tests are evaluated on various distributions, including correlated Gaussians, mixtures of Gaussians in 5, 20, and 100 dimensions, and a particle physics dataset of gluon jets from the JetNet dataset, considering both jet- and particle-level features.

The results demonstrate that one-dimensional-based tests provide a level of sensitivity comparable to other multivariate metrics, but with significantly lower computational cost, making them ideal for evaluating generative models in high-dimensional settings. The methodology offers an efficient, standardized tool for model comparison and can serve as a benchmark for more advanced tests, including machine-learning-based approaches.

edit_icon

تخصيص الملخص

edit_icon

إعادة الكتابة بالذكاء الاصطناعي

edit_icon

إنشاء الاستشهادات

translate_icon

ترجمة المصدر

visual_icon

إنشاء خريطة ذهنية

visit_icon

زيارة المصدر

الإحصائيات
The standard deviation of the features can be scaled by a random vector drawn from a uniform distribution between 1 and 1+ϵ. A fraction ϵ of each component of the reference model can be shuffled independently relative to the others. A random vector with entries drawn from a uniform distribution in the interval [-ϵ, ϵ] can be added to each point from the reference model to modify its mean.
اقتباسات
"This methodology offers an efficient, standardized tool for model comparison and can serve as a benchmark for more advanced tests, including machine-learning-based approaches." "The results demonstrate that one-dimensional-based tests provide a level of sensitivity comparable to other multivariate metrics, but with significantly lower computational cost, making them ideal for evaluating generative models in high-dimensional settings."

الرؤى الأساسية المستخلصة من

by Samuele Gros... في arxiv.org 09-26-2024

https://arxiv.org/pdf/2409.16336.pdf
Refereeing the Referees: Evaluating Two-Sample Tests for Validating Generators in Precision Sciences

استفسارات أعمق

How can the proposed methodology be extended to incorporate more advanced machine learning-based two-sample tests?

The proposed methodology for evaluating two-sample tests can be extended to incorporate advanced machine learning (ML)-based approaches by integrating classifiers that leverage deep learning architectures to model complex relationships in high-dimensional data. One potential direction is to utilize generative adversarial networks (GANs) or variational autoencoders (VAEs) to learn the underlying distributions of the data more effectively. These models can be trained to generate synthetic samples that closely resemble the reference distribution, allowing for a more nuanced comparison against alternative hypotheses. Additionally, the methodology can be enhanced by employing ensemble learning techniques, where multiple ML models are combined to improve robustness and accuracy in detecting distributional differences. For instance, stacking various classifiers that utilize different feature extraction methods or kernel functions can provide a comprehensive view of the data's structure. Furthermore, incorporating unsupervised learning techniques, such as clustering or dimensionality reduction (e.g., t-SNE or UMAP), can help identify latent structures and dependencies that traditional tests may overlook. To facilitate this integration, the evaluation framework can be adapted to include performance metrics specific to ML models, such as area under the ROC curve (AUC) or F1 scores, alongside traditional statistical measures. This hybrid approach would not only enhance the sensitivity of the tests to complex data patterns but also provide a more interpretable framework for practitioners in fields like particle physics, biology, and finance.

What are the limitations of the one-dimensional-based tests in capturing higher-order correlations and complex dependencies in the data?

One-dimensional-based tests, while computationally efficient and effective in many scenarios, have inherent limitations in capturing higher-order correlations and complex dependencies within high-dimensional data. These tests typically rely on marginal distributions, which means they assess differences in distributions along individual dimensions without considering interactions between them. As a result, they may fail to detect subtle yet significant relationships that arise from the joint behavior of multiple variables. For instance, in cases where the data exhibits intricate structures, such as non-linear relationships or multi-modal distributions, one-dimensional tests may yield misleading results. They can overlook the effects of correlations that exist between dimensions, leading to an underestimation of the differences between the reference and alternative distributions. This limitation is particularly pronounced in high-dimensional settings, where the curse of dimensionality can exacerbate the challenges of accurately modeling and interpreting data. Moreover, one-dimensional tests may not adequately account for the presence of outliers or noise, which can disproportionately influence the results. In contrast, multivariate tests that consider the joint distribution of data points are better suited to capture these complexities, providing a more comprehensive assessment of the underlying relationships in the data.

How can the insights from this work on evaluating generative models be applied to other domains beyond particle physics, such as in biology or finance, where high-dimensional data and precise modeling are also critical?

The insights gained from this work on evaluating generative models can be effectively applied to various domains beyond particle physics, including biology and finance, where high-dimensional data and precise modeling are crucial. In biology, for instance, the evaluation of generative models can enhance the analysis of genomic data, where researchers often deal with high-dimensional datasets that capture complex biological processes. By employing the proposed two-sample testing methodology, scientists can rigorously assess the fidelity of generative models used to simulate biological phenomena, such as gene expression patterns or protein interactions. In finance, the ability to model and validate generative processes is essential for risk assessment and portfolio optimization. The proposed methodology can be utilized to evaluate models that generate synthetic financial data, allowing analysts to compare the generated data against historical market data. This comparison can help identify discrepancies and improve the robustness of financial models, ultimately leading to better decision-making in investment strategies. Furthermore, the framework's emphasis on computational efficiency and sensitivity to distributional changes can be beneficial in real-time applications, such as fraud detection or anomaly detection in transaction data. By adapting the two-sample testing approach to these domains, practitioners can develop more reliable models that account for the complexities inherent in high-dimensional datasets, thereby enhancing the overall accuracy and interpretability of their analyses.
0
star