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Main Authors: Cengiz, Batuhan, Karagoz, Halil Faruk, Kumbasar, Tufan
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.01266
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author Cengiz, Batuhan
Karagoz, Halil Faruk
Kumbasar, Tufan
author_facet Cengiz, Batuhan
Karagoz, Halil Faruk
Kumbasar, Tufan
contents Recent methods in quantile regression have adopted a classification perspective to handle challenges posed by heteroscedastic, multimodal, or skewed data by quantizing outputs into fixed bins. Although these regression-as-classification frameworks can capture high-density prediction regions and bypass convex quantile constraints, they are restricted by quantization errors and the curse of dimensionality due to a constant number of bins per dimension. To address these limitations, we introduce a conformalized high-density quantile regression approach with a dynamically adaptive set of prototypes. Our method optimizes the set of prototypes by adaptively adding, deleting, and relocating quantization bins throughout the training process. Moreover, our conformal scheme provides valid coverage guarantees, focusing on regions with the highest probability density. Experiments across diverse datasets and dimensionalities confirm that our method consistently achieves high-quality prediction regions with enhanced coverage and robustness, all while utilizing fewer prototypes and memory, ensuring scalability to higher dimensions. The code is available at https://github.com/batuceng/max_quantile .
format Preprint
id arxiv_https___arxiv_org_abs_2411_01266
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Conformalized High-Density Quantile Regression via Dynamic Prototypes-based Probability Density Estimation
Cengiz, Batuhan
Karagoz, Halil Faruk
Kumbasar, Tufan
Machine Learning
Recent methods in quantile regression have adopted a classification perspective to handle challenges posed by heteroscedastic, multimodal, or skewed data by quantizing outputs into fixed bins. Although these regression-as-classification frameworks can capture high-density prediction regions and bypass convex quantile constraints, they are restricted by quantization errors and the curse of dimensionality due to a constant number of bins per dimension. To address these limitations, we introduce a conformalized high-density quantile regression approach with a dynamically adaptive set of prototypes. Our method optimizes the set of prototypes by adaptively adding, deleting, and relocating quantization bins throughout the training process. Moreover, our conformal scheme provides valid coverage guarantees, focusing on regions with the highest probability density. Experiments across diverse datasets and dimensionalities confirm that our method consistently achieves high-quality prediction regions with enhanced coverage and robustness, all while utilizing fewer prototypes and memory, ensuring scalability to higher dimensions. The code is available at https://github.com/batuceng/max_quantile .
title Conformalized High-Density Quantile Regression via Dynamic Prototypes-based Probability Density Estimation
topic Machine Learning
url https://arxiv.org/abs/2411.01266