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Autori principali: Uzun, Engin, Akagunduz, Erdem
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2405.06383
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author Uzun, Engin
Akagunduz, Erdem
author_facet Uzun, Engin
Akagunduz, Erdem
contents Atmospheric turbulence poses a significant challenge to the performance of object detection models. Turbulence causes distortions, blurring, and noise in images by bending and scattering light rays due to variations in the refractive index of air. This results in non-rigid geometric distortions and temporal fluctuations in the electromagnetic radiation received by optical systems. This paper explores the effectiveness of turbulence image augmentation techniques in improving the accuracy and robustness of thermal-adapted and deep learning-based object detection models under atmospheric turbulence. Three distinct approximation-based turbulence simulators (geometric, Zernike-based, and P2S) are employed to generate turbulent training and test datasets. The performance of three state-of-the-art deep learning-based object detection models: RTMDet-x, DINO-4scale, and YOLOv8-x, is employed on these turbulent datasets with and without turbulence augmentation during training. The results demonstrate that utilizing turbulence-specific augmentations during model training can significantly improve detection accuracy and robustness against distorted turbulent images. Turbulence augmentation enhances performance even for a non-turbulent test set.
format Preprint
id arxiv_https___arxiv_org_abs_2405_06383
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle How to Augment for Atmospheric Turbulence Effects on Thermal Adapted Object Detection Models?
Uzun, Engin
Akagunduz, Erdem
Computer Vision and Pattern Recognition
Atmospheric turbulence poses a significant challenge to the performance of object detection models. Turbulence causes distortions, blurring, and noise in images by bending and scattering light rays due to variations in the refractive index of air. This results in non-rigid geometric distortions and temporal fluctuations in the electromagnetic radiation received by optical systems. This paper explores the effectiveness of turbulence image augmentation techniques in improving the accuracy and robustness of thermal-adapted and deep learning-based object detection models under atmospheric turbulence. Three distinct approximation-based turbulence simulators (geometric, Zernike-based, and P2S) are employed to generate turbulent training and test datasets. The performance of three state-of-the-art deep learning-based object detection models: RTMDet-x, DINO-4scale, and YOLOv8-x, is employed on these turbulent datasets with and without turbulence augmentation during training. The results demonstrate that utilizing turbulence-specific augmentations during model training can significantly improve detection accuracy and robustness against distorted turbulent images. Turbulence augmentation enhances performance even for a non-turbulent test set.
title How to Augment for Atmospheric Turbulence Effects on Thermal Adapted Object Detection Models?
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2405.06383