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Main Authors: Elharrouss, Omar, Mahmood, Yasir, Bechqito, Yassine, Serhani, Mohamed Adel, Badidi, Elarbi, Riffi, Jamal, Tairi, Hamid
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.04242
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author Elharrouss, Omar
Mahmood, Yasir
Bechqito, Yassine
Serhani, Mohamed Adel
Badidi, Elarbi
Riffi, Jamal
Tairi, Hamid
author_facet Elharrouss, Omar
Mahmood, Yasir
Bechqito, Yassine
Serhani, Mohamed Adel
Badidi, Elarbi
Riffi, Jamal
Tairi, Hamid
contents Loss functions are at the heart of deep learning, shaping how models learn and perform across diverse tasks. They are used to quantify the difference between predicted outputs and ground truth labels, guiding the optimization process to minimize errors. Selecting the right loss function is critical, as it directly impacts model convergence, generalization, and overall performance across various applications, from computer vision to time series forecasting. This paper presents a comprehensive review of loss functions, covering fundamental metrics like Mean Squared Error and Cross-Entropy to advanced functions such as Adversarial and Diffusion losses. We explore their mathematical foundations, impact on model training, and strategic selection for various applications, including computer vision (Discriminative and generative), tabular data prediction, and time series forecasting. For each of these categories, we discuss the most used loss functions in the recent advancements of deep learning techniques. Also, this review explore the historical evolution, computational efficiency, and ongoing challenges in loss function design, underlining the need for more adaptive and robust solutions. Emphasis is placed on complex scenarios involving multi-modal data, class imbalances, and real-world constraints. Finally, we identify key future directions, advocating for loss functions that enhance interpretability, scalability, and generalization, leading to more effective and resilient deep learning models.
format Preprint
id arxiv_https___arxiv_org_abs_2504_04242
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Task-based Loss Functions in Computer Vision: A Comprehensive Review
Elharrouss, Omar
Mahmood, Yasir
Bechqito, Yassine
Serhani, Mohamed Adel
Badidi, Elarbi
Riffi, Jamal
Tairi, Hamid
Machine Learning
Computer Vision and Pattern Recognition
Loss functions are at the heart of deep learning, shaping how models learn and perform across diverse tasks. They are used to quantify the difference between predicted outputs and ground truth labels, guiding the optimization process to minimize errors. Selecting the right loss function is critical, as it directly impacts model convergence, generalization, and overall performance across various applications, from computer vision to time series forecasting. This paper presents a comprehensive review of loss functions, covering fundamental metrics like Mean Squared Error and Cross-Entropy to advanced functions such as Adversarial and Diffusion losses. We explore their mathematical foundations, impact on model training, and strategic selection for various applications, including computer vision (Discriminative and generative), tabular data prediction, and time series forecasting. For each of these categories, we discuss the most used loss functions in the recent advancements of deep learning techniques. Also, this review explore the historical evolution, computational efficiency, and ongoing challenges in loss function design, underlining the need for more adaptive and robust solutions. Emphasis is placed on complex scenarios involving multi-modal data, class imbalances, and real-world constraints. Finally, we identify key future directions, advocating for loss functions that enhance interpretability, scalability, and generalization, leading to more effective and resilient deep learning models.
title Task-based Loss Functions in Computer Vision: A Comprehensive Review
topic Machine Learning
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2504.04242