Enregistré dans:
Détails bibliographiques
Auteurs principaux: Samadi, Mohammadreza, Han, Fred X., Salameh, Mohammad, Wu, Hao, Sun, Fengyu, Zhou, Chunhua, Niu, Di
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2408.08495
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866909431117119488
author Samadi, Mohammadreza
Han, Fred X.
Salameh, Mohammad
Wu, Hao
Sun, Fengyu
Zhou, Chunhua
Niu, Di
author_facet Samadi, Mohammadreza
Han, Fred X.
Salameh, Mohammad
Wu, Hao
Sun, Fengyu
Zhou, Chunhua
Niu, Di
contents Diffusion models have demonstrated outstanding performance in generative tasks, making them ideal candidates for image editing. Recent studies highlight their ability to apply desired edits effectively by following textual instructions, yet with two key challenges remaining. First, these models struggle to apply multiple edits simultaneously, resulting in computational inefficiencies due to their reliance on sequential processing. Second, relying on textual prompts to determine the editing region can lead to unintended alterations to the image. We introduce FunEditor, an efficient diffusion model designed to learn atomic editing functions and perform complex edits by aggregating simpler functions. This approach enables complex editing tasks, such as object movement, by aggregating multiple functions and applying them simultaneously to specific areas. Our experiments demonstrate that FunEditor significantly outperforms recent inference-time optimization methods and fine-tuned models, either quantitatively across various metrics or through visual comparisons or both, on complex tasks like object movement and object pasting. In the meantime, with only 4 steps of inference, FunEditor achieves 5-24x inference speedups over existing popular methods. The code is available at: mhmdsmdi.github.io/funeditor/.
format Preprint
id arxiv_https___arxiv_org_abs_2408_08495
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle FunEditor: Achieving Complex Image Edits via Function Aggregation with Diffusion Models
Samadi, Mohammadreza
Han, Fred X.
Salameh, Mohammad
Wu, Hao
Sun, Fengyu
Zhou, Chunhua
Niu, Di
Computer Vision and Pattern Recognition
Diffusion models have demonstrated outstanding performance in generative tasks, making them ideal candidates for image editing. Recent studies highlight their ability to apply desired edits effectively by following textual instructions, yet with two key challenges remaining. First, these models struggle to apply multiple edits simultaneously, resulting in computational inefficiencies due to their reliance on sequential processing. Second, relying on textual prompts to determine the editing region can lead to unintended alterations to the image. We introduce FunEditor, an efficient diffusion model designed to learn atomic editing functions and perform complex edits by aggregating simpler functions. This approach enables complex editing tasks, such as object movement, by aggregating multiple functions and applying them simultaneously to specific areas. Our experiments demonstrate that FunEditor significantly outperforms recent inference-time optimization methods and fine-tuned models, either quantitatively across various metrics or through visual comparisons or both, on complex tasks like object movement and object pasting. In the meantime, with only 4 steps of inference, FunEditor achieves 5-24x inference speedups over existing popular methods. The code is available at: mhmdsmdi.github.io/funeditor/.
title FunEditor: Achieving Complex Image Edits via Function Aggregation with Diffusion Models
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2408.08495