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Osmosis: RGBD Diffusion Prior for Underwater Image Restoration


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Leveraging RGBD diffusion priors for superior underwater image restoration.
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The article discusses the challenges of restoring underwater images due to water effects and lack of ground truth data. It introduces a novel approach using RGBD diffusion priors trained on in-air images to enhance underwater image restoration. The method outperforms existing baselines, demonstrating significant improvements in challenging scenes.

Directory:

  1. Introduction
    • Challenges in underwater image restoration due to water effects.
    • Importance of clear underwater vision with increasing human activity.
  2. Methodology Overview
    • Unsupervised restoration method based on diffusion prior for color and depth.
    • Utilization of physical image formation model for guidance.
  3. Training the Prior Model
    • Training joint prior model on color and depth using public RGBD datasets from outdoor scenes collected in air.
  4. Sampling from the Posterior
    • Sampling process guided by reconstruction loss and optimization of water parameters during sampling iterations.
  5. Results Analysis
    • Comparison with existing methods on real-world and simulated data showcasing superior performance in image restoration and depth estimation.

For detailed information, refer to the full article content above.

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Statistieken
"Our method outperforms state-of-the-art baselines for image restoration." "Using this prior together with a novel guidance method based on the underwater image formation model, we generate posterior samples of clean images." "We train an RGBD prior, and demonstrate that modeling color and depth provides a stronger diffusion prior for underwater image restoration."
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"Our method outperforms models that were trained on underwater data." "We propose a new method that combines the RGBD prior of in-air data with the underwater image formation model."

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by Opher Bar Na... om arxiv.org 03-25-2024

https://arxiv.org/pdf/2403.14837.pdf
Osmosis

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How can this approach be adapted for other types of image restoration beyond underwater scenarios

This approach can be adapted for other types of image restoration beyond underwater scenarios by adjusting the training data and the model architecture. For instance, to apply this method to aerial image restoration, one could train the diffusion priors on datasets of aerial images captured in clear weather conditions. By incorporating the specific degradation effects present in aerial imagery, such as haze or atmospheric distortion, into the image formation model and guidance mechanism, the method could effectively restore clarity and details in aerial photos. Similarly, for medical imaging applications like MRI reconstruction or microscopy image enhancement, training on relevant datasets with noise and artifacts characteristic of those domains would enable the diffusion priors to learn appropriate restoration patterns.

What are potential limitations or drawbacks of relying solely on in-air datasets for training the diffusion priors

Relying solely on in-air datasets for training diffusion priors may have limitations when applied to underwater scenarios due to domain gaps between air and water environments. In-air images do not capture the unique optical properties introduced by water that affect color distortion, contrast reduction, and backscatter in underwater scenes. As a result, using only in-air data may lead to suboptimal performance when restoring underwater images since the prior lacks exposure to these specific degradation factors. Additionally, without direct training on underwater data with varying depths and water parameters, there might be challenges in accurately estimating these critical variables during restoration.

How might advancements in neural network architectures improve the efficiency and scalability of this method

Advancements in neural network architectures can significantly improve the efficiency and scalability of this method by optimizing computational resources and enhancing modeling capabilities. For example: Architectural Efficiency: Utilizing lightweight architectures like MobileNet or EfficientNet can reduce computational complexity while maintaining performance levels. Parallel Processing: Implementing parallel processing techniques such as distributed computing or GPU acceleration can speed up training and inference processes. Attention Mechanisms: Integrating attention mechanisms like transformers can enhance feature extraction from complex spatial relationships within images. Self-Supervised Learning: Leveraging self-supervised learning strategies can help improve model generalization by pretraining on large unlabeled datasets before fine-tuning on task-specific data. By incorporating these advancements into the method's design, it is possible to achieve faster convergence rates, better generalization across diverse datasets, and improved overall performance for various image restoration tasks beyond just underwater scenarios.
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