← Back to Research Radar
Scientific Literature Scientific Literature

Boosting underwater image quality: a deep learning approach to denoising and enhancement

Najaf Ali, Muhammad Habib, Fahad Ahmad, Saif Ur Rehman, Yuelin Guo, Ahmad Alshammari
April 14, 2026
Published Date

Research Abstract & Technology Focus

Underwater image restoration is significant for various applications such as ecological evaluation, exploration, searching and rescue operations, and autonomous vehicle navigation. In underwater environments, spatial images are frequently degraded as a result of light scattering, absorption, sensor noise, and reduced contrast. This research proposes a whole framework with deep learning that simultaneously performs restoration and enhancement. At a single stage, solving the problems of underwater image degradation in a holistic approach. The core of the proposed approach in this study is a Denoising Convolutional Neural Network (DnCNN) architecture. Where the suppression of noise takes place with extreme focus on significant detail by an advanced non-local attention mechanism. For the further natural color restoration, multi-color space transformations RGB, LAB, and HSV. Which come into play for enhancing the contrast adjustment and color correction of contrast and a correction of colors enabling effective correction of deep-sea views. The framework takes advantage of both synthetically modified images and actual underwater images for model training which offers enhanced generalization for various settings. For the evaluation of the developed approach, two datasets of underwater images, EUVP and LSUI, were used. For the evaluation of the developed approach, two datasets of underwater images, EUVP and LSUI, were used. For the EUVP dataset, this model produces a PSNR of 30.77 dB, an SSIM of 0.892, RMSE of 0.065, and NIQE of 3.52. It produces a PSNR of 29.90 dB, SSIM of 0.881, RMSE of 0.071, and NIQE of 3.82 for the LSUI dataset. As mentioned earlier these results outperform the baseline DnCNN model and show consistent performance with varying underwater conditions. Accompanying the performance results, the model achieves high fidelity results while being lightweight, real-time processing.
Read Full Literature

Correlated Market Trend: Artificial Intelligence

Bridging academia to market: The 60-day public search velocity mapping directly to the core technology of this paper. Dashed line represents 7-day moving average.

AI Semantic Synergy Context

Connecting this academic literature to real-world market discussions and products.

openalex.org › research concept
0%

Improving rare-class detection in deep-sea imagery via generative augmentation with stable diffusion

Megabenthos play a critical role in maintaining deep-sea ecosystem stability, making accurate detection important for deep-sea conservation. However, the high cost of deep-sea exploration and the l...

openalex.org › research concept
0%

Physical prior-guided SAM adaptation for underwater scene segmentation

Underwater image segmentation is fundamental to marine exploration and autonomous underwater vehicle navigation, yet its accuracy is severely compromised by wavelength-selective absorption and scat...

openalex.org › research concept
0%

Underwater 3D sound speed field reconstruction based on block term tensor decomposition

The three-dimensional sound speed field (SSF) is of great significance in underwater acoustic research; however, the high cost of maritime observation often leads to sparse and limited measurement ...

openalex.org › research concept
0%

Exploiting Phase Memory in Multicarrier Waveforms for Robust Underwater Acoustic Communication

Reliable underwater acoustic (UWA) communication is fundamental to marine sensing applications, including environmental monitoring, underwater sensor networks, and autonomous platforms, yet remains...

crossref.org › academic paper
0%

DICAM: Deep Inception and Channel-wise Attention Modules for underwater image enhancement

No description provided.

Frequently Asked Questions (FAQ)

Curated market intelligence mapped to this research.

What is the core focus of the research titled 'Boosting underwater image quality: a deep learning approach to denoising and enhancement'?

This literature focuses on: Underwater image restoration is significant for various applications such as ecological evaluation, exploration, searching and rescue operations, and autonomous vehicle navigation. In underwater environments, spatial images are frequently degraded...

What other academic literature is closely related to 'Boosting underwater image quality: a deep learning approach to denoising and enhancement'?

Yes, highly correlated activity was mapped. An entry titled 'Improving rare-class detection in deep-sea imagery via generative augmentation with stable diffusion' discusses this: Megabenthos play a critical role in maintaining deep-sea ecosystem stability, making accurate detection important for deep-sea conservation. Howeve...

Cite this Market Intelligence Report

Reference our AI-mapped synergy between this research and the commercial market to instantly build authority.