TRNR: Task-Driven Image Rain and Noise Removal with a Few Images Based on Patch Analysis
The recent success of learning-based image rain and noise removal can be attributed primarily to well-designed neural network architectures and large labeled datasets. However, we discover that current image rain and noise removal methods result in low utilization of images. To alleviate the relianc...
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Zusammenfassung: | The recent success of learning-based image rain and noise removal can be
attributed primarily to well-designed neural network architectures and large
labeled datasets. However, we discover that current image rain and noise
removal methods result in low utilization of images. To alleviate the reliance
of deep models on large labeled datasets, we propose the task-driven image rain
and noise removal (TRNR) based on a patch analysis strategy. The patch analysis
strategy samples image patches with various spatial and statistical properties
for training and can increase image utilization. Furthermore, the patch
analysis strategy encourages us to introduce the N-frequency-K-shot learning
task for the task-driven approach TRNR. TRNR allows neural networks to learn
from numerous N-frequency-K-shot learning tasks, rather than from a large
amount of data. To verify the effectiveness of TRNR, we build a Multi-Scale
Residual Network (MSResNet) for both image rain removal and Gaussian noise
removal. Specifically, we train MSResNet for image rain removal and noise
removal with a few images (for example, 20.0\% train-set of Rain100H).
Experimental results demonstrate that TRNR enables MSResNet to learn more
effectively when data is scarce. TRNR has also been shown in experiments to
improve the performance of existing methods. Furthermore, MSResNet trained with
a few images using TRNR outperforms most recent deep learning methods trained
data-driven on large labeled datasets. These experimental results have
confirmed the effectiveness and superiority of the proposed TRNR. The source
code is available on \url{https://github.com/Schizophreni/MSResNet-TRNR}. |
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DOI: | 10.48550/arxiv.2112.01924 |