Learning Detail-Structure Alternative Optimization for Blind
Super-Resolution
- URL: http://arxiv.org/abs/2212.01624v1
- Date: Sat, 3 Dec 2022 14:44:17 GMT
- Title: Learning Detail-Structure Alternative Optimization for Blind
Super-Resolution
- Authors: Feng Li, Yixuan Wu, Huihui Bai, Weisi Lin, Runmin Cong, and Yao Zhao
- Abstract summary: We propose an effective and kernel-free network, namely DSSR, which enables recurrent detail-structure alternative optimization without blur kernel prior incorporation for blind SR.
In our DSSR, a detail-structure modulation module (DSMM) is built to exploit the interaction and collaboration of image details and structures.
Our method achieves the state-of-the-art against existing methods.
- Score: 69.11604249813304
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Existing convolutional neural networks (CNN) based image super-resolution
(SR) methods have achieved impressive performance on bicubic kernel, which is
not valid to handle unknown degradations in real-world applications. Recent
blind SR methods suggest to reconstruct SR images relying on blur kernel
estimation. However, their results still remain visible artifacts and detail
distortion due to the estimation errors. To alleviate these problems, in this
paper, we propose an effective and kernel-free network, namely DSSR, which
enables recurrent detail-structure alternative optimization without blur kernel
prior incorporation for blind SR. Specifically, in our DSSR, a detail-structure
modulation module (DSMM) is built to exploit the interaction and collaboration
of image details and structures. The DSMM consists of two components: a detail
restoration unit (DRU) and a structure modulation unit (SMU). The former aims
at regressing the intermediate HR detail reconstruction from LR structural
contexts, and the latter performs structural contexts modulation conditioned on
the learned detail maps at both HR and LR spaces. Besides, we use the output of
DSMM as the hidden state and design our DSSR architecture from a recurrent
convolutional neural network (RCNN) view. In this way, the network can
alternatively optimize the image details and structural contexts, achieving
co-optimization across time. Moreover, equipped with the recurrent connection,
our DSSR allows low- and high-level feature representations complementary by
observing previous HR details and contexts at every unrolling time. Extensive
experiments on synthetic datasets and real-world images demonstrate that our
method achieves the state-of-the-art against existing methods. The source code
can be found at https://github.com/Arcananana/DSSR.
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