D2C-SR: A Divergence to Convergence Approach for Real-World Image Super-Resolution

TL;DR

D2C-SR introduces a two-stage divergence to convergence framework for real-world image super-resolution, modeling high-frequency details explicitly to improve accuracy and visual quality over existing methods.

Contribution

The paper proposes a novel divergence-convergence pipeline with a tree-based divergence network and spatially weighted fusion, explicitly modeling high-frequency distributions for super-resolution.

Findings

Achieves superior accuracy and visual quality on real-world benchmarks.

Uses fewer parameters than state-of-the-art methods.

The D2C structure can enhance other super-resolution models.

Abstract

In this paper, we present D2C-SR, a novel framework for the task of real-world image super-resolution. As an ill-posed problem, the key challenge in super-resolution related tasks is there can be multiple predictions for a given low-resolution input. Most classical deep learning based approaches ignored the fundamental fact and lack explicit modeling of the underlying high-frequency distribution which leads to blurred results. Recently, some methods of GAN-based or learning super-resolution space can generate simulated textures but do not promise the accuracy of the textures which have low quantitative performance. Rethinking both, we learn the distribution of underlying high-frequency details in a discrete form and propose a two-stage pipeline: divergence stage to convergence stage. At divergence stage, we propose a tree-based structure deep network as our divergence backbone. Divergence loss is proposed to encourage the generated results from the tree-based network to diverge into possible high-frequency representations, which is our way of discretely modeling the underlying high-frequency distribution. At convergence stage, we assign spatial weights to fuse these divergent predictions to obtain the final output with more accurate details. Our approach provides a convenient end-to-end manner to inference. We conduct evaluations on several real-world benchmarks, including a new proposed D2CRealSR dataset with x8 scaling factor. Our experiments demonstrate that D2C-SR achieves better accuracy and visual improvements against state-of-the-art methods, with a significantly less parameters number and our D2C structure can also be applied as a generalized structure to some other methods to obtain improvement. Our codes and dataset are available at https://github.com/megvii-research/D2C-SR