正则化扩散冲击涂色

IF 1.3 4区 数学 Q4 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Kristina Schaefer, Joachim Weickert
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引用次数: 0

摘要

我们在 SSVM 2023 会议论文中介绍了正则化扩散冲击(RDS)绘制,它是对扩散冲击绘制的修改。RDS 内画结合了两个精心选择的组件:均匀扩散和相干性增强冲击滤波。它得益于其构建模块的互补协同作用:由于各向异性程度较高,冲击项可以在大范围内以完美的清晰度和方向准确性传播边缘数据。均匀扩散可有效填充大面积区域。RDS Inpainting 所依据的二阶方程继承了其各组成部分的最大-最小原则,与其他各向异性方法相比,离散情况下也符合这一原则。正则化解决了原始模型的最大缺点:它允许在不降低质量的情况下大幅减少模型参数。此外,我们还将 RDS 内绘扩展到了矢量值数据。我们的实验表明,其性能与许多基于偏微分方程和相关积分微分模型(包括二阶或四阶各向异性过程)的绘制方法相当,甚至更好。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Regularised Diffusion–Shock Inpainting

We introduce regularised diffusion–shock (RDS) inpainting as a modification of diffusion–shock inpainting from our SSVM 2023 conference paper. RDS inpainting combines two carefully chosen components: homogeneous diffusion and coherence-enhancing shock filtering. It benefits from the complementary synergy of its building blocks: The shock term propagates edge data with perfect sharpness and directional accuracy over large distances due to its high degree of anisotropy. Homogeneous diffusion fills large areas efficiently. The second order equation underlying RDS inpainting inherits a maximum–minimum principle from its components, which is also fulfilled in the discrete case, in contrast to competing anisotropic methods. The regularisation addresses the largest drawback of the original model: It allows a drastic reduction in model parameters without any loss in quality. Furthermore, we extend RDS inpainting to vector-valued data. Our experiments show a performance that is comparable to or better than many inpainting methods based on partial differential equations and related integrodifferential models, including anisotropic processes of second or fourth order.

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来源期刊
Journal of Mathematical Imaging and Vision
Journal of Mathematical Imaging and Vision 工程技术-计算机:人工智能
CiteScore
4.30
自引率
5.00%
发文量
70
审稿时长
3.3 months
期刊介绍: The Journal of Mathematical Imaging and Vision is a technical journal publishing important new developments in mathematical imaging. The journal publishes research articles, invited papers, and expository articles. Current developments in new image processing hardware, the advent of multisensor data fusion, and rapid advances in vision research have led to an explosive growth in the interdisciplinary field of imaging science. This growth has resulted in the development of highly sophisticated mathematical models and theories. The journal emphasizes the role of mathematics as a rigorous basis for imaging science. This provides a sound alternative to present journals in this area. Contributions are judged on the basis of mathematical content. Articles may be physically speculative but need to be mathematically sound. Emphasis is placed on innovative or established mathematical techniques applied to vision and imaging problems in a novel way, as well as new developments and problems in mathematics arising from these applications. The scope of the journal includes: computational models of vision; imaging algebra and mathematical morphology mathematical methods in reconstruction, compactification, and coding filter theory probabilistic, statistical, geometric, topological, and fractal techniques and models in imaging science inverse optics wave theory. Specific application areas of interest include, but are not limited to: all aspects of image formation and representation medical, biological, industrial, geophysical, astronomical and military imaging image analysis and image understanding parallel and distributed computing computer vision architecture design.
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