The Four-Colour Theorem

“…As a matter of fact, that theory also states that at most 6 colors are required to color any map on the plane or the sphere [8]. Of course, and as repeatedly mentioned in the paper, the Four Color Theorem [17] demonstrates that the necessary number of colors is 4. Yet, such coloring is NP-complete and using more colors relaxes the situation, allowing for polynomial time complexity colorings.…”

Section: Theory and Parameters In Practicementioning

confidence: 87%

“…This representation corresponds to a planar graph, that is, a graph that can be drawn in the plane without edge crossings. According to the FCT [17] the chromatic number of the graph is 4 -at most 4 different colors are needed such that no adjacent vertices have the same color. For vertex coloring any map on a torus maximum 7 colors are necessary.…”

Section: Graph Coloringmentioning

confidence: 99%

“…These placeholder labels can then be replaced by the full set of actual labels. Since image segments form a planar graph, they therefore require at most four placeholder labels by virtue of the Four Color Theorem (FCT) [17] to still have different colors for all adjacent segments. A joint optimization process provides a fast segmentation through the placeholder labels and a fine-grained labeling through the actual labels.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Efficient Loopy Belief Propagation Using the Four Color Theorem

Timofte

Gool

2013

Advanced Topics in Computer Vision

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Summary. Recent work on early vision such as image segmentation, image denoising, stereo matching, and optical flow uses Markov Random Fields. Although this formulation yields an NP-hard energy minimization problem, good heuristics have been developed based on graph cuts and belief propagation. Nevertheless both approaches still require tens of seconds to solve stereo problems on recent PCs. Such running times are impractical for optical flow and many image segmentation and denoising problems and we review recent techniques for speeding them up. Moreover, we show how to reduce the computational complexity of belief propagation by applying the Four Color Theorem to limit the maximum number of labels in the underlying image segmentation to at most four. We show that this provides substantial speed improvements for large inputs, and this for a variety of vision problems, while maintaining competitive result quality.

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“…Given an instance of Spiral Galaxies, any solution can be interpreted as a two-dimensional map, where each galaxy g (and the fields it contains) is a region, and where two distinct regions are adjacent when they contain adjacent fields. The famous four color theorem (see e.g., [8]) tells us that such a map can be colored with at most four colors. The exact algorithm that follows from the above argument can be described easily as follows: generate every possible four-coloring C U of the fields of U ; for each such C U , check whether (a) each connected set of fields of the same color contains a unique galaxy center, and if so, whether (b) it is a valid galaxy, i.e., it satisfies the symmetry condition and is hole-free.…”

Section: A Nebula Of Exact Algorithmsmentioning

confidence: 99%