Algorithmic methods of finite discrete structures. The Four Color Theorem. Theory, methods, algorithms

Sergey Kurapov, Maxim Davidovsky
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Abstract

The Four color problem is closely related to other branches of mathematics and practical applications. More than 20 of its reformulations are known, which connect this problem with problems of algebra, statistical mechanics and planning. And this is also typical for mathematics: the solution to a problem studied out of pure curiosity turns out to be useful in representing real objects and processes that are completely different in nature. Despite the published machine methods for combinatorial proof of the Four color conjecture, there is still no clear description of the mechanism for coloring a planar graph with four colors, its natural essence and its connection with the phenomenon of graph planarity. It is necessary not only to prove (preferably by deductive methods) that any planar graph can be colored with four colors, but also to show how to color it. The paper considers an approach based on the possibility of reducing a maximally flat graph to a regular flat cubic graph with its further coloring. Based on the Tate-Volynsky theorem, the vertices of a maximally flat graph can be colored with four colors, if the edges of its dual cubic graph can be colored with three colors. Considering the properties of a colored cubic graph, it can be shown that the addition of colors obeys the transformation laws of the fourth order Klein group. Using this property, it is possible to create algorithms for coloring planar graphs.
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有限离散结构的算法。四色定理。理论、方法、算法
四色问题与其他数学分支和实际应用密切相关。目前已知的四色问题重述有 20 多种,这些重述将四色问题与代数、统计力学和规划问题联系在一起。这也是数学的典型特征:纯粹出于好奇心而研究的问题的解决方案,在表示性质完全不同的真实物体和过程时,会变得非常有用。尽管四色猜想的组合证明机器方法已经出版,但对于用四种颜色为平面图着色的机制、其自然本质及其与图平面性现象的联系,仍然没有清晰的描述。我们不仅需要证明(最好通过演绎法)任何平面图都可以用四种颜色着色,而且还需要说明如何着色。本文考虑的方法基于将最大平面图还原为规则平面立方图并进一步着色的可能性。根据塔特-沃林斯基定理,如果最大平面图的双立方图的边可以用三种颜色着色,那么最大平面图的顶点就可以用四种颜色着色。考虑到彩色立方图的性质,可以证明颜色的添加服从四阶克莱因群的变换定律。利用这一特性,可以创建平面图形着色算法。
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