二维蛇形立方体谜题的复杂性

arXiv - CS - Computational Geometry Pub Date : 2024-07-14 DOI:arxiv-2407.10323

MIT Hardness Group, Nithid Anchaleenukoon, Alex Dang, Erik D. Demaine, Kaylee Ji, Pitchayut Saengrungkongka

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引用次数: 0

摘要

给定一个由 $HW$ 立方体组成的链，其中每个立方体都标有 "转 90^\circ$ "或 "直走"，那么它什么时候能折叠成一个 $1 \times H \times W$ 的矩形盒子？我们证明了这个（仍然）未决问题的几种 NP 难变体：(1) 允许一些立方体是通配符（可以转弯或直行）；(2) 允许一个更大的空方框（简化了 CCCG 2022 的证明）；(3) 将方框（和立方体数量）增加到 2 （乘以 H （乘以 W $）（将之前的三维结果从高度 $8 改进为 $2）；(4) 使用六角棱柱而不是立方体，每个棱柱指定为直行、转弯 60^\circ$ 或转弯 120^\circ$；(5) 允许对立方体进行隐式编码，以压缩指数级的大量重复。

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Complexity of 2D Snake Cube Puzzles

Given a chain of $HW$ cubes where each cube is marked "turn $90^\circ$" or "go straight", when can it fold into a $1 \times H \times W$ rectangular box? We prove several variants of this (still) open problem NP-hard: (1) allowing some cubes to be wildcard (can turn or go straight); (2) allowing a larger box with empty spaces (simplifying a proof from CCCG 2022); (3) growing the box (and the number of cubes) to $2 \times H \times W$ (improving a prior 3D result from height $8$ to $2$); (4) with hexagonal prisms rather than cubes, each specified as going straight, turning $60^\circ$, or turning $120^\circ$; and (5) allowing the cubes to be encoded implicitly to compress exponentially large repetitions.

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arXiv - CS - Computational Geometry

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