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Paper detail

Algorithms for Solving Rubik's Cubes

The Rubik's Cube is perhaps the world's most famous and iconic puzzle, well-known to have a rich underlying mathematical structure (group theory). In this paper, we show that the Rubik's Cube also has a rich underlying algorithmic structure. Specifically, we show that the n x n x n Rubik's Cube, as well as the n x n x 1 variant, has a "God's Number" (diameter of the configuration space) of Theta(n^2/log n). The upper bound comes from effectively parallelizing standard Theta(n^2) solution algorithms, while the lower bound follows from a counting argument. The upper bound gives an asymptotically optimal algorithm for solving a general Rubik's Cube in the worst case. Given a specific starting state, we show how to find the shortest solution in an n x O(1) x O(1) Rubik's Cube. Finally, we show that finding this optimal solution becomes NP-hard in an n x n x 1 Rubik's Cube when the positions and colors of some of the cubies are ignored (not used in determining whether the cube is solved).

preprint2011arXivOpen access
Erik D. DemaineMartin L. DemaineSarah EisenstatAnna LubiwAndrew Winslow
math.COData Structures and AlgorithmsComputational ComplexityComputational Geometry
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Erik D. DemaineMartin L. DemaineSarah EisenstatAnna LubiwAndrew Winslow

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