Notes on Tuple Representation of Rubiks Cube

Let's first explain what we mean when we talk about a tuple representation of a cube, and why this is useful.

Tuple Representation

A tuple representation means, we are representing one possible permutation of the Rubik's Cube using a tuple, ideally a tuple of N items arranged in some particular way.

Now, if we think about how a 3x3 Rubik's Cube or 4x4 Rubik's Revenge is mechanically constructed, we see that the cube consists of:

Rubik's Cube: 26 total (mechanical) pieces

• 8 corner pieces
• 12 edge pieces
• 6 center pieces

Rubik's Revenge: 56 total (mechanical) pieces

• 8 corner pieces
• 24 double-edge pieces (12 left-hand, 12 right-hand)
• 24 center pieces

However, it is important to note that we are not trying to find the minimal representation of the Rubik's Cube, we are simply trying to find a unique representation of a Rubik's Cube. Representing faces requires more information than representing pieces, but it is a lot simpler and accomplishes what we need:

• The 3x3 Rubik's Cube has 9 squares on each face, and 6 faces, for a total of 36 squares.
• The 4x4 Rubik's Revenge has 16 squares on each face, and 6 faces, for 96 total squares.

Now, if we were looking for a minimal representation, we would utilize the fact that some of these squares are innately linked (for example, the three faces representing a corner piece are always positioned in the same way relative to one another, even though they may move relative to the rest of the pieces on the cube).

However, we simply want a unique representation, so we can represent the state of any 3x3 Rubik's Cube using a 36-tuple, or the state of any 4x4 Rubik's Revenge using a 96-tuple.

Why A Tuple Representation

Finding a tuple representation enables us to study the properties of various move sequences and understand how the cube works.

For example, if we repeatedly apply any sequence of moves to a Rubik's Cube, eventually it will return back to the solved state. To predict how many times a sequence must be applied to a cube to return to the solved state, we can use techniques demonstrated by Donald Knuth in Volume 3 of The Art of Computer Programming (see AOCP) to derive a permutation algebra, factor permutations into cycles, and find the sequence length via the lcm of each cycle length.

See also: https://github.com/charlesreid1/rubiks-cycles

Tuple representation: https://github.com/charlesreid1/rubiks-cycles/blob/master/tup.py

4x4 Rubiks Cube Representation

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Rubiks Cube notes on solving 3x3, 4x4, and 5x5 Rubiks Cubes Category:Rubiks Rubiks/Todo - task list for things to do on the wiki related to the rubiks cube pages Cubes and Solutions: Singmaster Notation 2x2 Cube: Pocket Cube  · Category:2x2 Cube Solving: Pocket Cube/Solution Method  · 3x3 Cube: Category:3x3 Cube Solving: Rubiks Cube/Layer Method  · Rubiks Cube/Fridrich Method 4x4 Cube: Rubiks Revenge  · Category:4x4 Cube Solving: Rubiks Revenge/Layer Method  · 5x5 Cube: Professors Cube  · Category:5x5 Cube Solving: Professors Cube/Layer Method  · Combinatorics Counting the Number of Cube States: Rubiks Cube/Numbers (3x3)  · Rubiks Revenge/Numbers (4x4)  · Professors Cube/Numbers (5x5) Cube Representations with Tuples: Rubiks Cube/Tuple (3x3)  · Rubiks Revenge/Tuple (4x4)  · Professors Cube/Tuple (5x5) Permutation Algebra and Groups: Rubiks Cube/Permutations (3x3)  · Rubiks Revenge/Permutations (4x4)  · Professors Cube/Permutations (5x5) The Most Useful Link: https://www.speedsolving.com/wiki/index.php Related Flags: Template:PocketCubeFlag  · Template:RubiksCubeFlag  · Template:RubiksRevengeFlag  · Template:ProfessorsCubeFlag Flags  · Template:RubiksFlag  · e