# Pyraminx Duo

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Twisty puzzle

The Pyraminx Duo in its solved state.

The **Pyraminx Duo** (originally known as *Rob's Pyraminx*)[1] is a [tetrahedral](/source/Tetrahedron) [twisty puzzle](/source/Combination_puzzle) in the style of the [Rubik's Cube](/source/Rubik's_Cube). It was suggested by [Rob Stegmann](https://en.wikipedia.org/w/index.php?title=Rob_Stegmann&action=edit&redlink=1),[1] invented by [Oskar van Deventer](/source/Oskar_van_Deventer),[1][2] and has now been mass-produced by [Meffert's](/source/Uwe_M%C3%A8ffert).[1][3]

## Overview

The Pyraminx Duo in the middle of a twist, showing how the puzzle can be scrambled.

The Pyraminx Duo is a puzzle in the shape of a tetrahedron, divided into 4 corner pieces and 4 face centre pieces. Each corner piece has three colours, while the centre pieces each have a single colour. Each face of the puzzle contains one face centre piece and three corner pieces.

The puzzle can be thought of as twisting around its corner pieces - each twist rotates one corner piece and permutates the three face centre pieces around it. An interesting feature is that the face centre pieces go "underneath" corner pieces during a twist.

The purpose of the puzzle is to scramble the colours, and then restore them to their original configuration of one colour per face.

Mechanically, the puzzle is similar to the [Skewb](/source/Skewb), with all corner pieces of the Skewb visible (although shaped differently) and all centre pieces hidden.

## Number of combinations

There are 4 corner pieces. Each corner can be twisted in 3 different orientations, independently of the other corners. Therefore, the corners can be orientated in 34 different ways. They cannot be permutated, therefore there is only one possible corner permutation.

There are 4 face centre pieces. These can be permutated in at most 4[!](/source/Factorial) different ways. However, the exact number of these permutations is not yet reached due to two constraints. The first constraint is that only even permutations of the face centers are possible (e.g. it is impossible to have only two face centre pieces swapped); this divides the limit by 2. The second constraint is that all centre permutations are dependent on the orientation of the corner pieces. Some permutations of centres are only possible when the total number of *clockwise* rotations of corner pieces is divisible by 3; other permutations are only possible when the total number of *clockwise* rotations is equivalent to 1 modulo 3; others are only possible when the number is equivalent to 2 modulo 3. This divides the limit by 3.

The face centre pieces have no obvious orientation, therefore this does not affect the total number of combinations.

The full number is therefore:[4]

- 3 4 × 4 ! 2 × 3 = 324 {\displaystyle {\frac {3^{4}\times 4!}{2\times 3}}=324}

This number, in relative terms, is extremely low compared to other puzzles like the [Rubik's Cube](/source/Rubik's_Cube) (which has over 43 quintillion combinations), the [Pocket Cube](/source/Pocket_Cube) (with over 3.6 million combinations), or even the [Pyraminx](/source/Pyraminx) (with just over 930 thousand combinations, excluding rotations of the [trivial tips](/source/Pyraminx#Description)).

## Optimal solutions

The Pyraminx Duo, scrambled.

As explained above, the total number of possible configurations of the Pyraminx Duo is 324, which is sufficiently small to allow a computer search for optimal solutions. The table below summarises the result of such a search, stating the number *p* of positions that require *n* twists to solve the Pyraminx Duo:[4]

n 0 1 2 3 4 Total p 1 8 48 188 79 324

The above table shows that the [God's Number](/source/God's_algorithm) of the Pyraminx Duo is 4 (i.e. the puzzle is always at most 4 twists away from its solved state). Similarly to the total number of combinations, this number is very low compared to the Rubik's Cube (20), the Pocket Cube (11) or the Pyraminx (11, excluding the trivial tips).

## Solving

Due to its substantially low number of combinations and its low God's Number, the Pyraminx Duo is a relatively easy puzzle to solve; it has been described as "arguably the easiest non-trivial twisty puzzle".[2] Because of this, cubers usually come up with their own methods of solving the puzzle. For an extra challenge, it is also not uncommon for cubers to invent their own "optimal" methods - i.e. methods that guarantee to solve the puzzle in no more than 4 moves.

## Variations

There are several variations of the Pyraminx Duo that have been invented. These variations all look the same as the original puzzle but use different colour schemes; usually these colour schemes make the orientations of the face centre pieces visible, which makes the puzzle slightly more challenging.[4]

## See also

- [Pyraminx](/source/Pyraminx)

- [Skewb](/source/Skewb)

## References

1. ^ [***a***](#cite_ref-TwistyPuzzles_1-0) [***b***](#cite_ref-TwistyPuzzles_1-1) [***c***](#cite_ref-TwistyPuzzles_1-2) [***d***](#cite_ref-TwistyPuzzles_1-3) [Twisty Puzzles - Museum - Rob's Pyraminx](http://www.twistypuzzles.com/cgi-bin/puzzle.cgi?pkey=4714)

1. ^ [***a***](#cite_ref-video_2-0) [***b***](#cite_ref-video_2-1) [Rob's Pyraminx - YouTube](https://www.youtube.com/watch?v=3bu0QzmmvCY)

1. **[^](#cite_ref-3)** [Pyraminx Duo Black](http://www.mefferts.com/products../details.php?lang=en&category=13&id=1035) - Meffert's

1. ^ [***a***](#cite_ref-jaap_4-0) [***b***](#cite_ref-jaap_4-1) [***c***](#cite_ref-jaap_4-2) [Pyraminx Duo](http://www.jaapsch.net/puzzles/pyraduo.htm) - Jaap's Puzzle Page

v t e Rubik's Cube Puzzle inventors Ernő Rubik Larry Nichols Uwe Mèffert Tony Fisher Panagiotis Verdes Katsuhiko Okamoto Oskar van Deventer Rubik's Cubes Overview Rubik's family cubes of varying sizes 2×2×2 (Pocket Cube) 3×3×3 (Rubik's Cube) 4×4×4 (Rubik's Revenge) 5×5×5 (Professor's Cube) 6×6×6 (V-Cube 6) 7×7×7 (V-Cube 7) 8×8×8 (V-Cube 8) Variations of the Rubik's Cube Bump Cube Nine-Colour Cube Sudoku Cube Rubik's WOWCube Other cubic combination puzzles Helicopter Cube Skewb Dino Cube Square-1 Gear Cube Non-cubic combination puzzles Tetrahedron Pyraminx Pyraminx Duo Pyramorphix BrainTwist Octahedron Face Turning Octahedron Skewb Diamond Dodecahedron Megaminx Pyraminx Crystal Skewb Ultimate Icosahedron Impossiball Dogic Great dodecahedron Alexander's Star Truncated icosahedron Tuttminx Cuboid Rubik's Domino (2x3x3) Virtual combination puzzles (>3D) MagicCube4D MagicCube5D MagicCube7D Magic 120-cell Derivatives Missing Link Rubik's 360 Rubik's Clock Rubik's Magic Master Edition Rubik's Revolution Rubik's Snake Rubik's Triamid Renowned solvers Yu Nakajima Édouard Chambon Bob Burton, Jr. Jessica Fridrich Chris Hardwick Kevin Hays Rowe Hessler Leyan Lo Shotaro Makisumi Toby Mao Prithveesh K. Bhat Krishnam Raju Gadiraju Tyson Mao Frank Morris Lars Petrus Gilles Roux David Singmaster Ron van Bruchem Eric Limeback Anthony Michael Brooks Mats Valk Feliks Zemdegs Collin Burns Max Park Tymon Kolasiński Mátyás Kuti Yiheng Wang Solutions Speedsolving Speedcubing World Championship 1982 2003 2005 Methods Layer by Layer CFOP method Optimal Mathematics God's algorithm Superflip Thistlethwaite's algorithm Rubik's Cube group Official organization World Cube Association Related articles Rubik's Cube in popular culture Rubik, the Amazing Cube The Simple Solution to Rubik's Cube

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Adapted from the Wikipedia article [Pyraminx Duo](https://en.wikipedia.org/wiki/Pyraminx_Duo) by Wikipedia contributors ([contributor history](https://en.wikipedia.org/wiki/Pyraminx_Duo?action=history)). Available under [Creative Commons Attribution-ShareAlike 4.0 International](https://creativecommons.org/licenses/by-sa/4.0/). Changes may have been made.