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A tetromino is a geometric shape composed of four squares, connected
orthogonally In mathematics, orthogonality is the generalization of the geometric notion of ''perpendicularity''. By extension, orthogonality is also used to refer to the separation of specific features of a system. The term also has specialized meanings in ...
(i.e. at the edges and not the corners). Tetrominoes, like dominoes and pentominoes, are a particular type of polyomino. The corresponding polycube, called a tetracube, is a geometric shape composed of four
cube In geometry, a cube is a three-dimensional solid object bounded by six square faces, facets or sides, with three meeting at each vertex. Viewed from a corner it is a hexagon and its net is usually depicted as a cross. The cube is the only r ...
s connected orthogonally. A popular use of tetrominoes is in the video game '' Tetris'' created by the Soviet game designer Alexey Pajitnov, which refers to them as tetriminos. The tetrominoes used in the game are specifically the one-sided tetrominoes.


The tetrominoes


Free tetrominoes

Polyominos are formed by joining unit squares along their edges. A free polyomino is a polyomino considered up to
congruence Congruence may refer to: Mathematics * Congruence (geometry), being the same size and shape * Congruence or congruence relation, in abstract algebra, an equivalence relation on an algebraic structure that is compatible with the structure * In mod ...
. That is, two free polyominos are the same if there is a combination of translations,
rotation Rotation, or spin, is the circular movement of an object around a '' central axis''. A two-dimensional rotating object has only one possible central axis and can rotate in either a clockwise or counterclockwise direction. A three-dimensional ...
s, and reflections that turns one into the other. A free tetromino is a free polyomino made from four squares. There are five free tetrominoes. The free tetrominoes have the following symmetry: * Straight: vertical and horizontal reflection symmetry, and two points of rotational symmetry * Square: vertical and horizontal reflection symmetry, and four points of rotational symmetry * T: vertical reflection symmetry only * L: no symmetry * S and Z: two points of rotational symmetry only


One-sided tetrominoes

One-sided tetrominoes are tetrominoes that may be translated and rotated but not reflected. They are used by, and are overwhelmingly associated with, '' Tetris''. There are seven distinct one-sided tetrominoes. These tetrominoes are named by the letter of the alphabet they most closely resemble. The "I", "O", and "T" tetrominoes have reflectional symmetry, so it does not matter whether they are considered as free tetrominoes or one-sided tetrominoes. The remaining four tetrominoes, "J", "L", "S", and "Z", exhibit a phenomenon called
chirality Chirality is a property of asymmetry important in several branches of science. The word ''chirality'' is derived from the Greek (''kheir''), "hand", a familiar chiral object. An object or a system is ''chiral'' if it is distinguishable from ...
. J and L are reflections of each other, and S and Z are reflections of each other. As free tetrominoes, J is equivalent to L, and S is equivalent to Z. But in two dimensions and without reflections, it is not possible to transform J into L or S into Z.


Fixed tetrominoes

The fixed tetrominoes allow only translation, not rotation or reflection. There are two distinct fixed I-tetrominoes, four J, four L, one O, two S, four T, and two Z, for a total of 19 fixed tetrominoes:


Tiling a rectangle


Filling a rectangle with one set of tetrominoes

A single set of free tetrominoes or one-sided tetrominoes cannot fit in a rectangle. This can be shown with a proof similar to the mutilated chessboard argument. A 5×4 rectangle with a checkerboard pattern has 20 squares, containing 10 light squares and 10 dark squares, but a complete set of free tetrominoes has either 11 dark squares and 9 light squares, or 11 light squares and 9 dark squares. This is due to the T tetromino having either 3 dark squares and one light square, or 3 light squares and one dark square, while all other tetrominoes each have 2 dark squares and 2 light squares. Similarly, a 7×4 rectangle has 28 squares, containing 14 squares of each shade, but the set of one-sided tetrominoes has either 15 dark squares and 13 light squares, or 15 light squares and 13 dark squares. By extension, any odd number of sets for either type cannot fit in a rectangle. Additionally, the 19 fixed tetrominoes cannot fit in a 4×19 rectangle. This was discovered by exhausting all possibilities in a computer search.


Filling a modified rectangle with one set of tetrominoes

However, all three sets of tetrominoes can fit rectangles with holes:


Filling a rectangle with two sets of tetrominoes

Two sets of free or one-sided tetrominoes can fit into a rectangle in different ways, as shown below:


Etymology

The name "tetromino" is a combination of the
prefix A prefix is an affix which is placed before the Word stem, stem of a word. Adding it to the beginning of one word changes it into another word. For example, when the prefix ''un-'' is added to the word ''happy'', it creates the word ''unhappy'' ...
''tetra-'' 'four' (from Ancient Greek ), and " domino". The name was introduced by
Solomon W. Golomb Solomon Wolf Golomb (; May 30, 1932 – May 1, 2016) was an American mathematician, engineer, and professor of electrical engineering at the University of Southern California, best known for his works on mathematical games. Most notably, he inve ...
in 1953 along with other nomenclature related to polyominos.


Filling a box with tetracubes

Each of the five free tetrominoes has a corresponding tetracube, which is the tetromino extruded by one unit. J and L are the same tetracube, as are S and Z, because one may be rotated around an axis parallel to the tetromino's plane to form the other. Three more tetracubes are possible, all created by placing a unit cube on the bent tricube: The tetracubes can be packed into two-layer 3D boxes in several different ways, based on the dimensions of the box and criteria for inclusion. They are shown in both a pictorial diagram and a text diagram. For boxes using two sets of the same pieces, the pictorial diagram depicts each set as a lighter or darker shade of the same color. The text diagram depicts each set as having a capital or lower-case letter. In the text diagram, the top layer is on the left, and the bottom layer is on the right.
1.) 2×4×5 box filled with two sets of free tetrominoes: 

Z Z T t I        l T T T i
L Z Z t I        l l l t i
L z z t I        o o z z i
L L O O I        o o O O i





2.) 2×2×10 box filled with two sets of free tetrominoes:

L L L z z Z Z T O O        o o z z Z Z T T T l
L I I I I t t t O O        o o i i i i t l l l





3.) 2×4×4 box filled with one set of all tetrominoes:

F T T T        F Z Z B
F F T B        Z Z B B
O O L D        L L L D
O O D D        I I I I





4.) 2×2×8 box filled with one set of all tetrominoes: 

D Z Z L O T T T        D L L L O B F F
D D Z Z O B T F        I I I I O B B F





5.) 2×2×7 box filled with tetrominoes, with mirror-image pieces removed:

L L L Z Z B B        L C O O Z Z B
C I I I I T B        C C O O T T T


See also

* Soma cube


Previous and next orders

* Tromino * Pentomino


References


External links

* Vadim Gerasimov, "Tetris: the story."
The story of TetrisThe Father of TetrisWeb Archive copy of the page here
{{Polyforms Polyforms Tetris Mathematical games