Definition
A tessellation is created when a shape is repeated over and over again covering a plane without any gaps or overlaps.
Another word for a tessellation is a tiling.
A regular polygon has 3 or 4 or 5 or more sides and angles, all equal. A regular tessellation means a tessellation made up of congruent regular polygons.
Only three regular polygons tessellate in the Euclidean plane: triangles, squares or hexagons. We can't show the entire plane, but imagine that these are pieces taken from planes that have been tiled. Here are examples of
| a tessellation of triangles |  |
| a tessellation of squares |  |
| a tessellation of hexagons |  |
You can work out the interior measure of the angles for each of these polygons:
| Shape triangle square pentagon hexagon more than six sides | Angle measure in degrees 60 90 108 120 more than 120 degrees |
Since the regular polygons in a tessellation must fill the plane at each vertex, the interior angle must be an exact divisor of 360 degrees. This works for the triangle, square, and hexagon, and you can show working tessellations for these figures. For all the others, the interior angles are not exact divisors of 360 degrees, and therefore those figures cannot tile the plane.
Naming Conventions
A tessellation of squares is named "4.4.4.4". Here's how: choose a vertex, and then look at one of the polygons that touches that vertex. How many sides does it have?
Since it's a square, it has four sides, and that's where the first "4" comes from. Now keep going around the vertex in either direction, finding the number of sides of the polygons until you get back to the polygon you started with. How many polygons did you count?
There are four polygons, and each has four sides.
For a tessellation of regular congruent hexagons, if you choose a vertex and count the sides of the polygons that touch it, you'll see that there are three polygons and each has six sides, so this tessellation is called "6.6.6":
A tessellation of triangles has six polygons surrounding a vertex, and each of them has three sides: "3.3.3.3.3.3".
Semi-regular Tessellations
You can also use a variety of regular polygons to make semi-regular tessellations. A semiregular tessellation has two properties which are:
Here are the eight semi-regular tessellations:
- It is formed by regular polygons.
- The arrangement of polygons at every vertex point is identical.
Interestingly there are other combinations that seem like they should tile the plane because the arrangements of the regular polygons fill the space around a point. For example:
If you try tiling the plane with these units of tessellation you will find that they cannot be extended infinitely.
There are an infinite number of tessellations that can be made of patterns that do not have the same combination of angles at every vertex point. There are also tessellations made of polygons that do not share common edges and vertices.
