Segment from the center of a polygon to the midpoint of one of its sides

The apothem (sometimes abbreviated as apo^{[1]}) of a regular polygon is a line segment from the center to the midpoint of one of its sides. Equivalently, it is the line drawn from the center of the polygon that is perpendicular to one of its sides. The word "apothem" can also refer to the length of that line segment and come from the ancient Greekἀπόθεμα ("put away, put aside"), made of ἀπό ("off, away") and θέμα ("that which is laid down"), indicating a generic line written down.^{[2]} Regular polygons are the only polygons that have apothems. Because of this, all the apothems in a polygon will be congruent.

For an equilateral triangle, the apothem is equivalent to the line segment from the midpoint of a side to the triangle's center.^{[note 1]}

Properties of apothems

The apothem a can be used to find the area of any regular n-sided polygon of side length s according to the following formula, which also states that the area is equal to the apothem multiplied by half the perimeter since ns = p.

$A={\frac {nsa}{2))={\frac {pa}{2)).$

This formula can be derived by partitioning the n-sided polygon into ncongruentisosceles triangles, and then noting that the apothem is the height of each triangle, and that the area of a triangle equals half the base times the height. The following formulations are all equivalent:

An apothem of a regular polygon will always be a radius of the inscribed circle. It is also the minimum distance between any side of the polygon and its center.

This property can also be used to easily derive the formula for the area of a circle, because as the number of sides approaches infinity, the regular polygon's area approaches the area of the inscribed circle of radius r = a.

These formulae can still be used even if only the perimeter p and the number of sides n are known because s = p/n.

Notes

^Equilateral triangles have only one triangle center, which is what makes this definition of the apothem of an equilateral triangle well-defined. For non-equilateral triangles however, there are many non-coinciding notions of triangle center; see Triangle center for details.