Incircle and excircles of a triangle
 |
\nA triangle (black) with incircle (purple),
\nexcircles (blue), internal angle bisectors (red)
\nand external angle bisectors (green) |
\n
\nIn
geometry, the
incircle or
inscribed circle of a
triangle is the largest
circle contained in the triangle; it touches (is
tangent to) the three sides. The center of the incircle is called the triangle's
incenter. An
excircle or
escribed circle of the triangle is a circle lying outside the triangle, tangent to one of its sides and tangent to the extensions of the other two. \nEvery triangle has three distinct excircles, each tangent to one of the triangle's sides.
The center of the incircle can be found as the intersection of the three internal
angle bisectors. \nThe center of an excircle is the intersection of the internal bisector of one angle and the external bisectors of the other two. From this, it follows that the center of the incircle together with the three excircle centers form an
orthocentric system.
The radii of the in- and excircles are closely related to the
area of the triangle. If
S is the triangle's area and its sides are
a,
b and
c, then the radius of the incircle (also known as the
inradius) is
S/(2(
a+
b+
c)), the excircle at side
a has radius
S/(2(-
a+
b+
c)), the excircle at side
b has radius
S/(2(
a-
b+
c)) and the excircle at side
c has radius
S/(2(
a+
b-
c)). From these formulas we see in particular that the excircles are always larger than the incircle, and that the largest excircle is the one attached to the longest side.
 |
\nA triangle with incircle (black),
\ncontact triangle (red) and Gergonne point (green) |
\n
\nThe triangle's
nine point circle is tangent to the three excircles as well as to the incircle. The triangle's
Feuerbach point lies on the incircle.
Denoting the three vertices of the triangle by
A,
B and
C and the three points where the incircle touches the triangle by
TA,
TB and
TC (where
TA is opposite of
A, etc.), the triangle
TATBTC is known as the
contact triangle of
ABC. The incircle of
ABC is the
circumcircle of
TATBTC. The three lines
ATA,
BTB and
CTC intersect in a single point, the triangle's
Gergonne point G.
The Gergonne point of a triangle is equal to the
symmedian point of its contact triangle.
See also
\n*circumcircle
Category:Triangles
