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|Edges and vertices||3|
|Internal angle (degrees)||60°|
|Edges and vertices||3|
|Internal angle (degrees)||60°|
In geometry, an equilateral triangle is a triangle in which all three sides are equal. In traditional or Euclidean geometry, equilateral triangles are also equiangular; that is, all three internal angles are also congruent to each other and are each 60°. They are regular polygons, and can therefore also be referred to as regular triangles.
Denoting the common length of the sides of the equilateral triangle as a, we can determine using the Pythagorean theorem that:
Many of these quantities have simple relationships to the altitude ("h") of each vertex from the opposite side:
In an equilateral triangle, the altitudes, the angle bisectors, the perpendicular bisectors and the medians to each side coincide.
A triangle ABC that has the sides a, b, c, semiperimeter s, area T, exradii ra, rb, rc (tangent to a, b, c respectively), and where R and r are the radii of the circumcircle and incircle respectively, is equilateral if and only if any one of the statements in the following nine categories is true. Thus these are properties that are unique to equilateral triangles.
Every triangle center of an equilateral triangle coincides with its centroid, and for some pairs of triangle centers, the fact that they coincide is enough to ensure that the triangle is equilateral. In particular:
For any triangle, the three medians partition the triangle into six smaller triangles.
Napoleon's theorem states that, if equilateral triangles are constructed on the sides of any triangle, either all outward, or all inward, the centers of those equilateral triangles themselves form an equilateral triangle.
Viviani's theorem states that, for any interior point P in an equilateral triangle, with distances d, e, and f from the sides, d + e + f = the altitude of the triangle, independent of the location of P.
Pompeiu's theorem states that, if P is an arbitrary point in an equilateral triangle ABC, then there exists a triangle with sides of length PA, PB, and PC.
By Euler's inequality, the equilateral triangle has the smallest ratio R/r of the circumradius to the inradius of any triangle: specifically, R/r = 2.
The triangle of largest area of all those inscribed in a given circle is equilateral; and the triangle of smallest area of all those circumscribed around a given circle is equilateral.
The ratio of the area of the incircle to the area of an equilateral triangle, , is larger than that of any non-equilateral triangle.
The ratio of the area to the square of the perimeter of an equilateral triangle, is larger than that for any other triangle.
If a segment splits an equilateral triangle into two regions with equal perimeters and with areas A1 and A2 , then :p.151,#J26
Given a point P in the interior of an equilateral triangle, the ratio of the sum of its distances from the vertices to the sum of its distances from the sides equals 2 and is less than that of any other triangle. This is the Erdős–Mordell inequality; a stronger variant of it is Barrow's inequality, which replaces the perpendicular distances to the sides with the distances from P to the points where the angle bisectors of ∠APB, ∠BPC, and ∠CPA cross the sides (A, B, and C being the vertices).
For any point P in the plane, with distances p, q, and t from the vertices A, B, and C respectively,
For any point P on the inscribed circle of an equilateral triangle, with distances p, q, and t from the vertices,
moreover, if point D on side BC divides PA into segments PD and DA with DA having length z and PD having length y, then:172
which also equals if t ≠ q; and
Equilateral triangles are the only triangles whose Steiner inellipse is a circle (specifically, it is the incircle).
Equilateral triangles are found in many other geometric constructs. The intersection of circles whose centers are a radius width apart is a pair of equilateral arches, each of which can be inscribed with an equilateral triangle. They form faces of regular and uniform polyhedra. Three of the five Platonic solids are composed of equilateral triangles. In particular, the regular tetrahedron has four equilateral triangles for faces and can be considered the three-dimensional analogue of the shape. The plane can be tiled using equilateral triangles giving the triangular tiling.
An equilateral triangle is easily constructed using a compass and straightedge. Draw a straight line, and place the point of the compass on one end of the line, and swing an arc from that point to the other point of the line segment. Repeat with the other side of the line. Finally, connect the point where the two arcs intersect with each end of the line segment
Draw a circle with radius r, place the point of the compass on the circle and draw another circle with the same radius. The two circles will intersect in two points. An equilateral triangle can be constructed by taking the two centers of the circles and either of the points of intersection.
The proof that the resulting figure is an equilateral triangle is the first proposition in Book I of Euclid's Elements.
The area formula in terms of side length a can be derived directly using the Pythagorean theorem or using trionometry.
The area of a triangle is half of one side a times the height h from that side:
The legs of either right triangle formed by an altitude of the equilateral triangle are half of the base a, and the hypotenuse is the side a of the equilateral triangle. The height of an equilateral triangle can be found using the Pythagorean theorem
Substituting h into the area formula (1/2)ah gives the area formula for the equilateral triangle:
Using trigonometry, the area of a triangle with any two sides a and b, and an angle C between them is
Each angle of an equilateral triangle is 60°, so
The sine of 60° is . Thus
since all sides of an equilateral triangle are equal.
Equilateral triangles have frequently appeared in man made constructions: