240 132 330 triangle

Obtuse scalene triangle.

Sides: a = 240 b = 132 c = 330

Area: T = 13385.87546072
Perimeter: p = 702
Semiperimeter: s = 351

Angle ∠ A = α = 37.92224831781° = 37°55'21″ = 0.6621872192 rad
Angle ∠ B = β = 19.75767220686° = 19°45'24″ = 0.34548198495 rad
Angle ∠ C = γ = 122.3210794753° = 122°19'15″ = 2.13549006121 rad

Height: h_a = 111.549895506
Height: h_b = 202.8166281928
Height: h_c = 81.1276512771

Median: m_a = 220.8211194635
Median: m_b = 280.8810757618
Median: m_c = 101.4254849026

Inradius: r = 38.13663948923
Circumradius: R = 195.2510596371

Vertex coordinates: A[330; 0] B[0; 0] C[225.8732727273; 81.1276512771]
Centroid: CG[185.2910909091; 27.04221709237]
Coordinates of the circumscribed circle: U[165; -104.3932506355]
Coordinates of the inscribed circle: I[219; 38.13663948923]

Exterior (or external, outer) angles of the triangle:
∠ A' = α' = 142.0787516822° = 142°4'39″ = 0.6621872192 rad
∠ B' = β' = 160.2433277931° = 160°14'36″ = 0.34548198495 rad
∠ C' = γ' = 57.67992052467° = 57°40'45″ = 2.13549006121 rad

Calculate another triangle

How did we calculate this triangle?

1. The triangle perimeter is the sum of the lengths of its three sides

p = a+b+c = 240+132+330 = 702

2. Semiperimeter of the triangle

The semiperimeter of the triangle is half its perimeter. The semiperimeter frequently appears in formulas for triangles that it is given a separate name. By the triangle inequality, the longest side length of a triangle is less than the semiperimeter.

s = \dfrac{ p }{ 2 } = \dfrac{ 702 }{ 2 } = 351

3. The triangle area using Heron's formula

Heron's formula gives the area of a triangle when the length of all three sides are known. There is no need to calculate angles or other distances in the triangle first. Heron's formula works equally well in all cases and types of triangles.

T = \sqrt{ s(s-a)(s-b)(s-c) } \ \\ T = \sqrt{ 351(351-240)(351-132)(351-330) } \ \\ T = \sqrt{ 179181639 } = 13385.87

4. Calculate the heights of the triangle from its area.

There are many ways to find the height of the triangle. The easiest way is from the area and base length. The area of a triangle is half of the product of the length of the base and the height. Every side of the triangle can be a base; there are three bases and three heights (altitudes). Triangle height is the perpendicular line segment from a vertex to a line containing the base.

T = \dfrac{ a h _a }{ 2 } \ \\ \ \\ h _a = \dfrac{ 2 \ T }{ a } = \dfrac{ 2 \cdot \ 13385.87 }{ 240 } = 111.55 \ \\ h _b = \dfrac{ 2 \ T }{ b } = \dfrac{ 2 \cdot \ 13385.87 }{ 132 } = 202.82 \ \\ h _c = \dfrac{ 2 \ T }{ c } = \dfrac{ 2 \cdot \ 13385.87 }{ 330 } = 81.13

5. Calculation of the inner angles of the triangle using a Law of Cosines

The Law of Cosines is useful for finding the angles of a triangle when we know all three sides. The cosine rule, also known as the law of cosines, relates all three sides of a triangle with an angle of a triangle. The Law of Cosines is the extrapolation of the Pythagorean theorem for any triangle. Pythagorean theorem works only in a right triangle. Pythagorean theorem is a special case of the Law of Cosines and can be derived from it because the cosine of 90° is 0. It is best to find the angle opposite the longest side first. With the Law of Cosines, there is also no problem with obtuse angles as with the Law of Sines, because cosine function is negative for obtuse angles, zero for right, and positive for acute angles. We also use inverse cosine called arccosine to determine the angle from cosine value.

a^2 = b^2+c^2 - 2bc \cos α \ \\ \ \\ α = \arccos(\dfrac{ b^2+c^2-a^2 }{ 2bc } ) = \arccos(\dfrac{ 132^2+330^2-240^2 }{ 2 \cdot \ 132 \cdot \ 330 } ) = 37^\circ 55'21" \ \\ \ \\ b^2 = a^2+c^2 - 2ac \cos β \ \\ β = \arccos(\dfrac{ a^2+c^2-b^2 }{ 2ac } ) = \arccos(\dfrac{ 240^2+330^2-132^2 }{ 2 \cdot \ 240 \cdot \ 330 } ) = 19^\circ 45'24" \ \\ γ = 180^\circ - α - β = 180^\circ - 37^\circ 55'21" - 19^\circ 45'24" = 122^\circ 19'15"

6. Inradius

An incircle of a triangle is a circle which is tangent to each side. An incircle center is called incenter and has a radius named inradius. All triangles have an incenter, and it always lies inside the triangle. The incenter is the intersection of the three angle bisectors. The product of the inradius and semiperimeter (half the perimeter) of a triangle is its area.

T = rs \ \\ r = \dfrac{ T }{ s } = \dfrac{ 13385.87 }{ 351 } = 38.14

7. Circumradius

The circumcircle of a triangle is a circle that passes through all of the triangle's vertices, and the circumradius of a triangle is the radius of the triangle's circumcircle. Circumcenter (center of circumcircle) is the point where the perpendicular bisectors of a triangle intersect.

R = \dfrac{ a b c }{ 4 \ r s } = \dfrac{ 240 \cdot \ 132 \cdot \ 330 }{ 4 \cdot \ 38.136 \cdot \ 351 } = 195.25

8. Calculation of medians

A median of a triangle is a line segment joining a vertex to the midpoint of the opposite side. Every triangle has three medians, and they all intersect each other at the triangle's centroid. The centroid divides each median into parts in the ratio 2:1, with the centroid being twice as close to the midpoint of a side as it is to the opposite vertex. We use Apollonius's theorem to calculate the length of a median from the lengths of its side.

m_a = \dfrac{ \sqrt{ 2b^2+2c^2 - a^2 } }{ 2 } = \dfrac{ \sqrt{ 2 \cdot \ 132^2+2 \cdot \ 330^2 - 240^2 } }{ 2 } = 220.821 \ \\ m_b = \dfrac{ \sqrt{ 2c^2+2a^2 - b^2 } }{ 2 } = \dfrac{ \sqrt{ 2 \cdot \ 330^2+2 \cdot \ 240^2 - 132^2 } }{ 2 } = 280.881 \ \\ m_c = \dfrac{ \sqrt{ 2a^2+2b^2 - c^2 } }{ 2 } = \dfrac{ \sqrt{ 2 \cdot \ 240^2+2 \cdot \ 132^2 - 330^2 } }{ 2 } = 101.425

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