Sides If angle
C is obtuse then for sides
a,
b, and
c we have :\frac{c^2}{2} with the left inequality approaching equality in the limit only as the apex angle of an isosceles triangle approaches 180°, and with the right inequality approaching equality only as the obtuse angle approaches 90°. If the triangle is acute then :a^2+b^2 > c^2, \quad b^2+c^2 > a^2, \quad c^2+a^2 > b^2.
Altitude If C is the greatest angle and
hc is the altitude from vertex
C, then for an acute triangle :\frac{1}{h_c^2} with the opposite inequality if C is obtuse.
Medians With longest side
c and
medians ma and
mb from the other sides, :4c^2 +9a^2b^2 > 16m_a^2m_b^2 for an acute triangle but with the inequality reversed for an obtuse triangle. The median
mc from the longest side is greater or less than the circumradius for an acute or obtuse triangle respectively: :m_c > R for acute triangles, with the opposite for obtuse triangles.
Area Ono's inequality for the area
A, :27 (b^2 + c^2 - a^2)^2 (c^2 + a^2 - b^2)^2 (a^2 + b^2 - c^2)^2 \leq (4 A)^6, holds for all acute triangles but not for all obtuse triangles.
Trigonometric functions For an acute triangle we have, for angles
A,
B, and
C, :\cos^2A+\cos^2B+\cos^2C with the reverse inequality holding for an obtuse triangle. For an acute triangle with circumradius
R, :a\cos^3 A +b\cos^3 B +c\cos^3 C \leq \frac{abc}{4R^2} and :\cos^3A+\cos^3B+\cos^3C+\cos A\cos B\cos C\geq\frac{1}{2}. For an acute triangle, :\sin^2 A+\sin^2 B+\sin^2 C > 2, with the reverse inequality for an obtuse triangle. For an acute triangle, :\sin A \cdot \sin B +\sin B \cdot \sin C + \sin C \cdot \sin A \leq (\cos A+\cos B+\cos C)^2. For any triangle the
triple tangent identity states that the sum of the angles'
tangents equals their product. Since an acute angle has a positive tangent value while an obtuse angle has a negative one, the expression for the product of the tangents shows that :\tan A+\tan B+\tan C = \tan A \cdot \tan B \cdot \tan C > 0 for acute triangles, while the opposite direction of inequality holds for obtuse triangles. We have :\tan A +\tan B+\tan C \geq 2(\sin 2A+\sin 2B+\sin 2C) for acute triangles, and the reverse for obtuse triangles. For all acute triangles, :(\tan A+\tan B+\tan C)^2 \geq (\sec A+1)^2+(\sec B+1)^2+(\sec C+1)^2. For all acute triangles with
inradius r and
circumradius R, :a\tan A+ b\tan B+c\tan C \geq 10R-2r. For an acute triangle with area
K, :(\sqrt{\cot A}+\sqrt{\cot B}+\sqrt{\cot C})^2 \leq \frac{K}{r^2}.
Circumradius, inradius, and exradii In an acute triangle, the sum of the circumradius
R and the inradius
r is less than half the sum of the shortest sides
a and
b: :R+r while the reverse inequality holds for an obtuse triangle. For an acute triangle with
medians ma ,
mb , and
mc and circumradius
R, we have :m_a^2+m_b^2+m_c^2 > 6R^2 while the opposite inequality holds for an obtuse triangle. Also, an acute triangle satisfies :r^2+r_a^2+r_b^2+r_c^2 in terms of the
excircle radii
ra ,
rb , and
rc , again with the reverse inequality holding for an obtuse triangle. For an acute triangle with semiperimeter
s, :s-r >2R, and the reverse inequality holds for an obtuse triangle. For an acute triangle with area
K, :ab+bc+ca \geq 2R(R+r)+\frac{8K}{\sqrt{3}}.
Distances involving triangle centers For an acute triangle the distance between the circumcenter
O and the orthocenter
H satisfies :OH with the opposite inequality holding for an obtuse triangle. For an acute triangle the distance between the incircle center
I and orthocenter
H satisfies :IH where
r is the
inradius, with the reverse inequality for an obtuse triangle.
Inscribed square If one of the inscribed squares of an acute triangle has side length
xa and another has side length
xb with
xa b, then :1 \geq \frac{x_a}{x_b} \geq \frac{2\sqrt{2}}{3} \approx 0.94.
Two triangles If two obtuse triangles have sides (
a, b, c) and (
p, q, r) with
c and
r being the respective longest sides, then :ap+bq ==Examples==