Triangle Calculator Guide: Sides, Angles & Area
A thorough reference for solving any triangle — right, acute, or obtuse — using trigonometric laws (Law of Sines, Law of Cosines), the Pythagorean theorem, and Heron's formula for area.
Related Calculator
Use the Triangle Calculator to apply what you learn in this guide.
What Is a Triangle?
A triangle is a polygon with three sides and three angles. The sum of all interior angles is always exactly 180°. This fundamental constraint — combined with the relationships between sides and angles — allows us to fully determine any triangle if we know enough information about it.
Triangles are classified in two ways:
- By angles: Acute (all angles < 90°), Right (one angle = 90°), Obtuse (one angle > 90°)
- By sides: Equilateral (all sides equal), Isosceles (two sides equal), Scalene (all sides different)
The Pythagorean Theorem (Right Triangles)
For any right triangle with legs a and b and hypotenuse c (the side opposite the right angle):
$$ a^2 + b^2 = c^2 $$
Example: A right triangle has legs of 6 and 8. Find the hypotenuse.
$$ c = \sqrt{6^2 + 8^2} = \sqrt{36 + 64} = \sqrt{100} = 10 $$
Trigonometric Ratios (SOH-CAH-TOA)
For a right triangle with an angle θ, opposite side O, adjacent side A, and hypotenuse H:
$$ \sin\theta = \frac{O}{H}, \quad \cos\theta = \frac{A}{H}, \quad \tan\theta = \frac{O}{A} $$
Law of Sines
The Law of Sines applies to any triangle (right or oblique) and relates sides to their opposite angles:
$$ \frac{a}{\sin A} = \frac{b}{\sin B} = \frac{c}{\sin C} $$
Best used when: You know two angles and one side (AAS or ASA), or two sides and an angle opposite one of them (SSA — but watch for the ambiguous case).
Example: In triangle ABC, A = 45°, B = 70°, and side a = 12. Find side b.
First find C: C = 180° − 45° − 70° = 65°
$$ \frac{12}{\sin 45°} = \frac{b}{\sin 70°} \implies b = \frac{12 \times \sin 70°}{\sin 45°} = \frac{12 \times 0.9397}{0.7071} \approx 15.95 $$
Law of Cosines
The Law of Cosines generalises the Pythagorean theorem to all triangles:
$$ c^2 = a^2 + b^2 - 2ab \cdot \cos C $$
(And equivalently for sides a and b by cycling the labels.)
Best used when: You know three sides (SSS) or two sides and the included angle (SAS).
Example: A triangle has sides a = 7, b = 10, and included angle C = 50°. Find side c.
$$ c^2 = 7^2 + 10^2 - 2(7)(10)\cos(50°) = 49 + 100 - 140 \times 0.6428 = 149 - 89.99 = 59.01 $$ $$ c = \sqrt{59.01} \approx 7.68 $$
Heron's Formula for Area
When you know all three side lengths (SSS), Heron's formula gives the area without needing an angle:
Step 1 — Calculate the semi-perimeter:
$$ s = \frac{a + b + c}{2} $$
Step 2 — Apply Heron's formula:
$$ A = \sqrt{s(s-a)(s-b)(s-c)} $$
Example: Triangle with sides 9, 12, and 15.
$$ s = \frac{9 + 12 + 15}{2} = 18 $$ $$ A = \sqrt{18(18-9)(18-12)(18-15)} = \sqrt{18 \times 9 \times 6 \times 3} = \sqrt{2916} = 54 \text{ square units} $$
(Note: this is also a right triangle since 9² + 12² = 225 = 15², confirming the area using ½ × 9 × 12 = 54.)
Decision Table — Which Method to Use?
| Given Information | Configuration | Method to Use |
|---|---|---|
| Three sides | SSS | Law of Cosines → Heron's formula for area |
| Two sides + included angle | SAS | Law of Cosines → Law of Sines for remaining |
| Two angles + one side | AAS or ASA | Law of Sines (find third angle first: 180° − A − B) |
| Two sides + non-included angle | SSA | Law of Sines (check for ambiguous case) |
| Hypotenuse + one leg (right Δ) | Right triangle | Pythagorean theorem + SOH-CAH-TOA |
| All three angles only | AAA | Shape determined but NOT size (infinite solutions) |
Full Example — Solving an Oblique Triangle (SAS)
Problem: A surveyor measures two sides of a triangular plot of land as 120 m and 85 m, with an included angle of 67°. Find the third side, the other two angles, and the area.
Step 1 — Find the third side using Law of Cosines (c² = a² + b² − 2ab·cosC):
$$ c^2 = 120^2 + 85^2 - 2(120)(85)\cos(67°) $$ $$ = 14{,}400 + 7{,}225 - 20{,}400 \times 0.3907 = 21{,}625 - 7{,}970 = 13{,}655 $$ $$ c \approx 116.9 \text{ m} $$
Step 2 — Find angle A using Law of Sines:
$$ \frac{\sin A}{120} = \frac{\sin 67°}{116.9} \implies \sin A = \frac{120 \times 0.9205}{116.9} \approx 0.9449 \implies A \approx 70.8° $$
Step 3 — Find angle B:
$$ B = 180° - 67° - 70.8° = 42.2° $$
Step 4 — Calculate area:
$$ \text{Area} = \frac{1}{2} \times 120 \times 85 \times \sin(67°) = 0.5 \times 120 \times 85 \times 0.9205 \approx 4{,}698 \text{ m}^2 $$
Frequently Asked Questions
Q: What is the ambiguous case (SSA)? A: When given two sides and a non-included angle (SSA), the Law of Sines may produce 0, 1, or 2 valid triangles. Given sides a, b and angle A: if a < b·sinA, no triangle exists; if a = b·sinA, exactly one right triangle exists; if b·sinA < a < b, two triangles are possible (you must solve for both and check which is valid in context); if a ≥ b, exactly one triangle exists.
Q: Can I use the Law of Cosines for right triangles? A: Yes. When C = 90°, cos(90°) = 0, so the term 2ab·cosC vanishes and the formula reduces exactly to the Pythagorean theorem: c² = a² + b².
Q: What if I only have three angles (AAA)? A: Three angles determine the shape of a triangle (all such triangles are similar) but not its size. An infinite number of triangles satisfy AAA, scaled differently. You need at least one side length to determine a unique triangle.
Q: Are there other area formulas besides Heron's and ½·base·height? A: Yes. When two sides and an included angle are known: Area = ½·a·b·sinC. This is often the quickest method for SAS configurations and avoids needing the third side first.
Q: What is the exterior angle theorem? A: An exterior angle of a triangle equals the sum of the two non-adjacent interior angles. This is a handy shortcut: if two angles are 45° and 70°, the exterior angle at the third vertex is 115°.