Right Triangle and the Pythagorean Theorem

The Pythagorean Theorem is one of the most important tools in geometry: it connects the three sides of a right triangle and lets us find a missing side from the other two. On this page we will learn how to find a leg or the hypotenuse, get to know Pythagorean triples that save us calculation effort, and determine when a triangle is actually a right triangle.

Background and Basic Definitions

A right triangle has one angle of \(90^\circ\). The two sides that form the right angle are called legs, and the longest side — the one opposite the right angle — is called the hypotenuse.

The Pythagorean Theorem: the sum of the squares of the legs equals the square of the hypotenuse:

\[ a^2 + b^2 = c^2 \]

where \(a\) and \(b\) are the legs and \(c\) is the hypotenuse. It follows that:

Finding the hypotenuse: \(c = \sqrt{a^2 + b^2}\)
Finding a leg: \(a = \sqrt{c^2 - b^2}\)

Pythagorean triples are sets of whole numbers that satisfy the theorem. The most common ones are worth memorising:

Leg	Leg	Hypotenuse
3	4	5
5	12	13
8	15	17
7	24	25

Note: any multiple of a triple is also a triple. For example, \(6\text{-}8\text{-}10\) is twice the \(3\text{-}4\text{-}5\) triple.

Right triangle: a²+b²=c²

Solution Steps

Step 1 — Identify the right angle and determine which side is the hypotenuse (the side opposite the right angle, always the longest) and which sides are the legs.
Step 2 — Decide what is being asked: if the hypotenuse is missing, use \(c = \sqrt{a^2 + b^2}\); if a leg is missing, use \(a = \sqrt{c^2 - b^2}\).
Step 3 — Check whether the given values match a familiar Pythagorean triple (or a multiple of one) — this lets you read off the answer immediately without computing a square root.
Step 4 — Substitute the values, compute the squares, add or subtract, and take the square root.
Step 5 — Check your answer for reasonableness: the hypotenuse must be greater than each leg, and when finding a leg the result must be less than the hypotenuse.

Worked Examples

Example 1: Finding the Hypotenuse from Two Legs

Problem: In a right triangle the legs are \(9\) cm and \(40\) cm. Find the length of the hypotenuse.

Solution:

Label the legs \(a = 9\), \(b = 40\), and the hypotenuse \(c\).
By the Pythagorean Theorem: \(c^2 = a^2 + b^2 = 9^2 + 40^2\).
Calculate: \(81 + 1600 = 1681\).
Take the square root: \(c = \sqrt{1681} = 41\).
Note that this is the Pythagorean triple \(9\text{-}40\text{-}41\), and the hypotenuse is indeed larger than both legs.

Answer: The hypotenuse is \(41\) cm.

Example 2: Finding a Leg Using a Triple

Problem: In a right triangle the hypotenuse is \(26\) cm and one leg is \(10\) cm. Find the other leg.

Solution:

Label \(c = 26\) (hypotenuse), \(a = 10\), and the unknown leg \(b\).
Isolate: \(b^2 = c^2 - a^2 = 26^2 - 10^2\).
Calculate: \(676 - 100 = 576\).
Take the square root: \(b = \sqrt{576} = 24\).
This is twice the \(5\text{-}12\text{-}13\) triple, giving \(10\text{-}24\text{-}26\).

Answer: The other leg is \(24\) cm.

Example 3: Checking Whether a Triangle Is a Right Triangle

Problem: A triangle has sides \(20\), \(21\), and \(29\). Is it a right triangle?

Solution:

The longest side is \(29\), so if the triangle is a right triangle it must be the hypotenuse.
Check whether \(20^2 + 21^2 = 29^2\) holds.
Left side: \(400 + 441 = 841\).
Right side: \(29^2 = 841\).
Both sides are equal, so by the converse of the Pythagorean Theorem the triangle is a right triangle.

Answer: Yes, the triangle is a right triangle (the hypotenuse is the side of length \(29\)).

Example 4: Applied Problem — Ladder Leaning Against a Wall

Problem: A \(17\)-metre ladder leans against a vertical wall with its base \(8\) metres from the base of the wall. How high up the wall does the top of the ladder reach?

Solution:

The ladder, wall, and ground form a right triangle. The ladder is the hypotenuse \(c = 17\), the ground distance is a leg \(a = 8\), and the height \(b\) is the unknown leg.
Write: \(b^2 = c^2 - a^2 = 17^2 - 8^2\).
Calculate: \(289 - 64 = 225\).
Take the square root: \(b = \sqrt{225} = 15\).
This is the \(8\text{-}15\text{-}17\) Pythagorean triple.

Answer: The top of the ladder reaches a height of \(15\) metres.

Common Mistakes

✗ Common mistake: Adding the squares of all three sides even when looking for a leg, resulting in an overly large hypotenuse.

✓ The correct way: When finding a leg, subtract: \(b^2 = c^2 - a^2\). Addition is used only when the hypotenuse is the missing side. Always confirm which side is the hypotenuse first.

✗ Common mistake: Confusing the hypotenuse with a leg and substituting the hypotenuse in the leg's place in the formula.

✓ The correct way: The hypotenuse is always the side opposite the right angle and is the longest side. Label it \(c\) before you begin calculating.

✗ Common mistake: Forgetting to take the square root at the end and leaving the answer as a squared value — for example, stating that the hypotenuse is 1681 instead of 41.

✓ The correct way: The formula gives the square of the side. The final step is always to take the square root: \(c = \sqrt{c^2}\).

Practice Tips

Tip — Memorise the triples \(3\text{-}4\text{-}5\), \(5\text{-}12\text{-}13\), \(8\text{-}15\text{-}17\), \(7\text{-}24\text{-}25\). They spare you from computing square roots.
Tip — If your sides are a multiple of a familiar triple (e.g. \(6\text{-}8\text{-}10\) or \(15\text{-}36\text{-}39\)), reduce first to recognise the pattern.
Tip — Quick sanity check: the hypotenuse is always greater than each leg, but less than the sum of the two legs.
Tip — Converse of Pythagoras: if \(a^2 + b^2 = c^2\) the triangle is right-angled; if \(a^2 + b^2 \lt c^2\) it is obtuse; if \(a^2 + b^2 \gt c^2\) it is acute.

Summary and Key Formulas

The key formula: \(a^2 + b^2 = c^2\), where \(c\) is the hypotenuse.

Finding the hypotenuse: \(c = \sqrt{a^2 + b^2}\)
Finding a leg: \(a = \sqrt{c^2 - b^2}\)
Triples to remember: \(3\text{-}4\text{-}5\), \(5\text{-}12\text{-}13\), \(8\text{-}15\text{-}17\), \(7\text{-}24\text{-}25\) and their multiples.
Checking for a right triangle: compare \(a^2 + b^2\) with \(c^2\) of the longest side.