4.18: Exterior Angles and Theorems (2024)

Example \(\PageIndex{1}\)

Two interior angles of a triangle are \(40^{\circ}\) and \(73^{\circ}\). What are the measures of the three exterior angles of the triangle?

Solution

Remember that every interior angle forms a linear pair (adds up to \(180^{\circ}\)) with an exterior angle. So, since one of the interior angles is \(40^{\circ}\) that means that one of the exterior angles is \(140^{\circ}\) (because \(40+140=180\)). Similarly, since another one of the interior angles is \(73^{\circ}\), one of the exterior angles must be \(107^{\circ}\). The third interior angle is not given to us, but we could figure it out using the Triangle Sum Theorem. We can also use the Exterior Angle Sum Theorem. If two of the exterior angles are \(140^{\circ}\) and \(107^{\circ}\), then the third Exterior Angle must be \(113^{\circ}\) since \(140+107+113=360\).

So, the measures of the three exterior angles are 140, 107 and 113.

Example \(\PageIndex{2}\)

Find the value of \(x\) and the measure of each angle.

Solution

Set up an equation using the Exterior Angle Theorem.

\(\begin{align*} \underbrace{(4x+2)^{\circ}+(2x−9)^{\circ}}_\text{remote interior angles}&=\underbrace{(5x+13)^{\circ}}_\text{exterior angle} \\ (6x−7)^{\circ}&=(5x+13)^{\circ} \\ x&=20 \end{align*}\)

Substitute in 20 for \(x\) to find each angle.

\([4(20)+2]^{\circ}=82^{\circ}[2(20)−9]^{\circ}=31^{\circ} \qquad Exterior \:angle:\: [5(20)+13]^{\circ}=113^{\circ}\)

Example \(\PageIndex{3}\)

Find the measure of \(\angle RQS\).

Solution

Notice that \(112^{\circ}\) is an exterior angle of \(\Delta RQS\) and is supplementary to \(\angle RQS\).

Set up an equation to solve for the missing angle.

\(\begin{align*}112^{\circ}+m\angle RQS &=180^{\circ} \\ m\angle RQS&=68^{\circ}\end{align*}\)

Example \(\PageIndex{4}\)

Find the measures of the numbered interior and exterior angles in the triangle.

Solution

We know that \(m\angle 1+92^{\circ}=180^{\circ}\) because they form a linear pair. So, m\angle 1=88^{\circ}\).

Similarly, \(m\angle 2+123^{\circ}=180^{\circ}\) because they form a linear pair. So, m\angle 2=57^{\circ}\).

We also know that the three interior angles must add up to 180^{\circ}\) by the Triangle Sum Theorem.

\(\begin{align*} m\angle 1+m\angle 2+m\angle 3&=180^{\circ} \qquad by\: the \:Triangle \:Sum \:Theorem. \\ 88^{\circ}+57^{\circ}+m\angle 3&=180 \\ m\angle 3&=35^{\circ}\end{align*}\)

Lastly, \(m\angle 3+m\angle 4=180^{\circ} \qquad because\: they\: form \:a \:linear \:pair.\)

\(\begin{align*} 35^{\circ}+m\angle 4&=180^{\circ} \\ m\angle 4&=145^{\circ}\end{align*}\)

Example \(\PageIndex{5}\)

What is the value of \(p\) in the triangle below?

Solution

First, we need to find the missing exterior angle, which we will call \(x\). Set up an equation using the Exterior Angle Sum Theorem.

\(\begin{align*} 130^{\circ}+110^{\circ}+x&=360^{\circ} \\ x&=360^{\circ}−130^{\circ}−110^{\circ} \\ x&=120^{\circ}\end{align*} \)

\(x\) and \(p\) add up to \(180^{\circ}\) because they are a linear pair.

\(\begin{align*} x+p&=180^{\circ} \\ 120^{\circ}+p&=180^{\circ} \\ p&=60^{\circ}\end{align*}\)

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