Triangle Inequality

The triangle inequality is a very important geometric and algebraic property that we will use frequently in the future.

Theorem 1 (Triangle Inequality): Let ${\displaystyle a}$ and ${\displaystyle b}$ be real numbers. Then ${\displaystyle \mid a+b\mid \leq \mid a\mid +\mid b\mid }$.

• Proof of Theorem: For ${\displaystyle a}$ and ${\displaystyle b}$ as real numbers we have that ${\displaystyle -\mid a\mid \leq a\leq \mid a\mid }$ and ${\displaystyle -\mid b\mid \leq b\leq \mid b\mid }$. If we add these inequalities together we get that ${\displaystyle -\mid a\mid -\mid b\mid \leq a+b\leq \mid a\mid +\mid b\mid }$ or rather ${\displaystyle -\left(\mid a\mid +\mid b\mid \right)\leq a+b\leq \left(\mid a\mid +\mid b\mid \right)}$ which is equivalent to saying that ${\displaystyle \mid a+b\mid \leq \mid a\mid +\mid b\mid }$. ${\displaystyle \blacksquare }$

There are also some other important results similar to the triangle inequality that are important to mention.

Corollary 1: If ${\displaystyle a}$ and ${\displaystyle b}$ are real numbers then ${\displaystyle \mid \mid a\mid -\mid b\mid \mid \leq \mid a-b\mid }$.

• Proof of Corollary 1: We first write ${\displaystyle a=a-b+b}$ and therefore applying the triangle inequality we get that ${\displaystyle \mid a\mid =\mid (a-b)+b\mid \leq \mid a-b\mid +\mid b\mid }$ and therefore ${\displaystyle \mid a\mid \leq \mid a-b\mid +\mid b\mid }$. Subtracting ${\displaystyle \mid b\mid }$ from both sides we get that ${\displaystyle \mid a\mid -\mid b\mid \leq \mid a-b\mid }$.

• Now we write ${\displaystyle b=b-a+a}$ and therefore applying the triangle inequality we get that ${\displaystyle \mid b\mid =\mid (b-a)+a\mid \leq \mid b-a\mid +\mid a\mid }$ and therefore ${\displaystyle \mid b\mid \leq \mid b-a\mid +\mid a\mid }$ and subtracting ${\displaystyle \mid a\mid }$ from both sides we get that ${\displaystyle \mid b\mid -\mid a\mid \leq \mid b-a\mid }$ which is equivalent to ${\displaystyle \mid a\mid -\mid b\mid \geq -\mid b-a\mid }$.

• Therefore ${\displaystyle \mid \mid a\mid -\mid b\mid \mid \leq \mid a+b\mid }$. ${\displaystyle \blacksquare }$

Corollary 2: If ${\displaystyle a}$ and ${\displaystyle b}$ are real numbers then ${\displaystyle \mid a-b\mid \leq \mid a\mid +\mid b\mid }$.

• Proof of Corollary 2: By the triangle inequality we get that ${\displaystyle \mid a+b\mid \leq \mid a\mid +\mid b\mid }$ and so then ${\displaystyle \mid a+(-b)\mid \leq \mid a\mid +\mid -b\mid =\mid a\mid +\mid b\mid }$. Therefore ${\displaystyle \mid a-b\mid \leq \mid a\mid +\mid b\mid }$. ${\displaystyle \blacksquare }$

Corollary 3: If ${\displaystyle a_{1},a_{2},...,a_{n}\in \mathbb {R} }$ then ${\displaystyle \mid a_{1}+a_{2}+...+a_{n}\mid \leq \mid a_{1}\mid +\mid a_{2}\mid +...+\mid a_{n}\mid }$.

• Proof of Corollary 3: We note that ${\displaystyle \mid a_{1}+a_{2}+...+a_{n}\mid =\mid a_{1}+(a_{2}+...+a_{n})\mid \leq \mid a_{1}\mid +\mid a_{2}+...+a_{n}\mid }$ by the triangle inequality. Applying the triangle inequality multiple times we eventually get that ${\displaystyle \mid a_{1}+a_{2}+...+a_{n}\mid \leq \mid a_{1}\mid +\mid a_{2}\mid +...+\mid a_{n}\mid }$. ${\displaystyle \blacksquare }$

A more formal proof of Corollary 3 can be carried out by Mathematical Induction.

Licensing

Content obtained and/or adapted from:

• The Triangle Inequality, mathonline.wikidot.com under a CC BY-SA license