Difference between revisions of "Euler's inequality"

Latest revision as of 10:09, 9 May 2025

Euler's Inequality states that $R \ge 2r$ where R is the circumradius and r is the inradius of a non-degenerate triangle

Proof

Let the circumradius be $R$ and inradius $r$ . Let $d$ be the distance between the circumcenter and the incenter. Then $d=\sqrt{R(R-2r)}$ From this formula, Euler's Inequality follows as $d^2=R(R-2r)$ By the Trivial Inequality, $R(R-2r)$ is positive. Since $R$ has to be positive as it is the circumradius, $R-2r \ge 0$ $R \ge 2r$ as desired.

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-==Euler's Inequality==
+Euler's Inequality states that <cmath>R \ge 2r</cmath> where R is the circumradius and r is the inradius of a non-degenerate triangle
-Euler's Inequality states that <cmath>R \gt 2r</cmath>
 ==Proof==
-Let the circumradius be <math>R</math> and inradius <math>r</math>. Let <math>d</math> be the distance between the circumcenter and the incenter. Then <cmath>d=\sqrt{R(R-2r)}</cmath>. From this formula, Euler's Inequality follows
+Let the circumradius be <math>R</math> and inradius <math>r</math>. Let <math>d</math> be the distance between the circumcenter and the incenter. Then <cmath>d=\sqrt{R(R-2r)}</cmath> From this formula, Euler's Inequality follows as <cmath>d^2=R(R-2r)</cmath> By the [[Trivial Inequality]], <math>R(R-2r)</math> is positive. Since <math>R</math> has to be positive as it is the circumradius, <math> R-2r \ge 0 </math> <math> R \ge 2r </math> as desired.

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Difference between revisions of "Euler's inequality"

Latest revision as of 10:09, 9 May 2025

Proof