If $a,b,c$ be the radii of three circles which touch one another externally,$r_1$ and $r_2$ be the radii of two circles that can be drawn to touch these three,prove that,$\frac{1}{r_1}-\frac{1}{r_2}=\frac{2}{a}+\frac{2}{b}+\frac{2}{c}$
What will be the formula of $r_1,r_2$ in terms of $a,b,c?$I don't know the formula or the method to prove directly.
Using Descartes' Theorem, for each of the circles that touch the three, $$ \left(\frac1a+\frac1b+\frac1c+\frac1{r_k}\right)^2=2\left(\frac1{a^2}+\frac1{b^2}+\frac1{c^2}+\frac1{r_k^2}\right) $$ Subtracting these equations for $r_1$ and $r_2$ gives $$ \left(\frac1{r_1}-\frac1{r_2}\right)\left(\frac2a+\frac2b+\frac2c+\frac1{r_1}+\frac1{r_2}\right)=2\left(\frac1{r_1^2}-\frac1{r_2^2}\right) $$ Dividing both sides by $\frac1{r_1}-\frac1{r_2}$ gives $$ \frac2a+\frac2b+\frac2c+\frac1{r_1}+\frac1{r_2}=2\left(\frac1{r_1}+\frac1{r_2}\right) $$ and finally, $$ \frac2a+\frac2b+\frac2c=\frac1{r_1}+\frac1{r_2} $$ This looks different, but the externally tangent circle has a negative bend ($\frac1r$), so correcting for that, we get $$ \bbox[5px,border:2px solid #C0A000]{\frac2a+\frac2b+\frac2c=\frac1{r_1}-\frac1{r_2}} $$ where $r_2$ is the radius of the externally tangent circle.
Example:
Let $a=1$, $b=2$, and $c=3$. Using Descartes' Theorem, we compute $$ r_1=\frac{6}{23}\quad\text{and}\quad r_2=6 $$ so that $$ \frac21+\frac22+\frac23=\frac{23}{6}-\frac16 $$