$S$ and $G$ are roots of $x^2 −3x +1=0$. Find equation whose roots are $\frac{1}{S -2}$ and$\frac{1}{G-2}$

Question

If S,G are roots of $x^2 −3x +1=0$, then find equation whose roots are $\frac{1}{S -2}$ , $\frac{1}{G-2}$.

So , the way my sir solved it is that

He took x = $\frac{1}{S -2}$ , then he got S = $\frac{2x+1}{x}$.

I am confused with is that we were told roots as $\frac{1}{S -2}$ and not only S for 2nd equation.

Why not just put $\frac{1}{S -2}$ in x and then solve ?

See https://math.stackexchange.com/questions/2209034/finding-sum-k-0n-1-frac-alpha-k2-alpha-k-where-alpha-k-are-the OR https://math.stackexchange.com/questions/1909362/product-of-one-minus-the-tenth-roots-of-unity OR https://math.stackexchange.com/questions/1811081/problem-based-on-sum-of-reciprocal-of-nth-roots-of-unity — lab bhattacharjee, Jan 02 '21 at 17:40
We have $S^2-3S+1=0$ and not $A^2-3A+1=0$ where $A=1/(S-2)$. It is $S$ that satisfies the given quadratic, not $1/(S-2)$. — cosmo5, Jan 02 '21 at 17:42

Quanto · Answer 1 · 2021-01-02T17:53:21.600

1

Note $SG=1,\>S+G=3$. Then

$$\frac1{S-2}\frac1{G-2}=\frac1{SG-2(S+G)+4}=-1 $$ $$\frac1{S-2}+\frac1{G-2}=\frac{S+G-4}{SG-2(S+G)+4}=1 $$ Thus, the equation with roots $\frac1{S-2}$ and $\frac1{G-2}$ is $$x^2-x-1=0$$

edited Jan 02 '21 at 17:53

answered Jan 02 '21 at 17:44

Quanto

97,352

score 1 · Answer 2 · answered Jan 02 '21 at 17:54

The substitution method your teacher is referring to goes as follows:

Let $y=\frac{1}{x-2}$ where $x=S, G$ are the roots of the given equation $x^2-3x+1=0$

Rearranging gives $x=\frac{1+2y}{y}$

Substituting this into the equation satisfied by $x$ gives $$(\frac{1+2y}{y})^2-3(\frac{1+2y}{y})+1=0$$

This simplifies to become $$y^2-y-1=0$$ This is the same as the answer obtained by Quanto using Vieta's formulas.

$S$ and $G$ are roots of $x^2 −3x +1=0$. Find equation whose roots are $\frac{1}{S -2}$ and$\frac{1}{G-2}$

2 Answers2