discriminant (1 Viewer)

Aesytic · Dec 1, 2011

for what values of p does the equation px^2 - 4x + p = 0 have real roots?
the answer is -2<=p<=2, but i was wondering, can p=0? because it just asks for real roots, and if p=0 then x=0, but does that still count?

marksgm · Dec 1, 2011

yes p can equal 0!

marksgm · Dec 1, 2011

since the equation is quadratic AND has TWO real roots since discriminant >0 . working out through the quadratic formula, we get that the roots are 0 and 4p. Meaning the parabola px^2 - 4x + p^2 = 0 cuts the x-axis at (0,0) and (4p,0). so yes x can equal zero since the parabola passes through (0,0)

Aesytic · Dec 1, 2011

ah, ok, thanks for that!

edit: sorry, the constant is actually p. does that change anything?

Trebla · Dec 1, 2011

Aesytic said:
for what values of p does the equation px^2 - 4x + p = 0 have real roots?
the answer is -2<=p<=2, but i was wondering, can p=0? because it just asks for real roots, and if p=0 then x=0, but does that still count?

If p = 0 the equation is no longer a quadratic and therefore the usual idea of discriminants don't apply. This can be seen from the quadratic formula that

$x=\dfrac{4 \pm \sqrt{16-4p^2}}{2p}=\dfrac{2 \pm \sqrt{4-p^2}}{p}$

Note that p is non-zero for a solution to exist for the quadratic. So technically speaking when we look at the quadratic formula, for real roots we have

$4-p^2 \geq 0\:$ with $ p\neq 0\\\\\Rightarrow -2 \leq p < 0 \:$ and $\: 0 < p \leq 2$

Now we consider the case when p = 0 in isolation (because the equation is no longer quadratic the above treatment is not appropriate). This implies x = 0 which is clearly a real root thus we include it in our domain which leads to

$-2\leq p \leq 2$

cutemouse · Dec 2, 2011

Trebla said:
If p = 0 the equation is no longer a quadratic and therefore the usual idea of discriminants don't apply.

Well, if one has done a bit of linear algebra, then one would conclude that it is a polynomial in P^2 (R)... ie a vector (s,t,0)^T with respect to the standard basis {1,x,x^2} for s,t real...

So it still could be a quadratic. It just depends how you define one...

Aesytic · Dec 2, 2011

Trebla said:
If p = 0 the equation is no longer a quadratic and therefore the usual idea of discriminants don't apply. This can be seen from the quadratic formula that

$x=\dfrac{4 \pm \sqrt{16-4p^2}}{2p}=\dfrac{2 \pm \sqrt{4-p^2}}{p}$

Note that p is non-zero for a solution to exist for the quadratic. So technically speaking when we look at the quadratic formula, for real roots we have

$4-p^2 \geq 0\:$ with $ p\neq 0\\\\\Rightarrow -2 \leq p < 0 \:$ and $\: 0 < p \leq 2$

Now we consider the case when p = 0 in isolation (because the equation is no longer quadratic the above treatment is not appropriate). This implies x = 0 which is clearly a real root thus we include it in our domain which leads to

$-2\leq p \leq 2$

yeah, i just checked with my teacher today, and he said the same thing. thanks for the help!

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