How do you find the rest of the zeros given one of the zero $c = \frac{1}{2}$ $c=1/2$ and the function $f (x) = 4 x^{4} - 28 x^{3} + 61 x^{2} - 42 x + 9$ $f(x)=4x^4-28x^3+61x^2-42x+9$ ?

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How do you find the rest of the zeros given one of the zero $c = \frac{1}{2}$ $c=1/2$ and the function $f (x) = 4 x^{4} - 28 x^{3} + 61 x^{2} - 42 x + 9$ $f(x)=4x^4-28x^3+61x^2-42x+9$ ?

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Answer 1 · 2016-12-29T22:32:50

The roots are $x = \frac{1}{2}$ $x=1/2$ (double root), $x = 3$ $x=3$ (double root).

Explanation:

You can't necessarily, but it may help. Let me explain;

The remainder theorem states that the remainder of the division of a polynomial $P (x)$ $P(x)$ by a linear polynomial $(x - a)$ $(x-a)$ is equal to $P (a)$ $P(a)$

So then the factor follows as a special case of the remainder theorem. The factor theorem states that a polynomial $P (x)$ $P(x)$ has a factor $(x - a)$ $(x - a)$ if and only $P (a) = 0$ $P(a)=0$

We know that $c = \frac{1}{2}$ $c=1/2$ is one root, So applying the factor theorem it must be that $(2 x - 1)$ $(2x-1)$ is a factor of $f (x)$ $f(x)$

We can then use polynomial division to divide $f (x)$ $f(x)$ by $(2 x - 1)$ $(2x-1)$ to reduce the quartic expression we started with to:

$f (x) = (2 x - 1) \times cubic expression$ $f(x) = (2x-1) xx "cubic expression"$

The BIG question is then can we further factorise that cubic?

The division (not shown) gives us.

$f (x) = (2 x - 1) (2 x^{3} - 13 x^{2} + 24 x - 9)$ $f(x)=(2x-1)(2x^3-13x^2+24x-9)$

By observation (ie I cheated and plotted the graph of $y = 2 x^{3} - 13 x^{2} + 24 x - 9$ $y=2x^3-13x^2+24x-9$ ) we can see that $x = 3$ $x=3$ is a root of the cubic. In reality we have to try various simple values $+-1, +-2,...$ in the vain hope that we find a further root (and hence a factor).

If we let:

$C(x) = 2x^3-13x^2+24x-9$ , then
$C(3) = 2*3^3-13*3^2+24*3-9 = 54-117+72-9=0$

So again using the factor theorem $(x-3)$ must be a factor also (of $f(x)$ and $C(x)$ ). Having found a factor of the cubic C(x) we can use polynomial division again to reduce the cubic to:

$C(x) = (x-3) xx "quadratic expression"$ ,

and indeed we get:

$\ \ \ \ C(x) = (x-3)(2x^2-7x+3)$
$:. f(x) = (2x-1)(x-3)(2x^2-7x+3)$

Now we have a quadratic left, we can hopefully factorise and we get:

$(2x^2-7x+3) = (x-3)(2x-1)$ :

$:. f(x) = (2x-1)(x-3)(x-3)(2x-1)$
$:. f(x) = (2x-1)^2(x-3)^2$

And so the roots are $x=1/2$ (double root), $x=3$ (double root).

We can confirm this graphically:

graph{4x^4-28x^3+61x^2-42x+9 [-5, 5, -5, 5]}

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How do you find the rest of the zeros given one of the zero $c = \frac{1}{2}$ $c=1/2$ and the function $f (x) = 4 x^{4} - 28 x^{3} + 61 x^{2} - 42 x + 9$ $f(x)=4x^4-28x^3+61x^2-42x+9$ ?

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How do you find the rest of the zeros given one of the zero c=1/2c=12c=1/2 and the function f(x)=4x^4-28x^3+61x^2-42x+9f(x)=4x4−28x3+61x2−42x+9f(x)=4x^4-28x^3+61x^2-42x+9?

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How do you find the rest of the zeros given one of the zero $c = \frac{1}{2}$ $c=1/2$ and the function $f (x) = 4 x^{4} - 28 x^{3} + 61 x^{2} - 42 x + 9$ $f(x)=4x^4-28x^3+61x^2-42x+9$ ?