Determine the completely factored form of $f (x) = 12 x^{3} - 44 x^{2} + 49 x - 15$ $f(x) = 12x^3 - 44x^2 + 49x - 15$ ?

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Determine the completely factored form of $f (x) = 12 x^{3} - 44 x^{2} + 49 x - 15$ $f(x) = 12x^3 - 44x^2 + 49x - 15$ ?

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Answer 1 · 2016-10-21T23:03:02

$12 x^{3} - 44 x^{2} + 49 x - 15 = (2 x - 3) (3 x - 5) (2 x - 1)$ $12x^3-44x^2+49x-15 = (2x-3)(3x-5)(2x-1)$

Explanation:

$f (x) = 12 x^{3} - 44 x^{2} + 49 x - 15$ $f(x) = 12x^3-44x^2+49x-15$

By the rational roots theorem, any rational zero of $f (x)$ $f(x)$ is expressible in the form $\frac{p}{q}$ $p/q$ for integers $p, q$ $p, q$ with $p$ $p$ a divisor of the constant term $- 15$ $-15$ and $q$ $q$ a divisor of the coefficient $12$ $12$ of the leading term.

In addition, note that the pattern of signs of coefficients of $f (x)$ $f(x)$ is $+ - + -$ $+ - + -$ with $3$ $3$ sign changes, while those of $f (- x)$ $f(-x)$ are in the pattern $- - - -$ $- - - -$ with $0$ $0$ sign changes. So by Descartes' Rule of Signs, $f (x)$ $f(x)$ has $3$ $3$ or $1$ $1$ positive Real zero and no negative Real zeros.

Hence the only possible rational zeros are:

$\frac{1}{12}, \frac{1}{6}, \frac{1}{4}, \frac{1}{3}, \frac{5}{12}, \frac{1}{2}, \frac{3}{4}, \frac{5}{6}, 1, \frac{5}{4}, \frac{3}{2}, \frac{5}{3}, \frac{5}{2}, 3, 5, 15$ $1/12, 1/6, 1/4, 1/3, 5/12, 1/2, 3/4, 5/6, 1, 5/4, 3/2, 5/3, 5/2, 3, 5, 15$

We could simply try each of these in turn, but if you are allowed, we can speed up the process of finding the zeros as follows:

Look at the derivative and find out where it is $0$ $0$ , indicating a local maximum or minimum...

$f'(x) = 36x^2-88x+49$

$color(white)(f'(x)) = (6x-22/3)^2-484/9+49$

$color(white)(f'(x)) = (6x-22/3)^2-(sqrt(43)/3)^2$

$color(white)(f'(x)) = (6x-22/3-sqrt(43)/3)(6x-22/3+sqrt(43)/3)$

Hence zero at $x = 1/6(22/3+-sqrt(43)/3) = 1/18(22+-sqrt(43))$

$sqrt(43) ~~ 6.5$

So the local maximum and minimum are approximately at:

$1/18(22-6.5) = 31/36 ~~ 5/6$ and $1/18(22+6.5) = 19/12 ~~ 3/2$

$f(5/6) = 20/9$

$f(3/2) = 0$

Hmmm - a zero near where we expect the minimum. Let's look at the other rational possibility nearby...

$f(5/3) = 0$

So $x=3/2$ and $x=5/3$ are zeros with corresponding factors $(2x-3)$ and $(3x-5)$ .

Looking at the coefficient of the leading term and constant term, the remaining factor (which must be rational) must be $(2x-1)$

So:

$12x^3-44x^2+49x-15 = (2x-3)(3x-5)(2x-1)$

graph{12x^3-44x^2+49x-15 [-0.448, 2.052, -1.26, 2.49]}

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Determine the completely factored form of $f (x) = 12 x^{3} - 44 x^{2} + 49 x - 15$ $f(x) = 12x^3 - 44x^2 + 49x - 15$ ?

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Explanation:

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Determine the completely factored form of f(x) = 12x^3 - 44x^2 + 49x - 15f(x)=12x3−44x2+49x−15f(x) = 12x^3 - 44x^2 + 49x - 15?

1 Answer

Explanation:

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Determine the completely factored form of $f (x) = 12 x^{3} - 44 x^{2} + 49 x - 15$ $f(x) = 12x^3 - 44x^2 + 49x - 15$ ?