Difference between revisions of "022 Exam 1 Sample A, Problem 4"

Latest revision as of 21:03, 12 April 2015

Determine the intervals where the function $h(x)=2x^{4}-x^{2}$ is increasing or decreasing.

Foundations:

When a first derivative is positive, the function is increasing (heading uphill). When the first derivative is negative, it is decreasing (heading downhill). When the first derivative is

0,

it is not quite so clear. If

f'(z)=0

at a point

z

, and the first derivative splits around it (either

f'(x)<0

for

x<z

and

f'(x)>0

for

x>z

, or

f'(x)>0

for

x<z

and

f'(x)<0

for

x>z

), then the point

(z,f(z))

is a local maximum or minimum, respectively, and is neither increasing or decreasing at that point.

On the other hand, if the first derivative does not split around

z

, then it will be increasing or decreasing at that point based on the derivative of the adjacent intervals. For example,

g(x)=x^{3}

has the derivative

g'(x)=3x^{2}

. Thus,

g'(0)=0

, but is strictly positive everywhere else. As a result,

g(x)=x^{3}

is increasing on

(-\infty ,\infty )

.

Solution:

Find the Roots of the First Derivative:
Note that
$h'(x)\,\,=\,\,8x^{3}-2x\,\,=\,\,2x\left(4x^{2}-1\right)\,\,=\,\,2x(2x+1)(2x-1),$
so the roots of $h'(x)$ are $0$ and $\pm 1/2$ .

Make a Sign Chart and Evaluate:

We need to test convenient numbers on the intervals separated by the roots. Using the form

h'(x)\,\,=\,\,2x(2x+1)(2x-1),

we can test at convenient points to find

f'(-10)=(-)(-)(-)=(-),\quad f'(-1/4)=(-)(+)(-)=(+),

f'(1/4)\,\,=(+)(+)(-)=(-),\quad f'(10)=(+)(+)(+)=(+).

From this, we can build a sign chart:

$x:$	$x<-1/2$	$x=-1/2$	$-1/2<x<0$	$x=0$	$0<x<1/2$	$x=1/2$	$x>1/2$
$f'(x):$	$(-)$	$0$	$(+)$	$0$	$(-)$	$0$	$(+)$

Notice that at each of our roots, the derivative does split (changes sign as

x

passes through each root of

h'(x)

), so the function is neither increasing or decreasing at each root. Thus,

h(x)

is increasing on

(-1/2,0)\cup (1/2,\infty )

, and decreasing on

(-\infty ,-1/2)\cup (0,1/2)

.

Final Answer:
$h(x)$ is increasing on $(-1/2,0)\cup (1/2,\infty )$ , and decreasing on $(-\infty ,-1/2)\cup (0,1/2)$ .

Return to Sample Exam

@@ Line 1: / Line 1: @@
-<span class="exam">[[022_Exam_1_Sample_A,_Problem_4 |<span class="biglink">&nbsp;Problem 4.&nbsp;</span>]] Determine the intervals where the function&thinsp; <math style="vertical-align: -16%">h(x)=2x^{4}-x^{2}</math>
+Determine the intervals where the function&thinsp; <math style="vertical-align: -20%">h(x)=2x^{4}-x^{2}</math>
 is increasing or decreasing.
@@ Line 8: / Line 8: @@
 <br>
 |-
-|On the other hand, if the first derivative does not split around <math style="vertical-align: 0%">z</math>, then it will be increasing or decreasing at that point based on the derivative of the adjacent intervals.  For example, <math style="vertical-align: -25%">g(x)=x^3</math> has the derivative <math style="vertical-align: -20%">g'(x)=3x^2</math>.  Thus, <math style="vertical-align: -25%">g'(0)=0</math>, but is strictly positive every else.  As a result, <math style="vertical-align: -20%">g(x)=x^3</math>&thinsp; is increasing on <math style="vertical-align: -20%">(-\infty,\infty)</math>.
+|On the other hand, if the first derivative does not split around <math style="vertical-align: 0%">z</math>, then it will be increasing or decreasing at that point based on the derivative of the adjacent intervals.  For example, <math style="vertical-align: -25%">g(x)=x^3</math> has the derivative <math style="vertical-align: -20%">g'(x)=3x^2</math>.  Thus, <math style="vertical-align: -25%">g'(0)=0</math>, but is strictly positive everywhere else.  As a result, <math style="vertical-align: -20%">g(x)=x^3</math>&thinsp; is increasing on <math style="vertical-align: -20%">(-\infty,\infty)</math>.
 |}

Difference between revisions of "022 Exam 1 Sample A, Problem 4"

Latest revision as of 21:03, 12 April 2015

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