Derivatives - Pre-Calculus

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Find the second derivative of the following equation:

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To solve, simply realize a constant derived is always 0. Thus, the answer is 0.

What is the first derivative of

with regards to ?

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Since we take the derivative with respect to we only apply power rule to terms that contain . Since all the terms contain , we treat as a constant.

The derivative of a constant is always .

So the derivative of

is zero.

Find the x-coordinates of all points of inflection of the function .

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We set the second derivative of the function equal to zero to find the x-coordinates of any points of inflection.

$0\neq 6$

, and the quadratic formula yields

$x=-$\frac{1}{2}$\pm$\frac{\sqrt{3}$}{2}$ .

Determine the location of the points of inflection for the following function:

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The points of inflection of a function are the points at which its concavity changes. The concavity of a function is described by its second derivative, which will be equal to zero at the inflection points, so we'll start by finding the first derivative of the function:

Next we'll take the derivative one more time to get the second derivative of the original function:

Now that we have the second derivative of the function, we can set it equal to 0 and solve for the points of inflection:

Which of the following is an -coordinate of an inflection point of the graph of the following function?

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The inflection points of a function are the points where the concavity changes, either from opening upwards to opening downwards or vice versa. The inflection points occur at the x-values where the second derivative is either zero or undefined. That means we need to find our second derivative.

We start by using the Power Rule to find the first derivative.

Taking the derivative once more gives the second derivative.

We then set this derivative equal to zero and solve.

This factors nicely.

Therefore our second derivative is zero when

8 is the only one of these two amongst our choices and is therefore our answer.

Determine the points of inflection of the following function:

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The points of inflection of a function are those at which its second derivative is equal to 0. First we find the second derivative of the function, then we set it equal to 0 and solve for the inflection points:

Find the inflection points of the following function:

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The points of inflection of a function are those at which its second derivative is equal to 0. First we find the second derivative of the function, then we set it equal to 0 and solve for the inflection points:

Find the points of inflection of the following function:

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The points of inflection of a function are those at which its second derivative is equal to 0. First we find the second derivative of the function, then we set it equal to 0 and solve for the inflection points:

Determine the points of inflection, if any, of the following function:

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The points of inflection of a function are those at which its concavity changes. The concavity of a function is described by its second derivative, and when the second derivative is 0 a point of inflection occurs. We find the second derivative of the function and then set it equal to 0 to solve for the inflection points:

$6x-10=0\rightarrow 6x=10\rightarrow x=\frac{5}{3}$$

So the function has only one point of inflection at x=5/3.

Determine the x-coordinate of the inflection point of the function .

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The point of inflection exists where the second derivative is zero.

, and we set this equal to zero.

$x=\frac{8}{6}$=\frac{4}{3}$$

Find the point of inflection of the function .

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To find the x-coordinate of the point of inflection, we set the second derivative of the function equal to zero.

$x=\frac{6}{12}$=\frac{1}{2}$$ .

To find the y-coordinate of the point, we plug the x-coordinate back into the original function.

$y=2\left($\frac{1}{8}\right)-3\left($\frac{1}{4}\right)+4$

$y=\frac{7}{2}$$

The point is then $\left($\frac{1}{2}$,$\frac{7}{2}\right)$ .

List the intervals and determine where the graph of is concave up and concave down.

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We need to set the second derivative equal to zero to determine where the inflection points are.

$x=-2,$\frac{3}{2}$$ are the x-coordinates of our inflection points. Thus the intervals of concavity are $(-\infty,-2)$ , $\left(-2,$\frac{3}{2}\right)$ , and $\left($\frac{3}{2}$,\infty\right)$ . We can use as our test points.

, so the graph is concave up on $(-\infty,-2)$ .

, so the graph is concave down on $\left(-2,$\frac{3}{2}\right)$ .

, so the graph is concave up on $\left($\frac{3}{2}$,\infty\right)$ .

Determine the point(s) of inflection of $y=\frac{1}{x+4}$$ .

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The points of inflection exist where the second derivative is zero.

$y=\frac{1}{x+4}$$

which can never be . Therefore, there are no points of inflection.

Determine the x-coordinate(s) of the point(s) of inflection of the function .

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Any points of inflection that exist will be found where the second derivative is equal to zero.

.

Since $0\neq2$ , we can focus on . Thus

, and .

Find the point(s) of inflection of $y=(x+3)^$\frac{2}{3}$$ .

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The points of inflection will exist where the second derivative is zero.

$y=(x+3)^$\frac{2}{3}$$

$y'=\frac{2}{3}$(x+3)^$\frac{-1}{3}$$

$y''=-$\frac{2}{3}$(x+3)^$\frac{-4}{3}$$

$0=-$\frac{2}{3}$(x+3)^$\frac{-4}{3}$$

.

This will never be , so there are no points of inflection.

List the interval(s) where the function is concave up.

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The graph is concave up where the second derivative is positive. Let us first find out if there are any points of inflection to narrow our search.

$x=\frac{2}{3}$$ .

Now we can perform the second derivative concavity test on points on either side of $x=\frac{2}{3}$$ . Let us try .

The second derivative at gives us which is less than zero, so the graph is concave down in this interval. The second derivative at gives us , which is positive. Hence, the graph is concave up on the interval $\left($\frac{2}{3}$,\infty\right)$ .

Find the x-coordinate(s) of the point(s) of inflection of .

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The points of inflection will only exist where the second derivative is zero.

Now $0\neq2$ therefore, there are no points of inflection.

Find the inflection point(s) of .

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The points of inflection, if any exist, will be found where the second derivative is zero.

.

To find the y-coordinates, we simply plug the x-coordinates in to the original function.

.

So $(-1,$\frac{1}{4}$)$ is an inflection point.

Also, , so is another inflection point.

Find the x-coordinate(s) of the point(s) of inflection of .

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The inflection points, if they exist, will occur where the second derivative is zero.

$x=\pm1$

Find the point(s) of inflection of the function .

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The point of inflection will exist where the second derivative equals zero.

.

Now we need the y-coordinate of the point.

Thus the inflection point is at .