All Calculus 1 Resources
Example Questions
Example Question #1 : How To Find Local Maximum Graphing Functions Of Curves
Function gives the velocity of a particle as a function of time.
Which of the following ordered pairs are the coordinates of a critical point of ?
Recall that a function has critcal points where its first derivative is equal to zero or undefined.
So, given , we need to find v'(t)
Where is this function equal to zero? t=0 for one. We can find the others, but we really just need one. Plug in t=0 into our original equation to find the point (0,0) Which is in this case a saddle point.
Example Question #2 : Finding Maximums
At which point does a local maxima appear in the following function?
A local max will occur when the function changes from increasing to decreasing. This means that the derivative of the function will change from positive to negative.
First step is to find the derivative.
Find the critical points (when is or undefined).
Next, find at which of these two values changes from positive to negative. Plug in a value in each of the regions into .
The regions to be tested are ,, and .
A value in the first region, such as , gives a positive number, and a value in the second range gives a negative number, meaning that must be the point where the max occurs.
To find what the coordinate of this point, plug in in to , not , to get .
Example Question #2 : Local Maximum
Tessie kicks a bean bag into the air. Its height at a given time can be given by the following equation:
At what time will the bean bag reach its maximum height?
To find the time at which the bean bag reaches its maximum height, we need to find the time when the velocity of the bean bag is zero.
We can find this by taking the derivative of the height position function with respect to time:
Setting this equal to 0, we can then solve for t:
Example Question #3 : Graphing Functions
Find the local maximum of the function on the interval .
There is no local maximum.
and
To find the local maximum, we must find where the derivative of the function is equal to 0.
Given that the derivative of the function yields using the power rule . We see the derivative is never zero.
However, we are given a closed interval, and so we must proceed to check the endpoints. By graphing the function, we can see that the endpoint is, in fact, a local maximum.
Example Question #2 : Graphing Functions
The postion of a feather in a windstorm is given by the following equation:
Determine when an extrema in the feather's position occurs and state whether it is a local minima or maxima.
The first step into finding when the extrema of a function occurs is to take the derivative and set it equal to zero:
To solve the right side of the equation, we'll need to find its roots. we may either use the quadratic formula:
or see that the equation factors into:
Either way, the only nonnegative root is 2.
To see whether this a local minima or maxima, we'll take the second derivative of our equation and plug in this value of 2:
Since the second derivative is positive, we know that this represents a local minima.
Example Question #1 : Local Maximum
Find the local maximum of the curve .
and
First rewrite :
Use the multiplication rule to take the derivative:
To find the local extrema, set this to 0...
...and solve for ...
*
* Since we divided by , we have to remember that is a valid solution
Therefore, we know that we have two potential local extrema: and .
By plugging these in, we get two potential local extrema: and . Therefore, we know that the slope is positive between and . This means that can't be a local maximum, leaving only as a potential answer.
Next, we can find the slope at . It is:
This is negative, meaning that we go from a positive slope to a negative slope at , making it a local maximum.
Example Question #2 : How To Find Local Maximum Graphing Functions Of Curves
What is the maximum value of the function on the interval ?
First, we need to find the critical points of the function by taking .
This is the derivative of a polynomial, so you can operate term by term.
This gives us,
.
Solving for by factoring, we get
.
This gives us critical values of 0 and . Since we are operating on the interval , we make sure our endpoints are included and exclude critical values outside this interval. Now we know the maximum could either occur at or . As the function is decreasing, we know at the max occurs at and that that value is .
Example Question #3 : How To Find Local Maximum Graphing Functions Of Curves
What type of point is in ?
Hole
Inflection point
Local maximum
Asymptote
Local minimum
Inflection point
Even though the first derivative () is at , there is no max or min because the function is increasing on both sides (derivative is positive on both sides). However, the function is changing its concavity (from negative to positive) at . We can tell because the second derivative () is also at , and it's going from negative to positive. Hole and asymptote are irrelevant. When the second derivative changes signs around a specific point we call this an inflection point. An inflection point describes a point that changes the concavity of a function.
Example Question #3 : Graphing Functions
Given that the equation of a graph is find the value of the local maximum on this graph.
There is no local maximum on this graph.
There is no local maximum on this graph.
To find the critical points of the graph, you first must take the derivative of the equation of the graph and set it equal to zero. To take the derivative of this equation, we must use the power rule,
.
We also must remember that the derivative of an constant is 0. The derivative of the equation for this graph comes out to . Solving for when , you find that . The tricky part now is to find out whether or not this point is a local maximum or a local minimum. In order to figure this out we will find whether or not the slope is increasing towards this point or decreasing. Remember that the derivative of a graph equation gives the slope of the graph at any given point.
Thus when we plug in into the slope equation, we find that the slope has a positive value. This means that the slope is increasing as the graph leaves , meaning that this point is a local minimum, We plug in into the slope equation and find that the slope is negative, confirming that is the local minimum. That means that there is no local maximum on this graph.
Example Question #2 : Local Maximum
Consider the family of curves given by with . If is a local maximum, determine and .
Since a local maximum occurs at , this tells us two pieces of information: the derivative of must be zero at and the point must lie on the graph of this function. Hence we must solve the following two equations:
.
From the first equation we get or .
To find the derivative we apply the quotient rule
.
Solving , we get . Plugging this into the expression for gives .
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