All Calculus AB Resources
Example Questions
Example Question #3 : Determine Increasing/Decreasing Intervals
We know that a function has a critical point at and the function is increasing on the interval and decreasing on the interval . Is the critical point a local maximum?
Yes
There is not enough information
No
Yes
When a critical point’s interval to the left of the point is increasing and the interval to the right of the point is decreasing, this means that the critical point is at least a local maximum. It could be a global maximum but we do not have enough information to determine this so we will say it is definitely a local maximum.
Example Question #8 : Determine Increasing/Decreasing Intervals
For the function , which intervals are increasing and which intervals are decreasing?
Increasing: , , Decreasing:
Decreasing: , , Increasing:
Increasing: , Decreasing: ,
Decreasing: , Increasing: ,
Increasing: , , Decreasing:
We begin by finding the critical point(s).
First we will consider the point . We will choose the point for the point less than the critical point and the point for the point less than the critical point.
So the function is decreasing on the interval and increasing on the interval .
Now we will consider the point . We already know that the function is increasing on the interval , so we only need to consider the interval . We will choose the point .
And so the function is also increasing on the interval .
Example Question #9 : Determine Increasing/Decreasing Intervals
The function is:
Increasing on both intervals
If we take the derivative of the function we have . The critical value of this function is . So if we plug into the derivative function we are left with . If we plug in to the derivative function we are left with . So both intervals give us positive solutions and so both intervals are increasing. This makes our critical point a point of inflection.
Example Question #1 : Determine Increasing/Decreasing Intervals
What is a critical value?
The point at which the derivative is equal to zero
A local min or max
A point of inflection
All of the above
All of the above
A point of inflection can be the point at which the derivative is equal to zero, a local minimum or maximum, and a point of inflection. A critical point will always be one that the tangent line to the original function is either completely horizontal or vertical. When the tangent line is completely horizontal, this will be a local maximum or minimum for the function. When the tangent line is completely vertical, then this will be a point of inflection. A point of inflection is a point in which there is a change of curvature in the graph of the function.
Example Question #14 : Analytical Applications Of Derivatives
What is the first derivative test in regards to increasing/decreasing intervals?
You choose a number greater than the critical value. You plug this number into the derivative and if the solution is positive then the function is increasing, but if the solution is negative then the function is decreasing.
You choose a number less than the critical value. You plug this number into the derivative and if the solution is positive then the function is increasing, but if the solution is negative then the function is decreasing.
If the critical value is positive, the function is increasing. If the critical value is negative, the function is decreasing.
You choose a number less than, and a number greater than the critical value. You plug these numbers into the derivative and if the solutions are positive, then the function is increasing but if the solutions are negative then the function is decreasing.
You choose a number less than, and a number greater than the critical value. You plug these numbers into the derivative and if the solutions are positive, then the function is increasing but if the solutions are negative then the function is decreasing.
To find whether a function is decreasing or increasing along an interval, we look at the critical values and use what we call the first derivative test. Take the example . The derivative would be . To find the critical value we set the derivative equal to zero and solve for .
Now we have our critical point . So we choose a number greater than this and plug it back into our derivative function.
The solution is positive. This means that the interval on the graph of
,
The solution is decreasing. This means that the interval is decreasing on the graph of .
Example Question #31 : Analytical Applications Of Derivatives
Find the critical value(s) for the function .
We begin by finding the derivative of our function, .
Now we set our derivative function equal to zero and solve for .
And we are left with two critical points
Example Question #3 : Determine Increasing/Decreasing Intervals
Find the critical point(s) of the function and determine which interval(s) are decreasing or increasing.
Critical point , increasing: , decreasing: .
Critical point , increasing: , decreasing: .
Critical point , increasing: , decreasing: .
Critical point , increasing: , decreasing: .
Critical point , increasing: , decreasing: .
Critical point , increasing: , decreasing: .
Explanation: We first have to find the critical point(s). To do this we begin by finding the derivative.
Now to find the critical point(s), we set the derivative equal to zero and solve for .
And so our critical point is . Now we will choose a number greater than to plug back into our derivative. We will arbitrarily choose the number .
.
The solution is positive, so we know that on the interval our function is increasing. Now we must choose a number less than to plug back into our derivative. We will arbitrarily choose .
The solution is negative. So we know that on the interval our function is decreasing.
Example Question #4 : Determine Increasing/Decreasing Intervals
Which intervals is the function increasing on?
We begin by finding the derivative of the function.
Now we must find the critical points of the function
So we need to look at the intervals , , , and . We will begin with the interval . We will arbitrarily choose to plug back into our derivative function.
The solution is negative, so the interval is decreasing. Now we will look at the interval . We need to choose a number between and . We will choose .
The solution is negative. So from the interval , the function is increasing. Now we will look at the interval . We will choose the number to plug back into our equation.
The solution is negative, so the interval is decreasing. Now we will look at the interval . We will choose the number to plug back into our derivative function.
The solution is positive. So the interval is increasing.
The increasing intervals are and
Example Question #2 : Determine Increasing/Decreasing Intervals
True or False: If a function has a critical point, then it must be increasing on one interval and decreasing on the other. It cannot be completely increasing or completely decreasing.
True
False
False
Think back to the types of critical values that we can have. We can have a maximum or a minimum; if we have one of these then the intervals will change from increasing to decreasing or vice versa. Or we will have an inflection point. An inflection point is a change in curvature of the function. So if the critical point is an inflection point, then the function can be completely increasing or completely decreasing.
Example Question #6 : Determine Increasing/Decreasing Intervals
True or False: The function is increasing on the interval .
False
True
True
Begin by finding the derivative.
Now find the critical point of the function.
Now we will plug a number that is greater than into the derivative function. We will arbitrarily choose the number .
The solution is positive, so the interval is increasing.