Absolute maximum and minimum calculator on interval

What is Absolute Extrema?

It refers to the most extensive and smallest values of a function. For instance, the highest profit a company can make, the least quantity of cement needed to complete a building, and much more. Knowing how to find absolute extrema of a function is a daunting task to many students. In order to make the process easier for you, we've prepared this calculator - feel free to use it online.

How To Use The Absolute Extrema Calculator

Finding the absolute extrema is very easy with our calculator. All you need to do is to:

• Identify the critical numbers, and
• Enter them into the function on the calculator
• As simple as that, and you have your answer!

However, are you aware that there is a way to find absolute extrema without a calculator?

So first, let us look at some of the comparisons of absolute extrema.

Local vs. Absolute Extrema

An absolute maximum occurs at the x value where the function is the biggest. In contrast, a local maximum occurs at an x value if the function is more prominent than points around it (i.e., an open interval around it).

A local minimum occurs at an x value if the function is smaller than the points around it. In contrast, an absolute minimum occurs at the x value where the function is the smallest (i.e., an open interval around it).

Absolute vs. Relative Extrema

The absolute extrema will refer to the absolute minimums and maximums, while the relative extrema will refer to the relative minimums and maximums. Note that relative extrema do not occur at the endpoints of a domain. Unlike the absolute extrema, they only occur interior to the domain.

Formula For Absolute Extrema Calculator With Interval

For absolute extrema, we should first have a continuous function, f(x), on an interval [a, b]. Therefore, using the function, we can be able to find the absolute extrema in the following steps:

• First, verify that the function is continuous
• Then find all the critical points of f(x) that are in the interval [a, b] 
• Evaluate the function at the critical points derived from step 2 and the endpoints
• Finally, identify the absolute extrema

You can see that the procedure above does not take much professional writing help. Provided you have the critical points and evaluate them, finding the absolute extrema becomes easy-peasy. 

Now, there are other ways of finding the absolute extrema:

How To Find the Absolute Extrema of the Function on the Closed Interval Calculator

Using this method requires you to compute a derivative. Below is how to go about this process:

• Identify all critical numbers of f within the interval i.e. f'(x) = 0,
• Solve for x 
• Consider only those solutions of x that satisfy a ≤ x ≤ b.
• Enter the values into the function f(x).
• Enter the endpoints, a and b, into the function f(x).

The immense value becomes the absolute maximum from the results you get, while the smallest value becomes the absolute minimum. You can use the absolute extrema calculator on interval to arrive at your answer.

How To Find Absolute Extrema on a Graphing

Once you’ve found all the critical numbers of f within the interval [a, b], you can move on to plug the values on your graph paper. Draw the graph to arrive at your absolute minimum and maximum points. 

Example:

Find the absolute extrema for:

g (t)=2t3+3t2−12t+4 on [−4,2]

Solution:

g′ (t) =6t2+6t−12=6(t+2) (t−1)

t = −2 and t = 1

Therefore:

g (-2) = 24

g (-4) = -28

g (1) = -3

g (2) = 8

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Video transcript

Let's say that we've got the function f of x is equal to eight times the natural log of x minus x squared and it is defined over the closed interval between one and four, so it's a closed interval. it also includes one and it includes four. You can view this as the domain of our function as we have defined it. So given this, given this information, this function definition, what I would like you to do is come up with the absolute, absolute maximum value, value of f, of f as defined where f is defined right over here, where f is defined on this closed interval. And I encourage you to pause this video and think about it on your own. So the extreme value theorem tells us, look, we've got some closed interval - I'm going to speak in generalities here - so let's say that's our X axis and let's say we have some function that's defined on a closed interval. We have a couple of different scenarios for what that function might look like on that closed interval. So, we might hit a maximum point, we might hit a maximum point, at the beginning of the interval, something like that. We might hit an absolute maximum point at the end of the interval, so it might look something like this, so that's at the end of the interval. Or, we might hit an absolute maximum point someplace in between and that could look something like this, it could look like this, and at this maximum point, the slope of the tangent line is zero, so here the derivative is zero, or we could have a maximum point someplace in between that looks like this. And if it looks like this, then here the derivative would be undefined. There's a lot of different tangent lines that you could place, that you could place right over there. So, what we need to do is, let's test. Let's test the different endpoints. Let's test the function at the beginning, let's test the function at the end of the interval, and then let's see if there's any points where the derivative is either zero or the derivative is undefined. And these points where the derivative is either zero it is undefined, we've seen them before, we call these, of course, critical numbers. So this would be either, in either case actually, if we assume that that's happening to the same number, we would call that a critical number. Critical - a critical number. So those are the different candidates. Now you could have a critical number in between that, where, say, the slope is zero, say something like this, but it is at the maximum or minimum. But what we can do is, if we can find all the critical numbers, we can then test the affect, the function of the value of the critical numbers and the function of the value at the endpoints and we can see which of those are the largest. All of those are the possible candidates for where f hits a maximum value. So, first we could think about - well actually, let's just, let's find the critical numbers first, since we have to do it. So, let's take the derivative of f. f prime of x is going to be equal to the derivative of the natural log of x is one over x. so it's going to be eight over x minus 2x and let's set that equal to zero. So if we focus on this part right over here, we could add 2x to both sides and we would get eight over x is equal to 2x. Multiply both sides by x, we get eight is equal to 2x squared. Divide both sides by two, you get four is equal to x squared. And if we were just purely solving this equation, we would get x is equal to plus or minus two. Now, we are saying that the function is only defined over this interval, so negative two is a part of its domain, so we are only going to focus on x is equal to two. This right over here is definitely a critical number. Now, have we found all of the critical numbers? Critical numbers. Well, this is the only number other than negative two, the only number in the interval that will make f prime of x equal to zero. What about where it's undefined? Well, f prime of x would be undefined, the only place where it would be undefined is if you stuck a zero right over here in the denominator, but zero is not in the interval, so the only critical number in the interval is x equals two. So, now we just have to test f at the different endpoints and at the critical number and see which of those is the highest. So, we're going to test f of one, f of one, which is equal to eight times the natural log of one minus one squared. We'll test f of four, which is equal to eight times the natural log of four minus four squared, which is, of course, 16, which is 16. And we're going to test f of 2. So these are the endpoints and this is a critical number. Eight times the natural log of two minus two squared. Now, which of these is going to be the largest? And it might be tempting to get a calculator out, but actually let's see if we can get a little intuition here. So this is, the natural log of one is zero, e to the zero power is equal to one. So eight times zero is zero, so this evaluates to negative one. Now, let's see, what does this evaluate to? The natural log of four, e is two point seven, on and on and on, so this number is going to be between one and two so it's going to be between one and two, and it's actually going to be, well, between one and two, you multiply that times eight and you're going to be between eight and 16, and then you subtract 16, so that means you're going to be between zero and negative eight. So, okay, so that, it's not clear, at least not without using a calculator, or this very rough way, which of these is larger. Both of these are negative numbers, though. Now, what about this? The natural log of two. The natural log of two is going to be some fraction. It's going to be more than half, it's going to be more than half, And since it's more than half, this whole thing is going to be more than four, which means this whole thing is going to be positive. So this is negative, this is negative, this is positive. And these are only critical numbers, these are only candidates for our maximum value, so I would go with this one. Our maximum, our maximum value happens when x is equal to two, and that maximum value is eight natural log of two minus four. That is the absolute maximum value, absolute max value over the interval, or I guess we could say over the domain that this function has defined. If we want to verify it with a calculator we, of course, could. So, we already figured out this one, but let's see, f of four, eight natural log of four minus 16 is equal to negative five. So that's, that's, this is definitely not, this one is definitely not the maximum value. And then f of two is eight natural log of two minus four which, as we said, is indeed a positive number. So feel pretty good about what we did.

How do you find the absolute maximum and minimum of an interval?

How do you find absolute extrema on an interval?