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### Course: Differential Calculus > Unit 5

Lesson 1: Mean value theorem- Mean value theorem
- Mean value theorem example: polynomial
- Mean value theorem example: square root function
- Using the mean value theorem
- Justification with the mean value theorem: table
- Justification with the mean value theorem: equation
- Establishing differentiability for MVT
- Justification with the mean value theorem
- Mean value theorem application
- Mean value theorem review

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# Mean value theorem

The Mean Value Theorem states that if a function f is continuous on the closed interval [a,b] and differentiable on the open interval (a,b), then there exists a point c in the interval (a,b) such that f'(c) is equal to the function's average rate of change over [a,b]. In other words, the graph has a tangent somewhere in (a,b) that is parallel to the secant line over [a,b]. Created by Sal Khan.

## Want to join the conversation?

- I'm having trouble thinking of when a function would be continuous over a closed period, but
**not**differentiable over the same period. Is it just a redundant statement? If not, can anyone provide an example?(50 votes)- The above answer is a good example of a function that is continuous but not differentiable at a point. If you really want to blow your mind, Google the phrase "nowhere differentiable function," and you will see examples of functions that are continuous but not differentiable at ANY point.

The Weierstrass function is perhaps the most famous example... As you might expect, these are very, very weird functions.(98 votes)

- Why aren't endpoints differentiable? Like let (x,f(x)) =endpoint & (x+h,f(x+h)) = some other point. Can't we use limits to figure out the derivative as h->0? Please explain!(20 votes)
- It would seem like we could, but to understand why it's not possible you need to return to the definition of the derivative as a limit.

We define the derivative as follows (also known as the difference quotient):

lim as h->0 of [f(x+h)-f(x)]/h

Notice that the limit is not specified as being left or right sided, so by the definition of the limit, the left sided and right sided limits as h->0 must exist and be equal for the derivative to exist.

Using this knowledge, we can see that although the limit will exist on the left side as we approach the rightmost endpoint, we cannot determine the value of the limit as we approach from the right because those values will not be included in the domain of the function f(x).

In summation: The left sided and right sided limit must exist and be equal for the derivative to exist at a given point, and by nature such two sided limits are not possible if we can only approach a point from one side. Therefore, we cannot take the derivative at the endpoints.(62 votes)

- At5:50Sal says there exists a value c in the OPEN interval (a,b). In this case, why would the interval be open?(10 votes)
- f'(c) must be on the open interval because a function defined on a closed interval is not differentiable at the endpoints because we don't have both a left hand and right hand limit to make sure that the derivative exists per the definition of a derivative. Thus, we cannot differentiate that the endpoints.

Technically speaking, we can do a one-sided limit at each of the closed interval endpoints and get what is called a one-sided derivative. But the MVT is talking about a ordinary derivative, not a one-sided derivative. Thus, x=c must be on the open interval (a,b).

There are other reasons why x=c lies on (a,b) not [a,b].(17 votes)

- How can the Mean Value Theorem be proved by using Rolle's Theorem? (Rolle's Theorem is a special case of the MVT; both f(a) and f(b) are equal to 0.)(5 votes)
- Rolle's theorem states the following: suppose
`ƒ`

is a function continuous on the closed interval`[a, b]`

and that the derivative`ƒ'`

exists on`(a, b)`

. Assume also that`ƒ(a) = ƒ(b)`

. Then there exists a`c`

in`(a, b)`

for which`ƒ'(c) = 0`

.

To prove the Mean Value Theorem using Rolle's theorem, we must construct a function that has equal values at both endpoints. The Mean Value Theorem states the following: suppose`ƒ`

is a function continuous on a closed interval`[a, b]`

and that the derivative`ƒ'`

exists on`(a, b)`

. Then there exists a`c`

in`(a, b)`

for which`ƒ(b) - ƒ(a) = ƒ'(c)(b - a)`

.**Proof**

Construct a new function`ß`

according to the following formula:`ß(x) = [b - a]ƒ(x) - x[ƒ(b) - ƒ(a)].`

Then`ß`

is continuous on`[a, b]`

and the derivative`ß'`

exists on`(a, b)`

(why?). We also have`ß(a) = [b - a]ƒ(a) - a[ƒ(b) - ƒ(a)] = bƒ(a) - aƒ(b),`

`ß(b) = [b - a]ƒ(b) - b[ƒ(b) - ƒ(a)] = bƒ(a) - aƒ(b).`

Since the function`ß`

satisfies the conditions of Rolle's theorem on`[a, b]`

, there exists a`c`

in`(a, b)`

for which`ß'(c) = 0`

. We have`ß'(x) = [b - a]ƒ'(x) - [ƒ(b) - ƒ(a)]`

. Hence`ß'(c) = [b - a]ƒ'(c) - [ƒ(b) - ƒ(a)] = 0`

. This can be written as`ƒ(b) - ƒ(a) = ƒ'(c)(b - a),`

and the proof is complete.(17 votes)

- Is this the same as Average Rate of Change?(3 votes)
- It isn't the same, but uses the idea. MVT basically says that the average change over an interval would be equal to the instantaneous change at atleast one point on that interval.

In other words, if you covered 90 miles in 2 hours, your average speed is 45mph. There was atleast one instance where your speed at an instant was also 45mph.(10 votes)

- Wouldn't the slope of the secant line of f(x)=|x| on the interval [-a,a] be 0? But there are no point where f'(x)=0. Is |x| an exception to the mean value theorem, or am I missing something?(5 votes)
- f(x)=|x| isn't differentiable at x=0 and hence this theorom can't applied on it.

Its not exception, it is just not satisfying the condition to apply itself.(6 votes)

- Isn't there like,a video explaining Rolle's Theorem having exercises and stuff about it?I've come across exercises that require knowledge of both MVT and Rolle's Theorem on my math book.I'm revising differntial and integral calculus for my math exam in 7 days so please if you see this answer.Yes,I've searched and searched for it and can't find it.Even the search shows nothing(which is a bit weird for such a fundamantel theorem in calculus such as Rolle's).(3 votes)
- Rolle's theorem just says if you have a closed interval on the real number line and you graph a function over that closed interval then you have a point where the slope is zero.(5 votes)

- Why is the function in the MVT defined as continuous over a closed interval [a,b]? How does this make sense in relation to the definition of continuity? how would you take the limit of the extremities? Why isn't it open?(5 votes)
- Our average rate of change over the interval from a to b, but what about b to a, I'm so confused.(3 votes)
- Going from 𝑏 to 𝑎 doesn't change the ARC, since

(𝑓(𝑏) − 𝑓(𝑎))∕(𝑏 − 𝑎) = (𝑓(𝑎) − 𝑓(𝑏))∕(𝑎 − 𝑏)(3 votes)

- So the derivative of the function will be equal to the slope of the secant line between the two points at some point in the function?(2 votes)
- You are correct. For a continuous function defined on a closed interval, there is a point on the interior of the interval such that the derivative at that point is the same as the slope of the line connecting the endpoints.(5 votes)

## Video transcript

Let's see if we
can give ourselves an intuitive understanding
of the mean value theorem. And as we'll see, once you parse
some of the mathematical lingo and notation, it's actually
a quite intuitive theorem. And so let's just think
about some function, f. So let's say I have
some function f. And we know a few things
about this function. We know that it is
continuous over the closed interval between x equals
a and x is equal to b. And so when we put
these brackets here, that just means closed interval. So when I put a
bracket here, that means we're including
the point a. And if I put the bracket on
the right hand side instead of a parentheses,
that means that we are including the point b. And continuous
just means we don't have any gaps or jumps in
the function over this closed interval. Now, let's also assume that
it's differentiable over the open interval
between a and b. So now we're saying,
well, it's OK if it's not
differentiable right at a, or if it's not
differentiable right at b. And differentiable
just means that there's a defined derivative,
that you can actually take the derivative
at those points. So it's differentiable over the
open interval between a and b. So those are the
constraints we're going to put on ourselves
for the mean value theorem. And so let's just try
to visualize this thing. So this is my function,
that's the y-axis. And then this right
over here is the x-axis. And I'm going to--
let's see, x-axis, and let me draw my interval. So that's a, and then
this is b right over here. And so let's say our function
looks something like this. Draw an arbitrary
function right over here, let's say my function
looks something like that. So at this point right over
here, the x value is a, and the y value is f(a). At this point right
over here, the x value is b, and the y value,
of course, is f(b). So all the mean
value theorem tells us is if we take the
average rate of change over the interval,
that at some point the instantaneous rate
of change, at least at some point in
this open interval, the instantaneous
change is going to be the same as
the average change. Now what does that
mean, visually? So let's calculate
the average change. The average change between
point a and point b, well, that's going to be the
slope of the secant line. So that's-- so this
is the secant line. So think about its slope. All the mean value
theorem tells us is that at some point
in this interval, the instant slope
of the tangent line is going to be the same as
the slope of the secant line. And we can see, just visually,
it looks like right over here, the slope of the tangent line
is it looks like the same as the slope of the secant line. It also looks like the
case right over here. The slope of the tangent
line is equal to the slope of the secant line. And it makes intuitive sense. At some point, your
instantaneous slope is going to be the same
as the average slope. Now how would we write
that mathematically? Well, let's calculate
the average slope over this interval. Well, the average slope
over this interval, or the average change, the
slope of the secant line, is going to be our change
in y-- our change in y right over here--
over our change in x. Well, what is our change in y? Our change in y is
f(b) minus f(a), and that's going to be
over our change in x. Over b minus b minus a. I'll do that in that red color. So let's just remind ourselves
what's going on here. So this right over here,
this is the graph of y is equal to f(x). We're saying that the
slope of the secant line, or our average rate of change
over the interval from a to b, is our change in y-- that the
Greek letter delta is just shorthand for change in
y-- over our change in x. Which, of course,
is equal to this. And the mean value
theorem tells us that there exists-- so
if we know these two things about the
function, then there exists some x value
in between a and b. So in the open interval between
a and b, there exists some c. There exists some
c, and we could say it's a member of the open
interval between a and b. Or we could say some c
such that a is less than c, which is less than b. So some c in this interval. So some c in between it
where the instantaneous rate of change at that
x value is the same as the average rate of change. So there exists some c
in this open interval where the average
rate of change is equal to the instantaneous
rate of change at that point. That's all it's saying. And as we saw this diagram right
over here, this could be our c. Or this could be our c as well. So nothing really--
it looks, you would say f is continuous over
a, b, differentiable over-- f is continuous over the closed
interval, differentiable over the open interval, and
you see all this notation. You're like, what
is that telling us? All it's saying is at some
point in the interval, the instantaneous
rate of change is going to be the same as
the average rate of change over the whole interval. In the next video,
we'll try to give you a kind of a real life example
about when that make sense.