Tip:
Highlight text to annotate it
X
So we have got a very interesting scenario here.
I have this conical thimble-like cup that is 4 centimeters high.
And also, the diameter of the top of the cup
is also 4 centimeters.
And I'm pouring water into this cup right now.
And I'm pouring the water at a rate of 1 cubic centimeter.
1 cubic centimeter per second.
And right at this moment, there is a height
of 2 centimeters of water in the cup right now.
So the height right now from the bottom of the cup to this point
right over here is 2 centimeters.
So my question to you is, at what rate--
we know the rate at which the water is flowing into the cup,
we're being given a volume per time.
My question to you is right at this moment,
right when we are filling our cup
at 1 cubic centimeter per second.
And we have exactly 2 centimeters
of water in the cup, 2 centimeters deep
of water in the cup, what is the rate at which
the height of the water is changing?
What is the rate at which this height right over here
is actually changing?
We know it's 2 centimeters, but how fast is it changing?
Well let's think about this a little bit.
What are we being given?
We're given-- we are being given the rate at which
the volume of the water is changing with respect to time.
So let's write that down.
We are being given the rate at which the volume of the water
is changing with respect to time,
and we're told that this is 1 cubic centimeter per second.
And what are we trying to figure out?
Well we're trying to figure out how fast
the height of the water is changing with respect to time.
We know that the height right now is 2 centimeters.
But what we want to figure out is the rate
at which the height is changing with respect to time.
If we can figure out this, then we
have essentially answered the question.
So one way that we can do this is we
can come up with the relationship between the volume
at any moment in time and the height at any moment in time.
And then maybe take the derivative
of that relationship, possibly using the chain rule,
to come up with a relationship between the rate at which
the volume is changing and the rate at which the height is
changing.
So let's try to do it step by step.
So first of all, can we come up with a relationship
between the volume and the height at any given moment?
Well we have also been given the formula
for the volume of a cone right over here.
The volume of a cone is 1/3 times the area
of the base of the cone, times the height.
And we won't prove it here, although we
could prove it later on.
Especially when we start doing solids of revolutions
within in integral calculus.
But we'll just take it on faith right now,
that this is how we can figure out the volume of a cone.
So given this can we figure out volume--
can we figure out an expression that relates volume
to the height of the cone?
Well we could say that volume-- and I'll
do it in this blue color-- the volume of water
is what we really care about.
The volume of water is going to be
equal to 1/3 times the area of the surface of the water--
area of water surface-- times our height of the water.
So times h.
So how can we figure out the area of the water surface,
preferably in terms of h?
Well we see right over here, the diameter
across the top of the cone is 4 centimeters.
And the height of the whole cup is 4 centimeters.
And so that ratio is going to be true of any--
at any depth of water.
It's always going to have the same ratio between the diameter
across the top and the height.
Because these are lines right over here.
So at any given point, the ratio between this and this
is going to be the same.
So at any given point, the diameter
across the surface of the water-- if the depth is h,
the diameter across the surface of the water
is also going to be h.
And so from that we can figure out
what are the radius is going to be.
The radius is going to be h over 2.
And so the area of the water surface
is going to be pi r squared, pi times the radius squared.
h over 2 squared.
That's the area of the surface of the water.
And of course we still have the 1/3 out here.
And we're still multiplying by this h over here.
So let me see if I can simplify this.
So this gives us 1/3 times pi h squared over 4 times another h,
which is equal to-- we have pi, h to the third power over 12.
So that is our volume.
Now what we want to do is relate the volume, how fast the volume
is changing with respect to time,
and how fast the height is changing with respect to time.
So we care with respect to time, since we care so much
about what's happening with respect to time,
let's take the derivative of both sides of this equation
with respect to time.
To do that, and just so I have enough space to do that,
let me move this over.
Let me move this over to the right a little bit.
So I just move this over to the right.
And so now we can take the derivative with respect
to time of both sides of this business.
So the derivative with respect to time of our volume
and the derivative with respect to time of this business.
Well the derivative with respect to time of our volume,
we could just rewrite that as dV dt, this thing right over here.
This is dV dt, and this is going to be
equal to-- well we could take the constants out
of this-- this is going to be equal to pi over
12 times the derivative with respect to t of h, of h
to the third power.
And just so that the next few things I do
will appear a little bit clearer,
we're assuming that height is a function of time.
In fact, it's definitely a function of time.
As time goes on, the height will change.
Because we're pouring more and more water here.
So instead of just writing h to the third power, which
I could write over here, let me write h of t
to the third power.
Just to make it clear that this is a function of t.
h of t to the third power.
Now what is the derivative with respect to t,
of h of t to the third power.
Now, you might be getting a tingling feeling
that the chain rule might be applicable here.
So let's think about the chain rule.
The chain rule tells us-- let me rewrite everything else.
dV with respect to t, is going to be equal to pi over 12,
times the derivative of this with respect to t.
If we want to take the derivative of this with respect
to t, we have something to the third power.
So we want to take the derivative of something
to the third power with respect to something.
So that's going to be-- let me write
this in a different color, maybe in orange-- so that's
going to be 3 times our something squared,
times the derivative of that something, with respect to t.
Times dh-- I've already used that pink-- times dh dt.
Let's just be very clear.
This orange term right over here-- and I'm
just using the chain rule-- this is the derivative of h of t
to the third power with respect to h of t.
And then we're going to multiply that times the derivative of h
of t with respect to t.
And then that gives us the derivative
of this entire thing, h of t to the third power, with respect
to t.
This will give us the derivative of h
of t to the third power with respect to d with respect
to t, which is exactly what we want
to do when we apply this operator.
How fast is this changing?
How is this changing with respect to time?
So we can just rewrite this, just
so gets a little bit cleaner.
Let me rewrite everything I've done.
So we've got dV, the rate at which our volume is
changing with respect to time.
The rate at which our volume is changing with respect to time
is equal to pi over 12 times 3 h of t squared,
or I could just write that as 3h squared,
times the rate at which the height is changing
with respect to time, times dh dt.
And you might be a little confused.
You might have been tempted to take the derivative over here
with respect to h.
But remember, we're thinking about how
things are changing with respect to time.
So we're assuming-- we did express volume
as a function of height-- but we're
saying that height itself is a function of time.
So we're taking the derivative of everything
with respect to time.
So that's why the chain rule came into play
when we were taking the derivative of h,
or the derivative of h of t, because we're
assuming that h is a function of time.
Now what does this thing right over here get us?
Well we're telling us at the exact moment
that we set up this problem, we know
what dV dt is, we know that it's 1 centimeter cubed per second.
We know that this right over here
is 1 centimeter cubed per second.
We know what our height is right at this moment.
We were told it is 2 centimeters.
So the only unknown we have over here
is the rate at which our height is
changing with respect to time.
Which is exactly what we needed to figure out
in the first place.
So we just have to solve for that.
So we get 1 cubic centimeter-- let
me make it clear-- we get 1 cubic centimeter per second--
I won't write the units to save some space-- is
equal to pi over 2.
And I'll write this in a neutral color.
Actually, let me write in the same color.
Is equal to pi over 2, times 3, times h squared.
h is 2 so you're going to get 4 squared centimeters if we
kept the units.
So 3 times 4.
All right let me be careful, that wasn't
pi over 2, that was pi over 12.
This is a pi over 12 right over here.
So you get pi over 12, times 3 times 2 squared, times dh dt.
All of this is equal to 1.
So now I'll switch to a neutral color.
We get 1 is equal to, well 3 times 4 is 12,
cancels out with that 12.
We get one is equal to pi times dh dt.
To solve for dh dt divide both sides by pi.
And we get our drum roll now.
The rate at which our height is changing with respect
to time as we're putting 1 cubic centimeter of water per second
in.
And right when our height is 2 centimeters high,
the rate at which this height is changing with respect to time
is 1 over pi.
And I haven't done the dimensional analysis
but this is going to be in centimeters per second.
You can work through the dimensional analysis
if you like by putting in the dimensions right over here.
But there you have it.
That's how fast our height is going
to be changing at exactly that moment.