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Let's now do another triple integral, and in this one I
won't actually evaluate the triple integral.
But what we'll do is we'll define the triple integral.
We're going to something similar that we did in the
second video where we figured out the mass
using a density function.
But what I want to do in this video is show you how to set
the boundaries when the figure is a little
bit more complicated.
And if we have time we'll try to do it where we change
the order of integration.
So let's say I have the surface -- let me just make something
up -- 2x plus 3z plus y is equal to 6.
Let's draw that surface.
It looks something like this.
This will be my x-axis.
This is going to be my z-axis.
This is going to be my y-axis.
Draw them out.
x, y and z.
And I care about the surface in the kind of positive octant,
right, because when you're dealing with three-dimensionals
we have, instead of four quadrants we have
eight octants.
But we want the octant where all x, y and z is positive,
which is the one I drew here.
So let's see, let me draw some -- what is the x-intercept?
When y and z are 0, so we'll write here,
that's the x-intercept.
2x is equal to 6, so x is equal to 3.
So 1, 2, 3.
So that's the x-intercept.
The y-intercept when x and z are 0 are on the y-axis,
so y will be equal to 6.
so we have 1, 2, 3, 4, 5, 6 is the y-intercept.
Then finally the z-intercept when x and y are 0
we're on the z-axis.
3z will be equal to 6.
So z is equal to 1, 2.
So the figure that I care about will look something like
this -- it's be this inclined surface.
It will look something like that.
In this positive octant.
So this is the surface defined by this function.
Let's say that I care about the volume, and I'm going
to make it a little bit more complicated.
We could say oh, well this was a volume between the
surface and the xy plane.
But I'm going to make it a little bit more complicated.
Let's say the volume above this surface, and the
surface z is equal to 2.
So the volume we care about is going to look
something like this.
Let me see if I can pull off drawing this.
If we go up 2 here -- let me draw the top in a different
color, let me draw the top in green.
So this is along the zy plane.
And then the other edge is going to look
something like this.
Let me make sure I can draw it -- this is the hardest part.
We'll go up 2 here, and this is along the zx plane.
And we'd have another line connecting these two.
So this green triangle, this is part of the
plane z is equal to 2.
The volume we care about is the volume between this top green
plane and this tilted plane defined by 2x plus 3z
plus y is equal to 6.
So this area in between.
Let me see if I can make it a little bit clearer.
Because the visualization, as I say, is often the hardest part.
So we'd have kind of a front wall here, and then the back
wall would be this wall back here, and then there'd
be another wall here.
And then the base of it, the base I'll do in magenta
will be this plane.
So the base is that plane -- that's the bottom part.
Anyway, I don't know if I should have made it that messy
because we're going to have to draw dv's and d volumes on it.
But anyway, let's try our best.
So, if we're going to figure out the volume -- and actually,
since we're doing a triple integral and we want to show
that we have to do the triple integral, instead of doing a
volume, let's do the mass of something of variable density.
So let's say the density in this volume that we care about,
the density function is a function of x, y and z.
It can be anything.
That's not the point of what I'm trying to teach here.
But I'll just define something.
Let's say it's x squared yz.
Our focus is really just to set up the integrals.
So the first thing I like to do is I visualize -- what we're
going to do is we're going to set up a little cube in the
volume under consideration.
So if I had a -- let me do it in a bold color so that you can
see it -- so if I have a cube -- maybe I'll do it in brown,
it's not as bold but it's different enough from
the other colors.
So if I had a little cube here in the volume under
consideration, that's a little cube -- you consider that dv.
The volume of that cube is kind of a volume differential.
And that is equal to dx -- no, sorry, this is dy.
Let me do this in yellow, or green even better.
So dy, which is this.
dy times dx, dx times dz.
That's the volume of that little cube.
And if we wanted to know the mass of that cube, we would
multiply the density function at that point times this dv.
So the mass, you could call it d -- I don't know, dm.
The mass differential is going to be equal to that times that.
So x squared y z times this.
dy, dx, and dz.
And we normally switch this order around, depending on what
we're going to integrate with respect to first so we
don't get confused.
So let's try to do this.
Let's try to set up this integral.
So let's do it traditionally.
The last couple of triple integrals we did we integrated
with respect to z first.
So let's do that.
So we're going to integrate with respect to z first. so
we're going to take this cube and we're going to sum up all
of the cubes in the z-axis.
So going up and down first, right?
So if we do that, what is the bottom boundary?
So when you sum up up and down, these cubes are going to
turn to columns, right?
So what is the bottom of the column, the bottom bound?
What's the surface?
It's the surface defined right here.
So, if we want that bottom bound defined in terms of
z, we just have to solve this in terms of z.
So let's subtract.
So what do we get.
If we want this defined in terms of z, we get 3z is
equal to 6 minus 2x minus y.
Or z is equal 2 minus 2/3x minus y over 3.
This is the same thing as that.
But when we're talking about z, explicitly defining a
z, this is how we get it, algebraically manipulated.
So the bottom boundary -- and you can visualize it, right?
The bottom of these columns are going to go up and down.
We're going to add up all the columns in up and
down direction, right?
You can imagine summing them.
The bottom boundary is going to be this surface.
z is equal to 2 minus 2/3x minus y over 3.
And then what's the upper bound?
Well, the top of the column is going to be this green
plane, and what did we say the green plane was?
It was z is equal to 2.
That's this plane, this surface right here.
Z is equal to 2.
And, of course, what is the volume of that column?
Well, it's going to be the density function, x squared yz
times the volume differential, but we're integrating
with respect to z first.
Let me write dz there.
I don't know, let's say we want to integrate with respect to --
I don't know, we want to integrate with respect
to x for next.
In the last couple of videos, I integrated
with respect to y next.
So let's do x just to show you it really doesn't matter.
So we're going to integrate with respect to x.
So, now we have these columns, right?
When we integrate with respect to z, we get the volume of each
of these columns wher the top boundary is that plane.
Let's see if I can draw it decently.
The top boundary is that plane.
The bottom boundary is this surface.
Now we want to integrate with respect to x.
So we're going to add up all of the dx's.
So what is the bottom boundary for the x's?
Well, this surface is defined all the way to -- the volume
under question is defined all the way until x is equal to 0.
And if you get confused, and it's not that difficult to get
confused when you're imagining these three-dimensional things,
say you know what, we already integrated with respect to z.
The two variables I have left are x and y.
Let me draw the projection of our volume onto the xy plane,
and what does that look like?
So I will do that.
Because that actually does help simplify things.
So if we twist it, if we take this y and flip it out like
that, and x like that we'll get in kind of the traditional way
that we learned when we first learned algebra.
The xy-axis.
So this is x, this is y.
And this point is what?
Or this point?
What is that?
That's x is equal to 3.
So it's 1, 2, 3.
That's x is equal to 3.
And this point right here is y is equal to 6.
So 1, 2, 3, 4, 5, 6.
So on the xy-axis, kind of the domain -- you can view it that
-- looks something like that.
So one way to think about it is we've figured out if these
columns -- we've integrated up/down or along the z-axis.
But when you view it looking straight down onto it, you're
looking on the xy plane, each of our columns are going to
look like this where the column's going to pop out out
of your screen in the z direction.
But the base of each column is going to dx like that, and
then dy up and down, right?
So we decided to integrate with respect to x next.
So we're going to add up each of those columns in the
x direction, in the horizontal direction.
So the question was what is the bottom boundary?
What is the lower bound in the x direction?
Well, it's x is equal to 0.
If there was a line here, then it would be that line probably
as a function of y, or definitely as a function of y.
So our bottom bound here is x is equal to 0.
What's our top bound?
I realize I'm already pushing.
Well, our top bound is this relation, but it has to
be in terms of x, right?
So what is this relation.
So, you could view it as kind of saying well, if z is equal
to 0, what is this line?
What is this line right here?
So z is equal to 0.
We have 2x plus y is equal to 6.
We want the relationship in terms of x.
So we get 2x is equal to 6 minus y where x is equal
to 3 minus y over 2.
And then finally we're going to integrate with respect to y.
And this is the easy part.
So we've integrated up and down to get a column.
These are the bases of the column, so we've integrated
in the x direction.
Now we just have to go up and down with respect to y, or in
the xy plane with respect to y.
So what is the y bottom boundary?
Well, it's 0.
y is equal to 0.
And the top boundary is y is equal to 6.
And there you have it.
We have set up the integral and now it's just a matter
of chugging through it mechanically.
But I've run out of time and I don't want this
video to get rejected.
So I'll leave you there.
See you in the next video.