LINAN CHEN: Hello.
Welcome back to recitation.
I'm sure you are
becoming more and more
familiar with the
determinants of matrices.
In the lecture, we also learned
the geometric interpretation
of the determinant.
The absolute value of the
determinant of a matrix
is simply equal to the volume
of the parallelepiped spanned
by the row vectors
of that matrix.
So today, we're going
to apply this fact
to solve the following problem.
I have a tetrahedron,
T, in this 3D space.
And the vertices of T are given
by O, which is the origin, A_1,
A_2, and A_3.
So I have highlighted
this tetrahedron
using the blue chalk.
So this is T.
And our first goal is to
compute the volume of T
using the determinant.
And the second part is:
if I fix A_1 and A_2,
but move A_3 to another
point, A_3 prime, which
is given by this
coordinate, I ask you
to compute the volume again.
OK.
So since we want to use the fact
that the determinant is related
to the volume, we have to
figure out which volume
we should be looking at.
We know that the
determinant is related
to the volume of
a parallelepiped.
But here, we only
have a tetrahedron.
So the first goal should be to
find out which parallelepiped
you should be working with.
OK, why don't you hit pause and
try to work it out yourself.
You can sketch the
parallelepiped on this picture.
And I will return in a while
and continue working with you.
All right.
How did your computation go?
Now let's complete
this picture together.
As we were saying, we
need a parallelepiped
so that we can use the fact
that the determinant is
related to the volume.
Here, I have a tetrahedron.
And let's look at these three
edges, OA_1, OA_2, and OA_3.
All of them meet at the origin.
So why don't we just consider
the parallelepiped spanned
by those same three edges?
It's a natural choice,
because at least it
shares three edges with T.
OK, now let's move on
to this picture here.
As you can see, I have
drawn this parallelepiped
in red chalk.
So the blue part
is my original T.
And the red part,
let me call it P.
It's the parallelepiped spanned
by edges OA_1, OA_2, and OA_3.
So that's the parallelepiped
that I'm going to work with.
Now the next step is to
relate the volume of T
to the volume of P. OK,
let's recall together
what is the volume
of a tetrahedron.
We note that the
volume of a tetrahedron
is going to be equal to
1/3 of the area of the base
times the height, right?
Of course, you can choose any
side, any face to be the base.
But for convenience, we're going
to choose the triangle OA_1A_2
to be the base of T.
So the volume of T
is going to be equal to 1/3
times the area of triangle
OA_1A_2.
So I use this A to
indicate the area.
Then times the height.
Well, if I choose
this to be my base,
then this A_3 becomes the apex.
Then the height is simply
equal to the distance from A_3
to the triangle OA_1A_2.
Let me use letter h to
denote this quantity.
So that's the height.
And the volume of
T is equal to 1/3
of the product of the area
of the base times the height.
OK, this is the volume of T. Now
let's see what the volume of P
is.
So P is a parallelepiped.
The volume of a
parallelepiped is simply
equal to the area of the
base times its height.
This time, which face would
you choose to be the base?
Well, of course, you would like
to choose this parallelogram
to be the base because it
contains the base of T.
If we do so, so we want to
choose this parallelogram
to be the base, then
what is the area of this?
Well, it clearly contains two
copies of the triangle OA_1A_2.
So the area of the
parallelogram is simply
equal to twice the area
of the triangle OA_1A_2.
Then what is the height of P?
Again, if you choose
this face to be the base,
then A_3 becomes the apex again.
Then the height of
the parallelepiped
is equal to the
distance from A_3
to the base, which is the
same as the distance from A_3
to triangle OA_1A_2.
So here, the height
is also equal to h.
Now you can compare
these two formulae.
You see that volume
of T is simply
equal to 1/6 of
volume of P. That's
the connection
between the volume
of the tetrahedron with the
volume of the parallelepiped.
In order to compute
the volume of T,
we only need to compute
the volume of P.
Now let's compute the volume
of this parallelepiped.
We know that it's related to
the determinant of a matrix.
And the row vectors
of that matrix
are given by these three edges.
So because all of
them start from 0,
we only need the coordinate
of A_1, A_2, and A_3.
So here, volume of P is
equal to the absolute value.
So don't forget the
absolute value sign.
Absolute value of the
determinant of a three
by three matrix.
So we just need to copy the
coordinates of the vertices
down here.
The first one is [2, 2, -1].
These two are too close.
-1.
And A_2 is [1, 3, 0].
A3 is [-1, 1, 4].
The absolute value
of this determinant.
And if you compute this, this
is a three by three matrix.
The determinant should
be easy to compute.
And the result should be 12.
So that's the volume
of P, which means
the volume of the tetrahedron
T is equal to 12 over 6,
which is 2.
Did you get the correct answer?
OK, so in order to
compute the volume of T,
we have related to
a parallelepiped, P,
which contains T. All right.
Now let's look at
the second part.
The second part says that if
I keep A_1 and A_2 unchanged,
but I move A_3 to
a new point-- so A3
is going to be moved to a
point given by A_3 prime,
and the coordinate is
-201, -199, and 104.
And I'm asking you
to compute the volume
of the new tetrahedron.
Well as you can see,
this point seems
to be far away from the origin.
I'm not even able to
draw this point here.
But you can imagine, as
this point goes far away
from the origin,
this spike is going
to become more and more pointy.
In other words, the entire
tetrahedron looks more and more
like a needle.
But nonetheless, we
can use the same method
to compute the volume.
So we follow the same
idea, the volume of T
is going to be equal to
1/6 of the volume of P.
And in this case,
that's going to become
the absolute value of the
determinant of a three
by three matrix
whose row vectors are
given by these three edges.
So in this case, we again
copy down the coordinates
of three vertices.
The first one is [2, 2, -1].
The second one is [1, 3, 0].
The third one should become
this, so [-201, 199, 104].
OK.
That should give me the
volume of the new tetrahedron.
Let me call it T prime
just to differentiate it
from the previous tetrahedron.
And of course, you can compute
this determinant explicitly.
If you do so, you will see
the answer should be 2 again.
But in fact, there is
a way that you can just
read out the answer directly
without any real computation.
Let's pay attention
to the last row.
In other words, let's pay
attention to this new A_3,
well, A_3 prime.
What do you observe here?
A_3 prime, if you consider the
difference between A_3 and A_3
prime, in other words, if you
consider how much you have
moved your apex, you will
see that's equal to -100*A_1.
Right?
So A_3 is [-1, 1, 4].
A_3 prime is this.
That's exactly equal
to -100 times A_1.
What does that mean?
Well from the point
of view of the matrix,
you are subtracting from the
original third row 100 times
the first row.
But this row operation does
not change the determinant.
In other words, you know that
this determinant should be
the same as the previous one.
So you can write out 2 directly.
From this picture, we
can also see that fact.
So from this picture, we
know that this section
is saying that I need to move
A_3 in the inverse direction
of A_1 by 100 times A_1.
So you're moving
A_3 parallel to A_1.
But it doesn't matter how
far you've moved your apex.
You're moving in a way
that remains parallel
to the base, which is saying
that this movement does not
change the height.
Since A_1 and A_2 are
fixed, your base is fixed,
and you're not
changing the height.
So of course, the
volume is not changing.
That's also a
reason, another way
to see that the
volume of T prime
is simply equal to
the volume of T.
OK, this completes this problem.
I hope this example
was helpful to you.
And we should keep in mind that
the fact that the determinant
is related to
volume sometimes can
become very handy in
computing the volume
of certain geometric objects.
Thank you for watching,
and I'm looking forward
to seeing you soon.
