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Let's see if we can learn
a thing or two about
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conic sections.
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So first of all, what are
they and why are they
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called conic sections?
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Actually, you probably
recognize a few of them
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already, and I'll
write them out.
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They're the circle, the
ellipse, the parabola,
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and the hyperbola.
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That's a p.
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Hyperbola.
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And you know what
these are already.
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When I first learned conic
sections, I was like, oh,
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I know what a circle is.
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I know what a parabola is.
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And I even know a little bit
about ellipses and hyperbolas.
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Why on earth are they
called conic sections?
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So to put things simply because
they're the intersection
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of a plane and a cone.
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And I draw you
that in a second.
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But just before I do that it
probably makes sense to just
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draw them by themselves.
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And I'll switch colors.
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Circle, we all know
what that is.
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Actually let me see if
I can pick a thicker
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line for my circles.
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so a circle looks
something like that.
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It's all the points that are
equidistant from some center,
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and that distance that they
all are that's the radius.
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So if this is r, and this is
the center, the circle is all
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the points that are exactly
r away from this center.
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We learned that early in our
education what a circle
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is; it makes the world
go round, literally.
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Ellipse in layman's terms is
kind of a squished circle.
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It could look
something like this.
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Let me do an ellipse
in another color.
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So an ellipse could
be like that.
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Could be like that.
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It's harder to draw using the
tool I'm drawing, but it could
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also be tilted and
rotated around.
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But this is a general sense.
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And actually, circles are a
special case of an ellipse.
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It's an ellipse where it's not
stretched in one dimension
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more than the other.
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It's kind of perfectly
symmetric in every way.
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Parabola.
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You've learned that if you've
taken algebra two and you
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probably have if you care
about conic sections.
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But a parabola-- let me draw a
line here to separate things.
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A parabola looks something like
this, kind of a U shape and you
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know, the classic parabola.
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I won't go into the
equations right now.
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Well, I will because you're
probably familiar with it.
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y is equal to x squared.
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And then, you could shift it
around and then you can even
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have a parabola that
goes like this.
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That would be x is
equal to y squared.
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You could rotate these things
around, but I think you know
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the general shape
of a parabola.
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We'll talk more about how do
you graph it or how do you know
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what the interesting points
on a parabola actually are.
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And then the last one,
you might have seen this
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before, is a hyperbola.
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It almost looks like two
parabolas, but not quite,
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because the curves look a
little less U-ish and
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a little more open.
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But I'll explain what
I mean by that.
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So a hyperbola usually
looks something like this.
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So if these are the axes,
then if I were to draw-- let
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me draw some asymptotes.
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I want to go right through
the-- that's pretty good.
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These are asymptotes.
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Those aren't the
actual hyperbola.
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But a hyperbola would look
something like this.
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They get to be right here
and they get really
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close to the asymptote.
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They get closer and closer to
those blue lines like that and
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it happened on this side too.
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The graphs show up here and
then they pop over and
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they show up there.
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This magenta could be one
hyperbola; I haven't done
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true justice to it.
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Or another hyperbola could be
on, you could kind of call
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it a vertical hyperbola.
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That's not the exact word, but
it would look something like
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that where it's below
the asymptote here.
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It's above the asymptote there.
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So this blue one would be
one hyperbola and then the
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magenta one would be a
different hyperbola.
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So those are the
different graphs.
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So the one thing that I'm sure
you're asking is why are
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they called conic sections?
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Why are they not called
bolas or variations of
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circles or whatever?
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And in fact, wasn't
even the relationship.
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It's pretty clear that
circles and ellipses
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are somehow related.
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That an ellipse is just
a squished circle.
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And maybe it even seems that
parabolas and hyperbolas
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are somewhat related.
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This is a P once again.
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They both have bola in their
name and they both kind
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of look like open U's.
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Although a hyperbola has two of
these going and kind of opening
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in different directions,
but they look related.
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But what is the connection
behind all these?
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And that's frankly where
the word conic comes from.
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So let me see if I can draw
a three-dimensional cone.
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So this is a cone.
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That's the top.
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I could've used an
ellipse for the top.
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Looks like that.
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Actually, it has no top.
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It would actually keep going
on forever in that direction.
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I'm just kind of slicing it
so you see that it's a cone.
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This could be the
bottom part of it.
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So let's take different
intersections of a plane with
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this cone and see if we can at
least generate the different
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shapes that we talked
about just now.
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So if we have a plane that goes
directly-- I guess if you call
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this the axis of this
three-dimensional cone,
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so this is the axis.
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So if we have a plane that's
exactly perpendicular to that
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axis-- let's see if I can
draw it in three dimensions.
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The plane would look
something like this.
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So it would have a line.
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This is the front line that's
closer to you and then they
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would have another
line back here.
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That's close enough.
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And of course, you know these
are infinite planes, so it
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goes off in every direction.
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If this plane is directly
perpendicular to the axis
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of these and this is where
the plane goes behind it.
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The intersection of this
plane and this cone is
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going to look like this.
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We're looking at it from an
angle, but if you were looking
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straight down, if you were
listening here and you look at
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this plane-- if you were
looking at it right above.
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If I were to just flip this
over like this, so we're
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looking straight down on this
plane, that intersection
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would be a circle.
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Now, if we take the plane and
we tilt it down a little bit,
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so if instead of that we
have a situation like this.
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Let me see if I can
do it justice.
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We have a situation
where it's-- whoops.
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Let me undo that.
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Edit.
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Undo.
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Where it's like this and has
another side like this,
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and I connect them.
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So that's the plane.
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Now the intersection of this
plane, which is now not
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orthogonal or it's not
perpendicular to the axis of
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this three-dimensional cone.
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If you take the intersection of
that plane and that cone-- and
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in future videos, and you
don't do this in your
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algebra two class.
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But eventually we'll kind of
do the three-dimensional
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intersection and prove that
this is definitely the case.
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You definitely do get the
equations, which I'll show you
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in the not too far future.
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This intersection would
look something like this.
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I think you can
visualize it right now.
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It would look
something like this.
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And if you were to look
straight down on this plane, if
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you were to look right above
the plane, this would look
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something-- this figure I
just drew in purple-- would
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look something like this.
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Well, I didn't draw
it that well.
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It'd be an ellipse.
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You know what an
ellipse looks like.
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And if I tilted it the other
way, the ellipse would
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squeeze the other way.
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But that just gives you a
general sense of why both of
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these are conic sections.
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Now something very interesting.
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If we keep tilting this plane,
so if we tilt the plane so
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it's-- so let's say we're
pivoting around that point.
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So now my plane-- let me
see if I can do this.
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It's a good exercise in
three-dimensional drawing.
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Let's say it looks
something like this.
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I want to go through
that point.
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So this is my
three-dimensional plane.
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I'm drawing it in such a way
that it only intersects this
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bottom cone and the surface
of the plane is parallel to
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the side of this top cone.
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In this case the intersection
of the plane and the cone
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is going to intersect
right at that point.
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You can almost view that I'm
pivoting around this point, at
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the intersection of this point
and the plane and the cone.
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Well this now, the
intersection, would look
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something like this.
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It would look like that.
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And it would keep going down.
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So if I were to draw it,
it would look like this.
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If I was right above the
plane, if I were to
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just draw the plane.
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And there you get
your parabola.
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So that's interesting.
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If you keep kind of tilting--
if you start with a
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circle, tilt a little bit,
you get an ellipse.
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You get kind of a more
and more skewed ellipse.
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And at some point, the ellipse
keeps getting more and
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more skewed like that.
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It kind of pops right when you
become exactly parallel to
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the side of this top cone.
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And I'm doing it all very
inexact right now, but I
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think I want to give
you the intuition.
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It pops and it turns
into a parabola.
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So you can kind of view
a parabola-- there is
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this relationship.
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Parabola is what happens when
one side of an ellipse pops
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open and you get this parabola.
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And then, if you keep tilting
this plane, and I'll do it
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another color-- so
it intersects both
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sides of the cone.
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Let me see if I can draw that.
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So if this is my new
plane-- whoops.
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That's good enough.
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So if my plane looks like
this-- I know it's very hard to
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read now-- and you wanted the
intersection of this plane,
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this green plane and the cone--
I should probably redraw it
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all, but hopefully you're not
getting overwhelmingly
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confused-- the intersection
would look like this.
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It would intersect the bottom
cone there and it would
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intersect the top
cone over there.
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And then you would have
something like this.
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This would be intersection of
the plane and the bottom cone.
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And then up here would be
the intersection of the
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plane and the top one.
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Remember, this plane goes off
in every direction infinitely.
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So that's just a general sense
of what the conic sections are
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and why frankly they're
called conic sections.
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And let me know if this got
confusing because maybe I'll do
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another video while I redraw
it a little bit cleaner.
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Maybe I can find some kind of
neat 3D application that can do
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it better than I can do it.
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This is kind of just the reason
why they all are conic
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sections, and why they really
are related to each other.
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And will do that a little
more in depth mathematically
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in a few videos.
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But in the next video, now that
you know what they are and why
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they're all called conic
sections, I'll actually talk
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about the formulas about these
and how do you recognize
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the formulas.
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And given a formula, how do
you actually plot the graphs
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of these conic sections?
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See you in the next video.
Khan Academy
