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In the last video, we started to explore
the notion of an error function.
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Not to be confused with the expected value
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because it really does reflect the same
notation.
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But here E is for error.
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And we could also thought it will
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some times here referred to as Reminder
function.
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And we saw it's really just the difference
as we,
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the difference between the function and
our approximation of the function.
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So for example, this, this distance right
over here, that is our error.
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That is our error at the x is equal to b.
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And what we really care about is the
absolute value of it.
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Because at some points f of x might be
larger than the polynomial.
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Sometimes the polynomial might be larger
than f of x.
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What we care is the absolute distance
between them.
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And so what I want to do in this video is
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try to bound, try to bound our error at
some b.
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Try to bound our error.
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So say it's less than or equal to some
constant value.
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Try to bound it at b for some b is greater
than a.
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We're just going to assume that b is
greater than a.
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And we saw some tantalizing, we, we got to
a bit of a tantalizing
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result that seems like we might be able to
bound it in the last video.
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We saw that the n plus 1th derivative of
our error
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function is equal to the n plus 1th
derivative of our function.
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Or their absolute values would also be
equal to.
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So if we could somehow bound the n plus
1th derivative
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of our function over some interval, an
interval that matters to us.
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An interval that maybe has b in it.
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Then, we can, at least bound the n plus
1th derivative our error function.
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And then, maybe we can do a little bit of
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integration to bound the error itself at
some value b.
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So, let's see if we can do that.
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Well, let's just assume, let's just assume
that we're in a reality where
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we do know something about the n plus1
derivative of f of x.
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Let's say we do know that this.
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We do it in a color I that haven't used
yet.
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Well, I'll do it in white.
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So let's say that that thing over there
looks something like that.
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So that is f the n plus 1th derivative.
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The n plus 1th derivative.
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And I only care about it over this
interval right over here.
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Who cares what it does later, I just gotta
bound it over the interval
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cuz at the end of the day I just wanna
balance b right over there.
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So let's say that the absolute value of
this.
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Let's say that we know.
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Let me write it over here, let's say that
we know.
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We know that the absolute value of the n
plus 1th derivative, the n plus 1th.
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And, I apologize I actually switch between
the capital N and
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the lower-case n and I did that in the
last video.
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I shouldn't have, but now that you know
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that I did that hopefully it doesn't
confuse it.
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N plus 1th, so let's say we know that the
n plus 1th
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derivative of f of x, the absolute value
of it, let's say it's bounded.
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Let's say it's less than or equal to some
m
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over the interval, cuz we only care about
the interval.
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It might not be bounded in general, but
all we
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care is it takes some maximum value over
this interval.
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So over, over, over the interval x, I
could write it this way,
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over the interval x is a member between a
and b, so this includes both of them.
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It's a closed interval, x could be a, x
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could be b, or x could be anything in
between.
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And we can say this generally that,
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that this derivative will have some
maximum value.
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So this is its, the absolute value,
maximum value, max value, m for max.
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We know that it will have a maximum value,
if this thing is continuous.
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So once again we're going to assume that
it is continuous,
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that it has some maximum value over this
interval right over here.
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Well this thing, this thing right over
here, we know is the
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same thing as the n plus 1 derivative of
the error function.
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So then we know, so then that, that
implies, that implies that,
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that implies that the, that's a new color,
let me do that in blue, or that green.
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That implies that the, the, the end plus
one derivative of the error function.
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The absolute value of it because these are
the
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same thing is also, is also bounded by m.
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So that's a little bit of an interesting
result but it gets us no where near there.
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It might look similar but this is the n
plus 1 derivative of the error function.
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And, and we'll have to think about how we
can get an m in the future.
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We're assuming that we some how know it
and maybe
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we'll do some example problems where we
figure that out.
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But this is the m plus 1th derivative.
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We bounded it's absolute value but we
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really want to bound the actual error
function.
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The 0 is the derivative, you could say,
the actual function itself.
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What we could try to integrate both sides
of this and see
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if we can eventually get to e, to get to e
of x.
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To get our, to our error function or our
remainder function so let's do that.
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Let's take the integral, let's take the
integral of both sides of this.
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Now the integral on this left hand side,
it's a little interesting.
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We take the integral of the absolute
value.
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It would be easier if we were taking the
absolute value of the integral.
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And lucky for us, the way it's set up.
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So let me just write a little aside here.
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We know generally that if I take, and it's
something for you to think about.
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If I take, so if I have two options, if I
have two
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options, this option versus and I don't
know, they look the same right now.
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I know they look the same right now.
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So over here, I'm gonna have the integral
of the absolute value
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and over here I'm going to have the
absolute value of the interval.
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Which of these is going to be, which of
these can be larger?
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Well, you just have to think about the
scenarios.
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So, if f of x is always positive over the
interval that
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you're taking the integration, then
they're going to be the same thing.
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They're, you're gonna get positive values.
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Take the absolute of a value of a positive
value.
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It doesn't make a difference.
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What matters is if f of x is negative.
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If f of x, if f of x is negative the
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entire time, so if this our x-axis, that
is our y-axis.
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If f of x is, well we saw if it's positive
the entire
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time, you're taking the absolute value of
a positive, absolute value of positive.
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It's not going to matter.
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These two things are going to be equal.
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If f of x is negative the whole time, then
you're going
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to get, then this integral going to
evaluate to a negative value.
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But then, you would take the absolute
value of it.
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And then over here, you're just going to,
this is, the integral going to
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value to a positive value and it's still
going to be the same thing.
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The interesting case is when f of x is
both
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positive and negative, so you can imagine
a situation like this.
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If f of x looks something like that, then
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this right over here, the integral, you'd
have positive.
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This would be positive and then this would
be negative right over here.
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And so they would cancel each other out.
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So this would be a smaller value than
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if you took the integral of the absolute
value.
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So the integral, the absolute value of f
would look something like this.
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So all of the areas are going to be, if
you view the
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integral, if you view this it is
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definitely going to be a definite
integral.
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All of the areas, all of the areas would
be positive.
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So when you it, you are going to get a
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bigger value when you take the integral of
an absolute value.
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Then you will, especially when f of x
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goes both positive and negative over the
interval.
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Then you would if you took the integral
first and then the absolute value.
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Cuz once again, if you took the integral
first, for something like
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this, you'd get a low value cause this
stuff would cancel out.
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Would cancel out with this stuff right
over here then you'd
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take the absolute value of just a lower, a
lower magnitude number.
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And so in general, the integral, the
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integral, sorry the absolute value of the
integral
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is going to be less than or equal to the
integral of the absolute value.
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So we can say, so this right here is the
integral of
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the absolute value which is going to be
greater than or equal.
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What we have written over here is just
this.
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That's going to be greater than or equal
to, and I
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think you'll see why I'm why I'm doing
this in a second.
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Greater than or equal to the absolute
value, the absolute
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value of the integral of, of the n plus
1th derivative.
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The n plus 1th derivative of, x, dx.
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And the reason why this is useful, is that
we can still
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keep the inequality that, this is less
than, or equal to this.
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But now, this is a pretty straight forward
integral to evaluate.
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The indo, the anti-derivative of the n
plus
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1th derivative, is going to be the nth
derivative.
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So this business, right over here.
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Is just going to the absolute value of the
nth derivative.
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The absolute value of the nth derivative
of our error function.
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Did I say expected value?
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I shouldn't.
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See, it even confuses me.
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This is the error function.
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I should've used r, r for remainder.
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But this all error.
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The, noth, nothing about probability or
expected value in this video.
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This is.
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E for error.
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So anyway, this is going to be the nth
derivative of our
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error function, which is going to be less
than or equal to this.
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Which is less than or equal to the
anti-derivative of M.
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Well, that's a constant.
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So that's going to be mx, mx.
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And since we're just taking indefinite
integrals.
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We can't forget the idea that we have a
constant over here.
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And in general, when you're trying to
create an upper
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bound you want as low of an upper bound as
possible.
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So we wanna minimize, we wanna minimize
what this constant is.
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And lucky for us, we do have, we do know
what this,
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what this function, what value this
function takes on at a point.
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We know that the nth derivative of our
error function at a is equal to 0.
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I think we wrote it over here.
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The nth derivative at a is equal to 0.
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And that's because the nth derivative of
the function and the
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approximation at a are going to be the
same exact thing.
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And so, if we evaluate both sides of this
at a, I'll
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do that over here on the side, we know
that the absolute value.
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We know the absolute value of the nth
derivative at a, we know
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that this thing is going to be equal to
the absolute value of 0.
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Which is 0.
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Which needs to be less than or equal to
when you evaluate this
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thing at a, which is less than or equal to
m a plus c.
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And so you can, if you look at this part
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of the inequality, you subtract m a from
both sides.
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You get negative m a is less than or equal
to c.
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So our constant here, based on that little
condition
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that we were able to get in the last
video.
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Our constant is going to be greater than
or equal to negative ma.
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So if we want to minimize the constant, if
we wanna get this as low
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of a bound as possible, we would wanna
pick c is equal to negative Ma.
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That is the lowest possible c that will
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meet these constraints that we know are
true.
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So, we will actually pick c to be negative
Ma.
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And then we can rewrite this whole thing
as the
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absolute value of the nth derivative of
the error function.
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The nth derivative of the error function.
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Not the expected value.
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I have a strange suspicion I might have
said expected value.
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But, this is the error function.
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The nth der.
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The absolute value of the nth derivative
of the error function
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is less than or equal to M times x minus
a.
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And once again all of the constraints
hold.
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This is for, this is for x as part of the
interval.
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The closed interval between, the closed
interval between a and b.
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But looks like we're making progress.
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We at least went from the m plus 1
derivative to the n derivative.
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Lets see if we can keep going.
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So same general idea.
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This if we know this then we know that
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we can take the integral of both sides of
this.
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So we can take the integral of both sides
of this
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the anti derivative of both sides.
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And we know from what we figured out up
here
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that something's that's even smaller than
this right over here.
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Is, is the absolute value of the integral
of the expected value.
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Now [LAUGH] see, I said it.
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Of the error function, not the expected
value.
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Of the error function.
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The nth derivative of the error function
of x.
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The nth derivative of the error function
of x dx.
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So we know that this is less than or equal
to based on the exact same logic there.
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And this is useful because this is just
going to be, this is just
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going to be the nth minus 1 derivative of
our error function of x.
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And of course we have the absolute value
outside of it.
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And now this is going to be less than or
equal to.
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It's less than or equal to this, which is
less than or equal
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to this, which is less than or equal to
this right over here.
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The anti-derivative of this right over
here is going
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to be M times x minus a squared over 2.
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You could do U substitution if you want or
you could just say hey look.
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I have a little expression here, it's
derivative is 1.
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So it's implicitly there so I can just
treat it as kind of a U.
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So raise it to an exponent and then divide
that exponent.
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But once again I'm taking indefinite
integrals.
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So I'm going to say a plus C over here.
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But let's use that same exact logic.
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If we evaluate this at A, you're going to
have it.
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If you evaluate this while, let's evaluate
both sides of this at A.
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the left side, evaluated at A, we know, is
going to be zero.
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We figured that out, all, up here in the
last video.
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So you get, I'm gonna do it on the right
over here.
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You get zero, when you valued the left
side of a.
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The right side of a, if you, the right
side of the
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value of a you get m times a menus a
square over 2.
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So you are gonna get 0 plus c, so you are
gonna get, 0 is less or equal to c.
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Once again we want to minimize our constant,
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we wanna minimize our upper boundary up
here.
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So we wanna pick the lowest possible c
that we talk constrains.
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So the lowest possible c that meets our
constraint is zero.
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And so the general idea here is that we
can keep doing this, we can
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keep doing exactly what we're doing all
the way, all the way, all the way until.
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And so we keep integrating it at the exact
same, same way that I've
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done it all the way that we get and using
this exact same property here.
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All the way until we get, the bound on the
error function of x.
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So you could view this as the 0th
derivative.
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You know, we're going all the way to the
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0th derivative, which is really just the
error function.
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The bound on the error function of x is
going to
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be less than or equal to, and what's it
going to be?
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And you can already see the pattern here.
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Is that it's going to be m times x, minus
a.
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And the exponent, the one way to think
about it, this exponent
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plus this derivative is going to be equal
to n plus 1.
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Now this derivative is zero so this
exponent is going to be n plus 1.
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And whatever the exponent is, you're going
to have,a nd maybe I should
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have done it, you're going to have n plus
one factorial over here.
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And if say wait why, where does this n
plus 1 factorial come from?
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I just had a two here.
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Well think about what happens when we
integrate this again.
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You're going to raise this to the third
power and then divide by three.
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So your denominator is going to have two
times three.
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Then when you integrate it again, you're
going to raise
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it to the fourth power and then divide by
four.
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So then your denominator is going to be
two times three times four.
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Four factorial.
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So whatever power you're raising to, the
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denominator is going to be that power
factorial.
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But what's really interesting now is if we
are
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able to figure out that maximum value of
our function.
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If we're able to figure out that maximum
value of our function right there.
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We now have a way of bounding our error
function
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over that interval, over that interval
between a and b.
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So for example, the error function at b.
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We can now bound it if we know what an m
is.
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We can say the error function at b is
going to be less than or equal to m times
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b minus a to the n plus 1th power over n
plus 1 factorial.
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So that gets us a really powerful, I guess
you
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could call it, result, kinda the, the math
behind it.
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And now we can show some examples where
this could actually be applied.
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