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Sometimes we have functions that
look like this.
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Cause of X squared.
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Now there are immediate things
that are different about this
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than the straightforward cosine
function. It's cause of X
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squared, not just cause of X,
and so we call this function
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of a function Y equals a
function of another function.
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Now in this case.
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The function F is the cosine
function, and the function G is
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the square function. Or we could
identify them, perhaps a bit
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more mathematically by saying
that F of X is cause
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X&G of X is X squared.
Now let's have a look at
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another example of this.
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This time we'll turn it around,
so to speak. Let's have a look
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at cause squared X.
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Now, how is this a function of a
function? Let's remember what
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cost squared of X means. It
means cause X squared cause X
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multiplied by itself. So now if
we look at our function of a
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function. Let's see what we can
do to identify which is F and
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which is G of X. So here we are
squaring, so it's the F is the
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square function, and inside the
square function, the thing that
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we are actually squaring is G of
X, namely cause X. So here the F
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is the square function and the G
is the cosine function. Or write
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it down more mathematically F of
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X. Is X squared? Angie of
X is cause X?
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Now how do we differentiate
a function like Cos squared
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X or a function like the
cause of X squared? What we
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need to do to be able to
differentiate something that
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is a function of a function?
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To do that, we need
to do two things. One,
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we need to substitute.
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You equals G of X. This would
then give us Y equals F of
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you, which of course is much
simpler than F of G of X.
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Next we need to use a rule
or a formula that's known as the
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chain rule. China
rules quite simple,
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says DY by DX is
equal to DY by EU
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Times du by The X.
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Notice it looks as though the D
use cancel out. If these were
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fractions, which they're not, it
looks as though they might
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cancel out. That's a way of
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remembering it. So this is how
we're going to approach it.
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Substitute you equals G of X.
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And then apply this rule called
the chain rule in order to find
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the derivative. So let's take a
number of examples and the first
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one will take is the very first
example that we looked at.
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And that was why equals
cause of X squared.
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So our first step was to
put you equals X squared.
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And then Y is
equal to cause you.
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Now the chain rule says DY
by the X is equal to
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DY by du times du by
the X. So we need.
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Do you buy the X?
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Well, that's 2X. We
differentiate this. We multiply
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by the two and take one off
the index. That leaves us 2X and
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we need the why by DU.
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And the derivative of Cos you is
minus sign you.
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So now we need to put these
together DY by the X is equal
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to. Divide by do you minus
sign U times do you buy DX
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which is 2 X?
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Now this is all very well, but
really we'd like to have
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everything in terms of X. And
here we've got you, so we need
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to undo this substitution. If we
put you equals X squared, we now
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need to replace EU by X squared,
and so we write minus 2X and
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bringing the two X to the front
sign of X squared.
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Now they're all done like that.
What I'm going to do with all
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the next examples that I do is
I'm going to put this
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differentiation of the two bits
up here with these two bits.
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Let's have a look at the
other one. We had. Y equals
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cause squared X. Let's
remember that meant the
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cause of X all squared.
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So this is now the G
of X and so we will
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put you equals cause of X.
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Then Y is equal
to you squared.
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I can calculate do you
buy DX that's minus sign
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X and I can calculate
DY by du. That's two
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you. Write down the chain
rule the why by DX is
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DY by du times DU by
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The X. And now we can substitute
in the bits that we've already
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calculated. The why by do you is
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to you. Times do you buy DX
which is minus sign X equals.
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Now again we want this all in
terms of X. So what we have to
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do is reverse the substitution
we put you equals to cause X and
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now we need to undo that by
replacing EU with cause X. So
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bringing the minus sign to the
front minus 2.
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Kohl's X
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Sign X.
Let's take
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another example.
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Y equals 2X minus five
all raised to the power
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10. Now, it might be tempting to
say, well surely we could just
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multiply out the brackets, but
this is to the power 10 to
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multiply out. Those brackets
would take his ages, and there's
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all those mistakes that could be
made in doing it. Plus when we
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differentiate it, we may not
have the best form for future
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work, so let's use function of a
function. So here we will put
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you equals this bit here inside
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the bracket. 2X minus five
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and then. Why is
equal to U to the power
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10?
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I can now do the differentiation
of the little bits. Do you buy
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the X is just two the derivative
of two X just giving us two and
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E? Why by DU is 10 we multiply
by the index U to the power 9.
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We take one away from the index.
Now we can put this together
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using the chain rule so divided
by DX is equal to.
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The why by DU times
DU by X, substituting our
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little bits. Here's the why
by DU10U to the ninth
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times two do you buy
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DX? 2 * 10 is 20 and I
want you to the power 9 and I
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need to get this all in terms of
X, so I need to replace the you
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here. By the two X minus five.
So that's 2X minus five all to
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the power 9, and that's a
compact expression for the
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derivative. Think what it would
have been like if I had to
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expand the brackets and
differentiate each term.
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I want now to take another trick
example and then develope that
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trig example a little bit
further to a more general case.
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So we'll take
Y equals the
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sign of 5X.
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Very easy here to identify the
G of X. It's this bit
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here the 5X so will put
you equals 5X.
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And then why will be
equal to sign you?
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Differentiating do you buy the
X is equal to 5.
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And DY bite U is
equal to cause you.
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Put the two bits together with
the chain rule DY by the
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X is equal to DY by
EU Times DU by The X.
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DIY Bindu is cause you.
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Times by and you by the
ex here is 5.
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So let's bring the five to
the front 5 cause of, and
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now let's reverse the
substitution. You is equal to
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5X, so will replace EU by
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5X. Now, notice how that five
here and here is apparently
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appeared there, and it did so
because the derivative of 5X was
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five. So the question is, could
we do this with any number that
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appeared there in front of the X
bit five or six? Or 1/2 or
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not .5? Or for that matter, an
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so? Have a look at
Y equal sign NX.
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You equals an X that
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sour substitution. And then Y
is equal to sign you we can
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differentiate EU with respect to
X and the derivative of NX is
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just N because N is a constant
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and number. And the why by
DU is equal to cause you.
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We can now put this back
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together again. My by the X
is DY by EU Times
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DU by The X.
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Equals. DIY
Bindu is cause you.
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Times by du by DX, which is just
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N. So let's move the
end to the front. That's
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N cause NX.
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So the ends of behaved in
exactly the same way that the
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fives behaved in the previous
question. And of course this
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means. Now we're in a position
to be able to do any question
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like this simply by writing down
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the answer. So if we're just
going to write down the answer,
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let's take. Why is
sign of 6X?
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And then divide by the X is
just six cause 6X just by using
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the standard result that we had
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before. Similarly, if we had
Y was equal to cause 1/2, X
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will just because it's cause
it's not going to be any
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different to sign really and
so D. Why by DX is equal
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to 1/2 and the derivative of
causes minus sign 1/2 X.
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Now let's take one more example.
In this particular style, so
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will take Y equals E to
the X cubed. And here this
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X cubed is our G of
X. So we will put you
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equals X cubed.
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And then why will be equal 2
E to the power you we can
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differentiate. So do you find
the X is equal to three X
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squared? We multiply by the
power and take one off it. And
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why by DU is equal to E
to the power you we
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differentiate with respect to
you. The exponential function is
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it's. Own derivative, and so it
stays the same.
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Bringing those two bits together
to give us the why by DX through
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the chain rule DY by DX is DY by
du times by DU by The X.
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The why Bindu is E to the power
you times by du by DX which is
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3 X squared.
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Move the three X squared through
to the front.
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E to the power. And now we made
the substitution that gave us
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you we put you equals X cubed
and now we need to.
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Reverse that substitution and
replace U by X cubed.
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So let's have a look at what
we've got here.
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E to the X cubed. Now if we
think of this as E to EU then E
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to EU is just the derivative of
the F with respect to you.
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Because the exponential function
is own derivative and here the
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three X squared is simply the
derivative of U with respect to
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X. In other words, it's the
derivative of G of X. Now let's
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see if we can put that together
for a general case.
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So we've got Y equals
F of G of X.
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And we're putting you equals G
of X and our chain rule tells
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us that the why by the X
is equal to.
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DY by EU Times
DU by The X.
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Equals let's start here. You
remember that in most of the
-
examples that I've done, I've
been pushing the result of du by
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DX forward to the front of the
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expression. So let's do it to
begin with. Instead, at the end
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when we've been simplifying, so
do you buy DX? This is the
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derivative of G of X, so that's
DG by D of X by DX.
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Times by and this is the why
by DU. So that's the derivative
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of F of G of X with
respect to you.
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Now can we use this? Let's have
a look at an example why equals
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the tan of X squared and so DY
by the X is equal to.
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Well, this bit here is the G of
X, so we need its derivative
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and we're going to write it
down at the front. That's easy,
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that's 2X. And now we need to
differentiate tan as though
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this was tamu with respect to
you and the derivative of tan
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is just sex squared. And then
we need to put in the G of X
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sex squared X squared.
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Notice how short this is. 2
lines. Let's just look back at
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the example that we did before
and it took us all of this.
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What we've done is we've
contracted this whole process to
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one that takes place in our
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head. Quicker. You can still do
it this way if you like, but if
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you can get into the habit of
doing this, it's much quicker.
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So let's have a look at some
examples and try and keep track
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of what we're doing. So let's
begin with Y equals E to the one
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plus X squared.
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Sunday why by DX is equal to.
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Well, we can identify the G of
X. It's this up here. The power
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of the exponential function, and
so if we differentiate that it's
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2X. And now we want the
derivative of the exponential
-
function. It is its own
derivative, so that's E to the
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one plus X squared.
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Able to write it down straight
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away. Let's take Y
equals the sign of X
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Plus E to the X.
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The why by DX is equal to
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well here. We can identify the G
of X, so we want the derivative
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of this to write down the
derivative of X is one. The
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derivative of E to the X is just
E to the X.
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Times by and we want the
derivative of this.
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As though this were you and the
derivative of sine is cause, and
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then X Plus E to the power X.
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We take
Y equals
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the tan.
All X squared
-
plus sign X.
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Why buy the X is equal
to identify the G of X?
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That's this lump here, the X
squared plus sign X
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differentiate it 2X plus cause
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X. And now the derivative of
tan as though it were tan of
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U. Well that will be sex
squared. But instead of EU
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we want you is G of X which
is X squared plus sign X.
-
Y equals this time will have a
look at one that's got brackets
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and powers in it. 2 minus X to
the 5th, all raised to the 9th
-
power. The why by DX is got
to identify the G of X first and
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the G of X is this bit inside
the bracket the two minus X to
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the power 5. So we need to
differentiate that first, so
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that's going to be minus 5X to
the power 4.
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Remember the derivative of two,
which is a constant is 0 and
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then multiply by the Five and
take one off the index of minus
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5X to the power 4.
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Now we've got to differentiate
to the power 9 as though it was
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you to the power 9 will that
would be times by 9, and then
-
instead of EU we want.
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The two minus X to the 5th and
we take one away from the
-
power. We get that little bit
of tidying up to do here,
-
'cause we've got a
multiplication that we can do
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minus five times by 9 - 45 X
to the power four 2 minus X to
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the fifth, raised to the power
8.
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Take 1 final example.
-
Let's take Y equals the
log of X plus sign
-
X. We can identify this as our
G of X.
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So D why by DX is equal to
we can write down the derivative
-
of this one plus cause X times
by and now we want the
-
derivative of log.
-
Well, the derivative of log of
you would be one over you, so
-
this is one over and this is EU
or the G of X one over X plus
-
sign X and it be untidy to leave
it like that. So we move that
-
numerator one plus cause X. So
it's more obviously the
-
numerator of the fraction. So
what we've seen there is the use
-
of the chain rule.
-
But then modifying it slightly
so we get used to writing down
-
the answer more or less
straight away. You can still
-
use the chain rule. You can
still do it at full length, but
-
if you can get into the habit
of doing it like this, you find
-
it quicker and easier to be
able to manage and more
-
complicated problems will be
easier to do if you can short
-
cut short circuit some of the
processes.
