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Transcript 
Slope of the tangent to ax
We defined a function M (a) as follows:
aΔx − 1
.
Δx→0
Δx
M (a) = lim
d x
This definition allows us to say that dx
a = M (a)ax . In order to understand
x
the derivative of a we must understand M (a); we next look at two different
ways of thinking about M (a).
First, if we plug x = 0 in to the definition of the derivative of ax we get:
�
�
d x ��
ax+Δx − ax ��
a
= lim
�
Δx→0
dx �x=0
Δx
x=0
a0+Δx − a0
Δx→0
Δx
aΔx − 1
= lim
Δx→0
Δx
= M (a)
=
lim
d x
(or we could simply observe that dx
a |x=0 = M (a)a0 = M (a)). So M (a) is the
x
value of the derivative of a when x = 0.
Remember that the derivative tells us the slope of the tangent line to the
graph. So M (a) can also be thought of as the slope of the graph of y = ax at
x = 0.
Note that the shape of the graph of ax depends on the choice of a, so for
different values for a we’ll get different tangent lines and different values for
M (a).
d x
Because dx
a = M (a)ax , we only need to know the slope of the line tangent
to the graph at x = 0 in order to figure out the slope of the tangent line at any
point on the graph!
Remember that when we computed the derivative of the sine function we
sin x
worked hard to compute the value of lim
. This value is just the derivative
x→ 0 x
of sin x when x = 0 — check this yourself by writing down the definition of the
derivative of sin x and replacing x by 0. In order to get a general formula for the
derivative of the sine function we first had to know the value of its derivative
when x = 0.
The formula for ax+Δx is simpler than the one for sin(x + Δx), so the first
d x
part of our calculation of dx
a was easier than the corresponding calculation
for sin x. But when we try to compute:
aΔx − 1
Δx→0
Δx
M (a) = lim
sin x
,
x→ 0 x
we get stuck. We were able to use radians and the unit circle to find lim
1
ax
M(a)
(slope of ax at x=0)
Figure 1: Geometric definition of M (a)
but we don’t have a good way to find the exact slope of the tangent line to
y = ax at x = 0.
2
MIT OpenCourseWare
http://ocw.mit.edu
18.01SC Single Variable Calculus
Fall 2010
For information about citing these materials or our Terms of Use, visit: http://ocw.mit.edu/terms.
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