Cambridge International AS and A Level Mathematics Pure Mathematics 1

(Michael S) #1

P1^


5


Finding the gradient from first principles


! Figure 5.6 shows Q in a position where h is positive, but negative values of
h would put Q to the left of P.

From figure 5.6, the gradient of PQ is ()^39 –
+h^2
h
= ++

= +

= +
=+

96 9

6

6

6

2

2

hh
h
hh
h
hh
h
h


()

.

For example, when h = 0.001, the gradient of PQ is 6.001, and when h = −0.001,
the gradient of PQ is 5.999. The gradient of the tangent at P is between these two
values. Similarly the gradient of the tangent would be between 6 − h and 6 + h for
all small non-zero values of h.
For this to be true the gradient of the tangent at (3, 9) must be exactly 6.

ACTIVITY 5.3 Using a similar method, find the gradient of the tangent to the curve at


(i) (1, 1)
(ii) (−2, 4)
(iii) (4, 16).
What do you notice?

The gradient function
The work so far has involved finding the gradient of the curve y = x^2 at a
particular point (3, 9), but this is not the way in which you would normally find
the gradient at a point. Rather you would consider the general point, (x, y), and
then substitute the value(s) of x (and/or y) corresponding to the point of interest.

h

Q

(3, 9) P

(3 + h)^2 – 9

(3 + h, (3 + h)^2 )

Figure 5.6
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