1)Find the linear approximation to:
f(x) = Ö (1 + x) at x = 3
Solution:
We evaluate the first two terms of the Taylor series for f at a = 3:
f(a) + f ’(a) × (x – a)
For which f '(x) = ½ (1 + x) -1/2
f(3) = 2
f '(3) = ½ (1 + 3) -1/2
= ½ (1/Ö (4)) = ½ (½) = 1/4
Then: f(x) = 2 + 1/4 (x - 3) = 2 + x/4 - 3/4
= 5/4 + x/4
At x = 3.2 we obtain:
Ö (1 + x) = Ö (1 + 3.2) » 5/4 + 3.2/4
= 1.250 + 0.800 = 2.050
Which differs from the true value:
Ö 4.2 » 2.04939
By less than one one thousandth
2) Show that in general:
(1 + x)k » 1 + kx
For any k, provided x » 0
Solution:
Check at two different values for k:
Rem: Approximation is good for any x » 0
a) k = -1 and we will get (-x) instead of x, so:
1/ (x - 1) = (1 + x)-1 » 1 + (-1) (-x) = 1 + x
Try x= 0.01, then:
(1 + x)-1 = 1.01
(1 + kx) = 1.01
But if larger x is tried, e.g. x = 0.1 we see:
(1 + x)-1 = 1.11 vs. 1.1
b) We use k = 1/3 and 5 x4 instead of x:
(1 + x) 1/3 = 3Ö( 1 + 5 x4 ) = (1 + 5 x4) 1/3
» 1 + 1/3 (5 x4) » 1 + 1/3 (5 x4) » 1 + 5 x4/ 3
Try x= 0.50, then:
(1 + x) 1/3 = 0.883
(1 + kx) = 1 + 1/3 (5 x4) » 0.896
But if smaller x is tried, e.g. x = 0.01, we get equal values (1)
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