q
B A
P
1
Figure 14.4
From Figure 14.4 we see that ifPAis an arc of a unit circle subtending an angleθ
at the centre (173
➤
), then we have:
PB
1
=sinθ
andPA= 1 ×θ(rads).
So
sinθ
θ
=
PB
PA
and clearly asθ→0,PB→PA,so
sinθ
θ
→ 1
Thus we obtain the given result. This limit implies that forθsmall we have sinθ θ.
The same sort of reasoning can also be used to show that for very smallθ,cosθ 1.
It is also useful to note that providedk
=0,
lim
θ→ 0
sinkθ
kθ
= 1
So, for example
lim
θ→ 0
sin 6θ
6 θ
= 1
Once again, remember that in all of this discussion, and in use of the limits defined,
qmust be in radians.
(ii) lim
x→a
(
xn−an
x−a
)
=nan−^1
Whenx=athis has the form 0/0. To find the value of the limit asx→awe consider
values ofxclose toaand therefore takex=a+hso asx→a,h→0. Using the
binomial theorem (71
➤
), we have
lim
h→ 0
[
(a+h)n−an
a+h−a
]
=lim
h→ 0
an+nan−^1 h+
n(n− 1 )
2
an−^2 h^2 +···−an
h
=lim
h→ 0
[
nan−^1 +
n(n− 1 )
2
an−^2 h+···
]
=nan−^1
This result is essentially the differentiation ofxnfrom first principles (231
➤
).
(iii) limx→∞
ex
xn
=limx→∞
[
1
xn
(
1 +x+
x^2
2!
+···+
xn
n!
+···
)]
(126
➤
)
=limx→∞
(
1
xn
+
1
xn−^1
+···+
1
n!
+
x
(n+ 1 )!
+···
)
=∞