The properties of limits are fairly well what we might expect. Thus, if
lim
x→a
f(x)=b lim
x→a
g(x)=c
then
L1. lim
x→a
kf (x)=kb for any fixed k
L2. xlim→a[f(x)±g(x)]=xlim→af(x)±xlim→ag(x)=b±c
L3. lim
x→a
[f(x)g(x)]=lim
x→a
f(x)lim
x→a
g(x)=bc
L4. lim
x→a
[
f(x)
g(x)
]
=
limx→af(x)
limx→ag(x)
=
b
c
ifc
= 0
L5. lim
x→a
[f(x)]
1
n=b
1
nprovided [f(x)]
1
nandb
1
nare real.
NB. We must always check that limx→af(x), limx→ag(x)exist before applying the above
results, all of which are proved rigorously in pure maths books, but are fairly ‘obvious’.
Problem 14.5
Evaluate the limits
(i) lim
x→ 1
[
x^2 − 1
x− 1
×.x^2 Y 2 xY 3 /
]
(ii) lim
x→ 1
[
x^2 − 1
.x− 1 /
√
x^2 Y 2 xY 3
]
We know from Problems 14.2 and 14.3 that
lim
x→ 1
x^2 − 1
x− 1
= 2 and lim
x→ 1
(x^2 + 2 x+ 3 )= 6
(i) Using rule L3, we have
lim
x→ 1
[
x^2 − 1
x− 1
×(x^2 + 2 x+ 3 )
]
=lim
x→ 1
x^2 − 1
x− 1
×lim
x→ 1
(x^2 + 2 x+ 3 )
= 2 × 6 = 12
which you can see we also get from:
lim
x→ 1
[(x+ 1 )×(x^2 + 2 x+ 3 )]= 12
(ii) Using rules L4 and L5, we have
lim
x→ 1
[
x^2 − 1
(x− 1 )
√
x^2 + 2 x+ 3
]
=lim
x→ 1
x^2 − 1
x− 1
÷lim
x→ 1
√
x^2 + 2 x+ 3
= 2 ÷
√
lim
x→ 1
x^2 + 2 x+ 3
= 2 ÷
√
6 =
2
√
6
=
√
6
3