214 Chapter 4 • Limits of Functions
Similarly, we can combine finite and infinite limits algebraically. Suppose
P > 0 and N < 0 represent positive and negative real numbers, respectively,
which are limits of functions. Table 4.2 summarizes the results:
Table 4.2
Algebra of Infinite Limits
(+oo) + P(or N) = +oo
(-oo) + P(or N) = -oo
(±oo) · P = ±oo
(±oo) · N = =foo
( ±oo) · 0 is indeterminate
_1_ =0
±oo
1
The indeterminate
0
, covered by Theorem 4.4.3 along with Exercises 2 and
4, can be refined a bit further. Suppose limf(x) = 0. We shall write limf(x ) =
o+ if f (x) > 0 throughout appropriate interval( s), and lim f(x) = o-if f (x) < 0
throughout appropriate interval(s). With this understanding, we have
Table 4.3
Algebra of Infinite Limits
1
o+ = +oo
1
-=- 00
o-
In Section 4 .2 we proved the "Squeeze Principle" (Theorem 4.2.20) for
[finite] limits of functions. The analogous result for infinite limits is called the
"Comparison Principle,'' and is stated in the following theorem.
Theorem 4.4.10 (Comparison Test) Suppose that f(x) ~ g(x) for all x in
some deleted neighborhood of xo.
(a) If lim f(x) = + oo, then lim g(x) = + oo;
X--+Xo X--+Xo
(b) lim g(x) = -oo, then lim f(x) = -oo.
x--+xo x--+xo