3.5. Limits at Infinity http://www.ck12.org
So we infer that limx→ 0 ln(xx+^1 )=1.
For the infinite limit, limx→∞ln(xx+^1 )=1, the inference of the limit is not as obvious. The function appears to approach
the value 0 but does so very slowly, as the following table suggests.
x ln(x+ 1 )/x
10 0. 23979
50 0. 078637
100 0. 046151
1000 0. 006909
10000 0. 000921This unpredictable situation will apply to many other functions of the form. Hence we need another method that will
provide a different tool for analyzing functions of the formgf((xx)).
L’Hospital’s Rule: Let functions f andgbe differentiable at every number other thancin some interval, with
g′(x) 6 =0 ifx 6 =c.If limx→cf(x) =limx→cg(x) =0, or if limx→cf(x) =±∞and limx→cg(x) =±∞,then:
- limx→cgf((xx))=limx→cgf′′((xx))as long as this latter limit exists or is infinite.
- Iffandgare differentiable at every numberxgreater than some numbera, withg′(x) 6 = 0 ,then limx→∞gf((xx))=
limx→∞gf′′((xx))as long as this latter limit exists or is infinite.
Let’s look at applying the rule to some examples.
Example 2:
We will start by reconsidering the previous example,f(x) =ln(xx+^1 ),and verify the following limits using L’Hospital’s
Rule:
limx→ 0 ln(xx+^1 )= 1.xlim→∞ln(xx+^1 )=^0.Solution:
Since limx→ 0 ln(x+ 1 ) =limx→ 0 x=0, L’Hospital’s Rule applies and we have
xlim→ 0 ln(xx+^1 )=limx→ 0x+^11
1 =1
1 =^1.
Likewise,
xlim→∞ln(xx+^1 )=xlim→∞x+^11
1 =0
1 =^0.
Now let’s look at some more examples.
Example 3: