4.7 EVALUATION OF LIMITS
Therefore we find
lim
x→af(x)
g(x)=f′(a)
g′(a),providedf′(a)andg′(a) are not themselves both equal to zero. If, however,
f′(a)andg′(a)areboth zero then the same process can be applied to the ratio
f′(x)/g′(x) to yield
lim
x→af(x)
g(x)=f′′(a)
g′′(a),provided that at least one off′′(a)andg′′(a) is non-zero. If the original limit does
exist then it can be found by repeating the process as many times as is necessary
for the ratio of correspondingnth derivatives not to be of the indeterminate form
0 /0, i.e.
lim
x→af(x)
g(x)=f(n)(a)
g(n)(a).Evaluate the limitlim
x→ 0sinx
x.
We first note that ifx= 0, both numerator and denominator are zero. Thus we apply
l’Hopital’s rule: differentiating, we obtainˆ
lim
x→ 0(sinx/x) = lim
x→ 0(cosx/1) = 1.So far we have only considered the case wheref(a)=g(a)=0.Forthecasewheref(a)=g(a)=∞we may still apply l’Hopital’s rule by writingˆ
lim
x→af(x)
g(x)= lim
x→a1 /g(x)
1 /f(x),whichisnowoftheform0/0atx=a. Note also that l’Hopital’s rule is stillˆ
valid for finding limits asx→∞,i.e.whena=∞. This is easily shown by letting
y=1/xas follows:
lim
x→∞f(x)
g(x)= lim
y→ 0f(1/y)
g(1/y)= lim
y→ 0−f′(1/y)/y^2
−g′(1/y)/y^2= lim
y→ 0f′(1/y)
g′(1/y)= lim
x→∞f′(x)
g′(x).