98 Chapter 4Differentiation
Point a.The function has a finite discontinuityatx 1 = 1 a. For example, the function
is discontinuous atx 1 = 10 where its value is −1. However, if we approach the point
x 1 = 10 from the right,f(x)approaches the value +1.
Point b.The function has an infinite discontinuityatx 1 = 1 b. If we approach this point
from the left, the value of the function tends to −∞; if we approach from the right the
function tends to +∞. Infinity is not a number, and the function is not defined at
x 1 = 1 b. An example is 12 (x 1 − 1 1), discontinuous atx 1 = 11.
Point c.The function tends to infinity if we approach the pointx 1 = 1 cfrom either side;
for example, 12 x
2atx 1 = 10.
In these three cases, the nature of the discontinuities is obvious from the graphs; they
are said to be essential discontinuities. In some cases however, the discontinuity
is not obvious from the graph. For example, the functionf(x) 1 = 1 x 2 xhas constant
value equal to 1 for all values ofx 1 ≠ 10 , but it is not defined atx 1 = 10 because 0 2 0 is
indeterminate and has no meaning. Such a discontinuity is said to be removable. If we
redefine the function such thatf 1 = 1 x 2 xwhenx 1 ≠ 10 andf(x) 1 = 11 whenx 1 = 10 , then
the function becomes continuous for every value of x; the discontinuity has been
removed with no change to the function except at an isolated point.
0 Exercises 4–6
4.4 Limits
Consider the rational function
which is continuous for all values of xexceptx 1 = 12. Table 4.1 shows that, whereas both
the numerator and the denominator go to zero atx 1 = 12 , their ratioapproaches the
valuey 1 = 14 asx 1 → 12 from both sides:
Table 4.1 Values ofy 1 = 1 (x
21 − 1 4) 2 (x 1 − 1 2)
x 2.1 2.01 2.001 2.0001 = 1.9999 1.999 1.99 1.9
y 4.1 4.01 4.001 4.0001 = 3.9999 3.999 3.99 3.9
lim
x
x
x
→
−
−
=
2
24
2
4
y
x
x
=
−
−
24
2
fx
xx
xx
()=
+>
−≤
10
10
if
if