PRELIMINARY CALCULUS
Q
A
B
C
f(x)xS
Figure 2.2 A graph of a function,f(x), showing how differentiation corre-
sponds to finding the gradient of the function at a particular point. PointsB,
QandSare stationary points (see text).Find the third derivative of the functionf(x)=x^3 sinx.Using (2.14) we immediately find
f′′′(x)=6sinx+3(6x)cosx+3(3x^2 )(−sinx)+x^3 (−cosx)
=3(2− 3 x^2 )sinx+x(18−x^2 )cosx.2.1.8 Special points of a functionWe have interpreted the derivative of a function as the gradient of the function at
the relevant point (figure 2.1). If the gradient is zero for some particular value of
xthen the function is said to have astationary pointthere. Clearly, in graphical
terms, this corresponds to a horizontal tangent to the graph.
Stationary points may be divided into three categories and an example of eachis shown in figure 2.2. PointBis said to be aminimumsince the functionincreases
in value in both directions away from it. PointQis said to be amaximumsince
the functiondecreasesin both directions away from it. Note thatBis not the
overall minimum value of the function andQis not the overall maximum; rather,
they are a local minimum and a local maximum. Maxima and minima are known
collectively asturning points.
The third type of stationary point is thestationary point of inflection,S.Inthis case the function falls in the positivex-direction and rises in the negative
x-direction so thatSis neither a maximum nor a minimum. Nevertheless, the
gradient of the function is zero atS, i.e. the graph of the function is flat there,
and this justifies our calling it a stationary point. Of course, a point at which the