This tells us that 11 is a critical point of the equation. Now we need to figure out if this is a maximum or a
minimum using the second derivative.
= 16
Because 16 is always positive, any critical value is going to be a minimum. Therefore, the company
should manufacture 11 units in order to minimize its cost.
Example 3: A rocket is fired into the air, and its height in meters at any given time t can be calculated
using the formula h(t) = 1,600 + 196t − 4.9t^2 . Find the maximum height of the rocket and the time at which
it occurs.
Take the derivative and set it equal to zero.
= 196 − 9.8tt = 20Now that we know 20 is a critical point of the equation, use the second derivative test.
= −9.8
This is always negative, so any critical value is a maximum. To determine the maximum height of the
rocket, plug t = 20 into the equation.
h(20) = 1,600 + 196(20) − 4.9(20^2 ) = 3,560 metersThe technique is always the same: (a) take the derivative of the equation; (b) set it equal to zero; and
(c) use the second derivative test.The hardest part of these word problems is when you have to set up the equation yourself. The following
is a classic AP problem:
Example 4: Max wants to make a box with no lid from a rectangular sheet of cardboard that is 18 inches
by 24 inches. The box is to be made by cutting a square of side x from each corner of the sheet and folding
up the sides (see figure below). Find the value of x that maximizes the volume of the box.