We'll note the integers as x and
y.
The sum of the integers is
12.
x + y = 12
y = 12 -
x
We also know that the product of one and the square of
the other is a maximum.
We'll write the product of integers
as:
P = x*y^2
We'll substitute
y by (12-x) and we'll create the function p(x):
p(x) =
x*(12-x)^2
We'll expand the
square:
p(x) = x(144 - 24x +
x^2)
We'll remove the
brackets:
p(x) = 144x - 24x^2 +
x^3
The function p(x) is a maximum when x is critical,
that means that p'(x) = 0
We'll calculate the first
derivative for p(x):
p'(x) = (144x - 24x^2 +
x^3)'
p'(x) = 144 - 48x +
3x^2
p'(x) = 0
144 - 48x +
3x^2 = 0
We'll divide by 3 and we'll apply symmetric
property:
x^2 - 16x + 48 =
0
We'll apply the quadratic
formula:
x1 =
[16+sqrt(256-192)]/2
x1 =
(16+8)/2
x1 = 12
x2 =
(16-8)/2
x2 =
4
The positive numbers are: x = 4 and y = 12
- 4 = 8.
Note:
We cannot choose x = 12 because x+y = 12, so if x = 12, y =
0.
If y = 0, the condition x*y^2 is a maximum is impossible
because x*0 = 0 and 0 is not the root for p'(x) = 0.
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