Derivative, Maximum, Minimum of Quadratic Functions

Differentiation is used to analyze the properties such as intervals of increase, decrease, local maximum, local minimum of quadratic functions.

A - Quadratic Function in General form

Quadratic functions in their general form are written as

f (x) = a x^{2} + b x + c

where $a$ , $b$ , and $c$ are real numbers such that $a \neq 0$ .

The first derivative of $f$ is given by

f^{'} (x) = 2 a x + b

Let us analyze the sign of $f^{'}$ and hence determine any maximum or minimum point and the intervals of increase and decrease. $f^{'} (x)$ is positive if

2 a x + b > 0

which may be written as

2 a x > - b

We now need to consider two cases and continue solving the inequality above.

case 1: coefficient $a > 0$

We divide both sides of the inequality by $2 a$ and solve it to obtain

x > - \frac{b}{2 a}

We now use a table to analyze the sign of $f^{'}$ and whether $f$ is increasing over a given interval.

$table of sign for $a > 0$$

The quadratic function with $a > 0$ has a minimum point at $(- b / 2 a, f (- b / 2 a))$ and the function is decreasing on the interval $(- \infty, - b / 2 a)$ and increasing over the interval $(- b / 2 a, + \infty)$ .

case 2: coefficient $a < 0$

We divide both sides of the inequality by $2 a$ but because $a$ is less than 0, we need to change the symbol of inequality

x < - \frac{b}{2 a}

We now analyze the sign of $f^{'}$ using the table below

$table of sign for $a < 0$$

The quadratic function with $a < 0$ has a maximum point at $(- b / 2 a, f (- b / 2 a))$ and the function is increasing on the interval $(- \infty, - b / 2 a)$ and decreasing over the interval $(- b / 2 a, + \infty)$ .

B - Quadratic Function in Vertex form

Quadratic functions in their vertex form are written as

f (x) = a (x - h)^{2} + k

where $a$ , $h$ , and $k$ are real numbers with $a \neq 0$ .

The first derivative of $f$ is given by

f^{'} (x) = 2 a (x - h)

We analyze the sign of $f^{'}$ using a table. $f^{'} (x)$ is positive if

a (x - h) > 0

We need to consider two cases again and continue solving the inequality above.

case 1: coefficient $a > 0$

We divide both sides of the inequality by $a$ and solve the inequality

x > h

The table below is used to analyze the sign of $f^{'}$ .

$table of sign for $a > 0$, vertex form$

The quadratic function with $a > 0$ has a minimum at the point $(h, k)$ and it is decreasing on the interval $(- \infty, h)$ and increasing over the interval $(h, + \infty)$ .

case 2: coefficient $a < 0$

We divide both sides of the inequality by $a$ but we need to change the symbol of inequality because $a$ is less than 0.

x < h

We analyze the sign of $f^{'}$ using the table below

$table of sign for $a < 0$, vertex form$

The quadratic function with $a < 0$ has a maximum point at $(h, k)$ and the function is increasing on the interval $(- \infty, h)$ and decreasing over the interval $(h, + \infty)$ .

Example 1

Find the extremum (minimum or maximum) of the quadratic function $f$ given by

f (x) = 2 x^{2} - 8 x + 1

Solution to Example 1

We first find the derivative
$f^{'} (x) = 4 x - 8$
$f^{'} (x)$ changes sign at $x = \frac{8}{4} = 2$ . The leading coefficient $a$ is positive hence $f$ has a minimum at $(2, f (2)) = (2, - 7)$ and $f$ is decreasing on $(- \infty, 2)$ and increasing on $(2, + \infty)$ . See graph below to confirm the result obtained by calculations.

Example 2

Find the extremum (minimum or maximum) of the quadratic function $f$ given by

f (x) = - (x + 3)^{2} + 1

Solution to Example 2

The derivative is given by
$f^{'} (x) = - 2 (x + 3)$
$f^{'} (x)$ changes sign at $x = - 3$ . The leading coefficient $a$ is negative hence $f$ has a maximum at $(- 3, 1)$ and $f$ is increasing on $(- \infty, - 3)$ and decreasing on $(- 3, + \infty)$ . See graph below of $f$ below.

Exercises on Properties of Quadratic Functions

For each quadratic function below find the extremum (minimum or maximum), the interval of increase and the interval of decrease.

a) $f (x) = x^{2} + 6 x$
b) $f (x) = - x^{2} - 2 x + 3$
c) $f (x) = x^{2} - 5$
d) $f (x) = - (x - 4)^{2} + 2$
e) $f (x) = - x^{2}$

Answers to Above Exercises

a) minimum at the point

(- 3, - 9)

decreasing on

(- \infty, - 3)

increasing on

(- 3, + \infty)

b) maximum at at the point

(- 1, 4)

increasing on the interval

(- \infty, - 1)

decreasing on the interval

(- 1, + \infty)

c) minimum at at the point

(0, - 5)

decreasing on the interval

(- \infty, 0)

increasing on the interval

(0, + \infty)

d) maximum at

(4, 2)

increasing on the interval

(- \infty, 4)

decreasing on the interval

(4, + \infty)

e) maximum at

(0, 0)

increasing on the interval

(- \infty, 0)

decreasing on the interval

(0, + \infty)

More on applications of differentiation

applications of differentiation

Derivative, Maximum, Minimum of Quadratic Functions

A - Quadratic Function in General form

case 1: coefficient a>0

case 2: coefficient a<0

B - Quadratic Function in Vertex form

case 1: coefficient a>0

case 2: coefficient a<0

Example 1

Solution to Example 1

Example 2

Solution to Example 2

Exercises on Properties of Quadratic Functions

Answers to Above Exercises

More on applications of differentiation

case 1: coefficient $a > 0$

case 2: coefficient $a < 0$

case 1: coefficient $a > 0$

case 2: coefficient $a < 0$