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Absolute value
equations, quadratic
equations and functions |
Solving quadratic
equations with absolute value |
Graphing absolute value
functions or equations, examples |
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Quadratic
equations with absolute value |
Graphical
interpretation of the
definition of the
absolute value of a function y =
f (x) will help us solve
an equation with absolute value. |
The
definition for the absolute value of a function is given by |
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Thus,
for
values of x
for which f (x)
is nonnegative ( >
0 ), the graph of | f
(x)| is the
same as that of f
(x).
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For values of
x
for which f (x)
is negative ( <
0 ), the graph of | f
(x)
| is a reflection of
the graph of f (x)
on the x
axis. That
is, the
graph of y = -
f (x) is obtained by reflecting the graph
of y = f
(x)
across the x-axis. |
Hence,
the graph of the absolute value of
the function
y =
x,
i.e.,
| x | is |
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Example:
Solve the absolute value
equation
| x2
-
3 | =
-
x + 3. |
Solution:
Using the definition of the
absolute value of a function we can write, |
if
x2
-
3 > 0
then |
x2 -
3 | =
x2 -
3, |
and
given equation x2
-
3 =
-
x + 3
or |
x2
+ x -
6 =
0.
By
factoring the equation, |
x2 +
3x
-
2
x -
6 =
[x(x + 3) -
2(x + 3)] |
x2
+ x -
6 =
(x + 3)(x -
2) =
0 |
so,
x
+ 3 =
0,
x1
= -
3
and x
-
2 =
0,
x2
= 2. |
If
x2
-
3 < 0 then |
x2 -
3 | =
-
(x2
-
3), |
and
given equation -
(
x2 -
3) =
-
x + 3
or |
-
x2
+
x =
x(-
x + 1) =
0 |
so,
x3
= 0
and -
x + 1 =
0,
x4
= 1. |
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Therefore,
the solutions of the given equation, x1
= -
3, x2
= 2,
x3
= 0
and x4
= 1 are the abscissas of the
intersection points of, y = |
x2 -
3 | and y = -
x + 3
functions, as is shown in the above figure. |
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Example:
Solve the absolute value
equation
| 2x2
-
x -
3 | = -
x + 5. |
Solution:
Using the definition of the
absolute value of a function we can write, |
if
2x2
-
x -
3 > 0 |
then
|
2
x2
-
x -
3 | =
2
x2
-
x -
3, |
and
given equation 2
x2
-
x -
3 =
-
x + 5 |
or 2x2
=
8,
x2
=
4, |
so,
x1,2
= ±
2,
x1
= -
2
and x2
= 2. |
if
2
x2
-
x -
3 < 0 |
then
|
2x2
-
x -
3 | =
-
(2x2
-
x -
3), |
and
given equation -
(2
x2
-
x -
3) =
-
x + 5, |
-
2x2
+
2x
-
2
= 0
or x2
-
x + 1
= 0, |
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thus,
there are no real solutions in this case. |
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Therefore,
the solutions of the given equation, x1
= -
2 and x2
= 2 are the abscissas of the
intersection points of, y = |
2
x2
-
x -
3 | and y = -
x + 5
functions, as is shown in the above figure. |
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Functions
contents A |
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