Inequalities
Sometimes we need to solve Inequalities like
these:
symbol
|
Words
|
Example
|
>
|
greater than
|
x + 3 > 2
|
<
|
less than
|
7x < 28
|
≥
|
greater than or equal to
|
5 ≥ x - 1
|
≤
|
less than or equal to
|
2y + 1 ≤ 7
|
Solving:
Our aim is
to have x (or whatever the variable
is) on its own on the left of the inequality sign:
Something
like:
|
x
< 5
|
|
or:
|
y
≥ 11
|
We call that "solved".
Solving inequalities is very like solving equations, we do most of the
same things, but we must also pay attention to the direction of the inequality.
Direction:
Which way the arrow "points"
Some things we do will change the direction!
< would become >
> would become <
≤ would become ≥
≥ would become ≤
Safe
Things to Do:
These are things we can do without
affecting the direction of the
inequality:
·
Add
(or subtract) a number from both sides
·
Multiply
(or divide) both sides by a positive number
·
Simplify
a side
Example:
3x < 7+3
We can simplify 7+3 without affecting the inequality:
3x
< 10
But these
things will change the direction of the inequality ("<"
becomes ">" for example):
Multiply (or divide) both sides by
a negative number
Swapping left and right hand sides.
Example:
2y+7 < 12
When we swap the left and right hand sides, we must
also change the direction of the inequality:
12 > 2y+7
Here
are the details:
Adding
or Subtracting a Value
We can often solve inequalities by adding (or
subtracting) a number from both sides (just as in Introduction
to Algebra), like this:
Solve: x
+ 3 < 7
If we subtract 3 from both sides, we get:
x + 3 - 3 < 7 - 3
x < 4
And that is our solution: x < 4
In other words, x can be any value less than
4.
What
did we do?
We went from this:
To this:
|
x+3 < 7
x < 4
|
What did we do?
We went from this:
To this:
|
 |
x+3 < 7
x < 4
|
||
And that works well for adding and subtracting,
because if we add (or subtract) the same amount from both sides, it does not
affect the inequality
Example:
Alex has more coins than Billy. If both Alex and Billy get three more coins
each, Alex will still have more coins than Billy.
What If I Solve It, but "x" Is On the Right?
No matter, just swap sides, but reverse the
sign so it still "points at" the correct value!
Example: 12
< x + 5
If we subtract 5 from both sides, we get:
12 - 5 < x + 5 -
5
7 < x
That
is a solution!
But it is normal to put "x" on the left hand
side, so let us flip sides (and the inequality sign!):
x
> 7
Do you see how the inequality sign still "points
at" the smaller value (7)?
And that is our solution: x > 7
Note: "x" can be on the
right, but people usually like to see it on the left hand side.
Multiplying
or Dividing by a Value
Another thing we do is multiply or divide both sides
by a value (just as in Algebra -
Multiplying).
But we need to be a bit more careful (as you will
see).
Positive Values
Everything is fine if we want to multiply or divide by
a positive number:
Solve: 3y < 15
If we divide both sides by 3 we get:
3y/3 <
15/3
y < 5
And
that is our solution: y < 5
Negative Values
When we multiply or divide by a negative number
we must reverse the inequality. |
Why?
Well, just look at the number line!
For example, from 3 to 7 is an increase,
but from -3 to -7 is a decrease.
but from -3 to -7 is a decrease.
See how the inequality sign reverses (from < to
>)?
Let
us try an example:
Solve: -2y
< -8
Let us divide both sides by -2, and reverse the inequality!
-2y < -8
-2y/-2 > -8/-2
y > 4
And
that is the correct solution: y > 4
(Note that I reversed the inequality on
the same line I divided by the negative number.)
So,
just remember:
When multiplying or dividing by a negative number, reverse the
inequality
Multiplying or Dividing by Variables
Here
is another (tricky!) example:
Solve: bx
< 3b
It seems easy just to divide both sides by b,
which would give us:
x < 3
but wait, if b is negative we need
to reverse the inequality like this:
x > 3
But we don't know if b is positive or negative, so we
can't answer this one!
To help you understand, imagine replacing b with 1 or -1 in
that example:
- if b is 1, then the answer is simply x < 3
- but if b is -1, then we would be solving -x < -3, and the answer would be x > 3
So:
Do not try dividing by a variable to
solve an inequality (unless you know the variable is always positive, or always
negative).
A
Bigger Example
Solve: (x-3)/2
< -5
First, let us clear out the "/2" by
multiplying both sides by 2.
Because we are multiplying by a positive number, the
inequalities will not change.
(x-3)/2 ×2 < -5 ×2
(x-3) < -10
Now
add 3 to both sides:
x-3 + 3 < -10 + 3
x < -7
And that is our solution: x < -7
Two
Inequalities at Once!
How do we solve something with two inequalities at
once?
Solve:
-2 < (6-2x)/3 < 4
First, let us clear out the "/3" by
multiplying each part by 3:
Because we are multiplying by a positive number, the
inequalities will not change.
-6 < 6-2x < 12
Now
subtract 6 from each part:
-12 < -2x < 6
Now multiply each part by -(1/2).
Because we are multiplying by a negative number,
the inequalities change direction.
6 > x > -3
And
that is the solution!
But to be neat it is better to have the smaller number
on the left, larger on the right. So let us swap them over (and make sure the
inequalities point correctly):
-3 < x < 6
QUESTIONS OF INEQUALITIES
Q1) Draw the following inequalities on graph paper.
a. y<2x+4
b. x+y ≥5
Q2) Solve the inequality.
4x+3>2(3x-1)
Q3) List the positive integers greater
than 10 which satisfy the following inequality.
5a-40≤2a+1
Q4) a,b,c integers
-a<a≤1
-6.7<b≤5
-5≤c<-2.8
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