When we reduce a common fraction such as
_{}
we do so by noticing that there is a factor common to both the numerator and the denominator (a factor of 2 in this example), which we can divide out of both the numerator and the denominator.
_{}
We use exactly the same procedure to reduce rational expressions.
_{}
Each term in the numerator must have a factor that cancels a common factor in the denominator.
_{},
but
_{}
cannot be reduced because the 2 is not a common factor of the entire numerator.
WARNING You can only cancel a factor of the entire numerator with a factor of the entire denominator
However, as an alternative, a fraction with more than one term in the numerator can be split up into separate fractions with each term over the same denominator; then each separate fraction can be reduced if possible: _{} · Think of this as the reverse of adding fractions over a common denominator. Sometimes this is a useful thing to do, depending on the circumstances. You end up with simpler fractions, but the price you pay is that you have more fractions than you started with. |
· Polynomials must be factored first. You can’t cancel factors unless you can see the factors:
Example:
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· Notice how canceling the (x – 2) from the denominator left behind a factor of 1
Same rules as for rational numbers!
Example:
Given Equation: |
_{} |
First factor all the expressions: |
_{} |
Now cancel common factors—any factor on the top can cancel with any factor on the bottom: |
_{} _{} _{} |
Now just multiply what’s left. |
_{} |
Same procedure as for rational numbers!
· Only the numerators can add together, once all the denominators are the same
Example:
Given equation: |
_{} |
Factor both denominators: |
_{} |
Assemble the LCD: |
_{} _{} _{} |
Build up the fractions so that they
both have the LCD for a denominator: |
_{} _{} |
Now that they are over the same denominator, you can add the numerators: |
_{} |
And simplify: |
_{} _{} |