Functions: Fractional functions
Inverse of linear fractional function
We have seen that determining the inverse function is the same as isolating the variable #x# in a formula of the form #y=\ldots#. Now we will investigate how to do that for linear fractional functions.
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Procedure We determine the inverse function of the linear fractional function #\green{y}=\frac{a\blue{x}+b}{c\blue{x}+d}# with #a#, #b#, #c# and #d# as numbers. |
Example #\green{y}=\frac{2\blue{x}-5}{3\blue{x}+2}# |
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| Step 1 | Multiply by the denominator of the fraction: #c\blue{x}+d#. | #\green{y} \left(3\blue{x}+2\right)=2\blue{x}-5# |
| Step 2 | Expand the brackets. | #3\blue{x}\green{y}+2 \green{y}=2\blue{x}-5# |
| Step 3 | By means of reduction move the terms without #x# to the right and the terms with a #x# to the left hand side. | #3\blue{x}\green{y}-2\blue{x}=-2 \green{y}-5# |
| Step 4 | Move #x# outside brackets. | #\blue x \left(3 \green{y}-2\right)=-2 \green{y}-5# |
| Step 5 | Divide by what's in between the brackets, so that we only have #x# at the left hand side. | #\blue x=\frac{-2 \green{y}-5}{3 \green{y}-2}# |
| Step 6 |
Swap the #\blue x# into a #\green y# and the #\green y# into a #\blue x# to get the inverse function. |
#\green y=\frac{-2 \blue{x}-5}{3 \blue{x}-2}# |
Isolate #x# in
\[y={{4\cdot x+2}\over{3\cdot x+6}}\]
\[y={{4\cdot x+2}\over{3\cdot x+6}}\]
#x={{2-6\cdot y}\over{3\cdot y-4}}#
#\begin{array}{rcl}
y&=&{{4\cdot x+2}\over{3\cdot x+6}} \\ &&\phantom{xxx}\blue{\text{the original function }}\\
y \cdot \left(3\cdot x+6\right)&=& 4\cdot x+2 \\ &&\phantom{xxx}\blue{\text{both sides divided by }3\cdot x+6}\\
3\cdot y\cdot x+6\cdot y&=&4\cdot x+2 \\ &&\phantom{xxx}\blue{\text{brackets expanded}}\\
3\cdot y\cdot x-4\cdot x &=&2-6\cdot y \\&&\phantom{xxx}\blue{\text{terms with } x \text{ to the left hand side, terms without }x \text{ to the right hand side }}\\
\left(3\cdot y-4\right)\cdot x &=& 2-6\cdot y \\ &&\phantom{xxx}\blue{x \text{ moved outside brackets}}\\
x&=&{{2-6\cdot y}\over{3\cdot y-4}} \\ &&\phantom{xxx}\blue{\text{divided by }3\cdot y-4}\\
\end{array}#
#\begin{array}{rcl}
y&=&{{4\cdot x+2}\over{3\cdot x+6}} \\ &&\phantom{xxx}\blue{\text{the original function }}\\
y \cdot \left(3\cdot x+6\right)&=& 4\cdot x+2 \\ &&\phantom{xxx}\blue{\text{both sides divided by }3\cdot x+6}\\
3\cdot y\cdot x+6\cdot y&=&4\cdot x+2 \\ &&\phantom{xxx}\blue{\text{brackets expanded}}\\
3\cdot y\cdot x-4\cdot x &=&2-6\cdot y \\&&\phantom{xxx}\blue{\text{terms with } x \text{ to the left hand side, terms without }x \text{ to the right hand side }}\\
\left(3\cdot y-4\right)\cdot x &=& 2-6\cdot y \\ &&\phantom{xxx}\blue{x \text{ moved outside brackets}}\\
x&=&{{2-6\cdot y}\over{3\cdot y-4}} \\ &&\phantom{xxx}\blue{\text{divided by }3\cdot y-4}\\
\end{array}#
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