How to Graph Transformations of Functions
Write the function given., Determine the basic function., Graph the basic graph., Determine the left/right shift., Include the left/right shift in the basic graph., Determine the left/right flip., Include the left/right flip in the graph., Determine...
Step-by-Step Guide
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Step 1: Write the function given.
Although it may seem silly, you always write out the function given so you can refer back to it. , The basic function is just the function in its natural state.
Its natural state is the function without any transformations.
The basic function of, f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, is just f(x)=x2{\displaystyle f(x)=x^{2}} The basic function of, f(x)=(−x+3)3−1{\displaystyle f(x)=(-x+3)^{3}-1}, is just f(x)=x3{\displaystyle f(x)=x^{3}} , By determining the basic function, you can graph the basic graph.
The basic graph is exactly what it sounds like, the graph of the basic function.
The basic graph can be looked at as the foundation for graphing the actual function.
The basic graph will be used to develop a sketch of the function with its transformations.
For the basic function, f(x)=x2{\displaystyle f(x)=x^{2}}, its basic graph is just a parabola. , The left/right shift determines whether the graph will shift to the right or left c units, where c is just used as a variable representing any number.
In a function where c is added to the variable of the function, meaning the function becomes f(x)=f(x+c){\displaystyle f(x)=f(x+c)}, the basic graph will shift to the left c units.
In a function where c is subtracted from the variable of the function, meaning the function becomes f(x)=f(x−c){\displaystyle f(x)=f(x-c)}, the basic graph will shift to the right c units.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the basic graph will shift to the right 2 units.
For the function f(x)=(−x+3)3−1{\displaystyle f(x)=(-x+3)^{3}-1}, the basic graph will shift to the left 3 units. , Now that you have determined the function left/right shift, you must redraw the basic graph including the left/right shift.
If your function is f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3} it has a right shift 2 units.
The redrawn basic graph will shift to the right 2 units If your function is f(x)=(−x+3)3−1{\displaystyle f(x)=(-x+3)^{3}-1} it has a left shift 3 units.
The redrawn basic graph will shift to the left 3 units. , The left/right flip determines if the graph will flip over the y-axis.
This flip means the original graph will be flipped the opposite direction across the y-axis, either to left or right.
If the variable of the function is multiplied by
-1, meaning the function becomes f(x)=f(−x){\displaystyle f(x)=f(-x)}, the basic graph will flip across the y-axis.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the basic graph will not flip across the y-axis because the variable of the function is not multiplied by
-1.
For the function f(x)=(−x+3)3−1{\displaystyle f(x)=(-x+3)^{3}-1}, the basic graph will flip across the y-axis because the variable of the function is multiplied by
-1. , Now that you have determined if the graph has a left/right flip, you must the flip to the basic graph including the left/right shift.
All this means is that graph of the basic graph will be redrawn with the left/right shift and left/right flip.
For the function f(x)=(−x+3)−1{\displaystyle f(x)=(-x+3)-1}, it will flip across the y-axis so the redrawn basic graph will now include the left shift 3 units as well as flip across the y-axis. , The up/down flip determines if the graph will be flipped across the x-axis.
This flip means that the original graph will flip the opposite direction across the x-axis, either up or down.
If the entire function is multiplied by
-1, meaning the function becomes f(x)=−f(x){\displaystyle f(x)=-f(x)}, the basic graph will flip across the x-axis.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, it will flip across the x-axis because the entire function is multiplied by
-1.
For the function f(x)=(x+3)3−1{\displaystyle f(x)=(x+3)^{3}-1} it will not flip across the x-axis because the entire function is not multiplied by
-1. , Now that you have determined if the function has an up/down flip, you must redraw the basic graph including the left/right shift, , if needed, the left/right flip, and up/down flip.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the redrawn basic graph will shift to the right 2 units and flip across the x-axis. , The up/down shift determines if the graph will be shifted up or down c units, where c is variable representing a number.
In a function where c is added to the entire function, meaning the function becomes f(x)=f(x)+c{\displaystyle f(x)=f(x)+c}, the basic graph will shift up c units.
In a function where c is subtracted from the entire function, meaning the function becomes f(x)=f(x)−c{\displaystyle f(x)=f(x)-c}, the basic graph will shift down c units.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the basic graph will shift up 3 units.
For the function f(x)=(x+3)3−1{\displaystyle f(x)=(x+3)^{3}-1}, the basic graph will shift down 1 unit. , Now that you have determined the up/down shift, you must redraw the basic graph include the left/right shift, left/right flip and/or up/down flip, and the up/down shift.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the redrawn basic graph will shift to the right 2 units, flip across the x-axis, and shift up 3 units.
For the function f(x)=(x+3)3−1{\displaystyle f(x)=(x+3)^{3}-1}, the redrawn basic graph will shift to the left 3 units, flip across the y-axis, and shift down 1 unit. , Now that you have a sketch of what the function looks like with its transformations, you must find where the function touches the x-axis or its x-intercept(s).
A x-intercept is just an ordered pair,(x,y), where y is always
0.
To find the x-intercepts, you set the entire function to zero and solve for x.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, let's find the x-intercepts: −(x−2)2+3=0{\displaystyle
-(x-2)^{2}+3=0} −(x−2)2=−3{\displaystyle
-(x-2)^{2}=-3} (x−2)2=3x−2=3{\displaystyle (x-2)^{2}=3x-2={\sqrt {3}}} x=−3+2{\displaystyle x=-{\sqrt {3}}+2} and x=3+2{\displaystyle x={\sqrt {3}}+2} so for the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, its x-intercepts are (3+2,0){\displaystyle ({\sqrt {3}}+2,0)} & (−3+2,0){\displaystyle (-{\sqrt {3}}+2,0)} , Now that you have found your functions x-intercept(s), you need to find where the function cross the y-axis or its y-intercept.
A y-intercept is just an ordered pair, (x,y){\displaystyle (x,y)}, where x is always
0.
To find a functions y-intercept, you set x=0 and find f(0){\displaystyle f(0)}.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, let's find its y-intercept: f(0)=−(0−2)2+3=−(−2)2+3=−4+3)=−1{\displaystyle f(0)=-(0-2)^{2}+3=-(-2)^{2}+3=-4+3)=-1} so the y-intercept is (0,−1){\displaystyle (0,-1)} , Now that you have a sketch of the functions graph and found the functions x-intercept(s) and y-intercept, your final step is to redraw the graph in step 11 including each x and y intercepts.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the graph of function shifts to the right 2 units, flips across the x-axis, shifts up 3 units, crosses the x-axis at (−3+2,0){\displaystyle (-{\sqrt {3}}+2,0)} & (3+2,0){\displaystyle ({\sqrt {3}}+2,0)}, and crosses the y-axis at (0,−1){\displaystyle (0,-1)}. -
Step 2: Determine the basic function.
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Step 3: Graph the basic graph.
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Step 4: Determine the left/right shift.
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Step 5: Include the left/right shift in the basic graph.
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Step 6: Determine the left/right flip.
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Step 7: Include the left/right flip in the graph.
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Step 8: Determine the up/down flip.
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Step 9: Include the up/down flip in the graph.
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Step 10: Determine the up/down shift.
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Step 11: Include the up/down shift in the graph.
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Step 12: Find the x-intercept(s).
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Step 13: Find the y-intercept.
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Step 14: Include the x and y intercepts in the graph.
Detailed Guide
Although it may seem silly, you always write out the function given so you can refer back to it. , The basic function is just the function in its natural state.
Its natural state is the function without any transformations.
The basic function of, f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, is just f(x)=x2{\displaystyle f(x)=x^{2}} The basic function of, f(x)=(−x+3)3−1{\displaystyle f(x)=(-x+3)^{3}-1}, is just f(x)=x3{\displaystyle f(x)=x^{3}} , By determining the basic function, you can graph the basic graph.
The basic graph is exactly what it sounds like, the graph of the basic function.
The basic graph can be looked at as the foundation for graphing the actual function.
The basic graph will be used to develop a sketch of the function with its transformations.
For the basic function, f(x)=x2{\displaystyle f(x)=x^{2}}, its basic graph is just a parabola. , The left/right shift determines whether the graph will shift to the right or left c units, where c is just used as a variable representing any number.
In a function where c is added to the variable of the function, meaning the function becomes f(x)=f(x+c){\displaystyle f(x)=f(x+c)}, the basic graph will shift to the left c units.
In a function where c is subtracted from the variable of the function, meaning the function becomes f(x)=f(x−c){\displaystyle f(x)=f(x-c)}, the basic graph will shift to the right c units.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the basic graph will shift to the right 2 units.
For the function f(x)=(−x+3)3−1{\displaystyle f(x)=(-x+3)^{3}-1}, the basic graph will shift to the left 3 units. , Now that you have determined the function left/right shift, you must redraw the basic graph including the left/right shift.
If your function is f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3} it has a right shift 2 units.
The redrawn basic graph will shift to the right 2 units If your function is f(x)=(−x+3)3−1{\displaystyle f(x)=(-x+3)^{3}-1} it has a left shift 3 units.
The redrawn basic graph will shift to the left 3 units. , The left/right flip determines if the graph will flip over the y-axis.
This flip means the original graph will be flipped the opposite direction across the y-axis, either to left or right.
If the variable of the function is multiplied by
-1, meaning the function becomes f(x)=f(−x){\displaystyle f(x)=f(-x)}, the basic graph will flip across the y-axis.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the basic graph will not flip across the y-axis because the variable of the function is not multiplied by
-1.
For the function f(x)=(−x+3)3−1{\displaystyle f(x)=(-x+3)^{3}-1}, the basic graph will flip across the y-axis because the variable of the function is multiplied by
-1. , Now that you have determined if the graph has a left/right flip, you must the flip to the basic graph including the left/right shift.
All this means is that graph of the basic graph will be redrawn with the left/right shift and left/right flip.
For the function f(x)=(−x+3)−1{\displaystyle f(x)=(-x+3)-1}, it will flip across the y-axis so the redrawn basic graph will now include the left shift 3 units as well as flip across the y-axis. , The up/down flip determines if the graph will be flipped across the x-axis.
This flip means that the original graph will flip the opposite direction across the x-axis, either up or down.
If the entire function is multiplied by
-1, meaning the function becomes f(x)=−f(x){\displaystyle f(x)=-f(x)}, the basic graph will flip across the x-axis.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, it will flip across the x-axis because the entire function is multiplied by
-1.
For the function f(x)=(x+3)3−1{\displaystyle f(x)=(x+3)^{3}-1} it will not flip across the x-axis because the entire function is not multiplied by
-1. , Now that you have determined if the function has an up/down flip, you must redraw the basic graph including the left/right shift, , if needed, the left/right flip, and up/down flip.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the redrawn basic graph will shift to the right 2 units and flip across the x-axis. , The up/down shift determines if the graph will be shifted up or down c units, where c is variable representing a number.
In a function where c is added to the entire function, meaning the function becomes f(x)=f(x)+c{\displaystyle f(x)=f(x)+c}, the basic graph will shift up c units.
In a function where c is subtracted from the entire function, meaning the function becomes f(x)=f(x)−c{\displaystyle f(x)=f(x)-c}, the basic graph will shift down c units.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the basic graph will shift up 3 units.
For the function f(x)=(x+3)3−1{\displaystyle f(x)=(x+3)^{3}-1}, the basic graph will shift down 1 unit. , Now that you have determined the up/down shift, you must redraw the basic graph include the left/right shift, left/right flip and/or up/down flip, and the up/down shift.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the redrawn basic graph will shift to the right 2 units, flip across the x-axis, and shift up 3 units.
For the function f(x)=(x+3)3−1{\displaystyle f(x)=(x+3)^{3}-1}, the redrawn basic graph will shift to the left 3 units, flip across the y-axis, and shift down 1 unit. , Now that you have a sketch of what the function looks like with its transformations, you must find where the function touches the x-axis or its x-intercept(s).
A x-intercept is just an ordered pair,(x,y), where y is always
0.
To find the x-intercepts, you set the entire function to zero and solve for x.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, let's find the x-intercepts: −(x−2)2+3=0{\displaystyle
-(x-2)^{2}+3=0} −(x−2)2=−3{\displaystyle
-(x-2)^{2}=-3} (x−2)2=3x−2=3{\displaystyle (x-2)^{2}=3x-2={\sqrt {3}}} x=−3+2{\displaystyle x=-{\sqrt {3}}+2} and x=3+2{\displaystyle x={\sqrt {3}}+2} so for the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, its x-intercepts are (3+2,0){\displaystyle ({\sqrt {3}}+2,0)} & (−3+2,0){\displaystyle (-{\sqrt {3}}+2,0)} , Now that you have found your functions x-intercept(s), you need to find where the function cross the y-axis or its y-intercept.
A y-intercept is just an ordered pair, (x,y){\displaystyle (x,y)}, where x is always
0.
To find a functions y-intercept, you set x=0 and find f(0){\displaystyle f(0)}.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, let's find its y-intercept: f(0)=−(0−2)2+3=−(−2)2+3=−4+3)=−1{\displaystyle f(0)=-(0-2)^{2}+3=-(-2)^{2}+3=-4+3)=-1} so the y-intercept is (0,−1){\displaystyle (0,-1)} , Now that you have a sketch of the functions graph and found the functions x-intercept(s) and y-intercept, your final step is to redraw the graph in step 11 including each x and y intercepts.
For the function f(x)=−(x−2)2+3{\displaystyle f(x)=-(x-2)^{2}+3}, the graph of function shifts to the right 2 units, flips across the x-axis, shifts up 3 units, crosses the x-axis at (−3+2,0){\displaystyle (-{\sqrt {3}}+2,0)} & (3+2,0){\displaystyle ({\sqrt {3}}+2,0)}, and crosses the y-axis at (0,−1){\displaystyle (0,-1)}.
About the Author
Hannah Burns
Specializes in breaking down complex practical skills topics into simple steps.
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