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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root To find your restrictions apply the composite rule, then : a) set the expression in the denominator ≠ 0 and solve for x - your domain will be all real numbers EXCEPT the restriction b) set the expression under the root < 0 and solve for x - your domain will the result where x ≥ OR x ≤ the restriction
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( ƒ ◦ g )(x) if ƒ(x) = and g (x) = 2x
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( ƒ ◦ g )(x) if ƒ(x) = and g (x) = 2x The domain of g(x) is all real numbers, but f(x) has a denominator. So ( x – 2 ) ≠ 0
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( ƒ ◦ g )(x) if ƒ(x) = and g (x) = 2x The domain of g(x) is all real numbers, but f(x) has a denominator. So ( x – 2 ) ≠ 0 Using the composite rule, replace 2x into f(x) for ‘x’
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( ƒ ◦ g )(x) if ƒ(x) = and g (x) = 2x The domain of g(x) is all real numbers, but f(x) has a denominator. So ( x – 2 ) ≠ 0 Using the composite rule, replace 2x into f(x) for ‘x’ 2x – 2 ≠ 0
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( ƒ ◦ g )(x) if ƒ(x) = and g (x) = 2x The domain of g(x) is all real numbers, but f(x) has a denominator. So ( x – 2 ) ≠ 0 Using the composite rule, replace 2x into f(x) for ‘x’ 2x – 2 ≠ 0 Now solve for x
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( ƒ ◦ g )(x) if ƒ(x) = and g (x) = 2x The domain of g(x) is all real numbers, but f(x) has a denominator. So ( x – 2 ) ≠ 0 Using the composite rule, replace 2x into f(x) for ‘x’ 2x – 2 ≠ 0 2x ≠ 2 x ≠ 1 Now solve for x Here is the restriction on the domain of ( ƒ ◦ g )(x)
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( ƒ ◦ g )(x) if ƒ(x) = and g (x) = 2x The domain ( ƒ ◦ g )(x) is all Real Numbers except 1. Because which is undefined
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( g ◦ ƒ )(x) if ƒ(x) = 3 – x, and g (x) = The domain of f(x) is all real numbers, but g(x) is a square root.
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( g ◦ ƒ )(x) if ƒ(x) = 3 – x, and g (x) = The domain of f(x) is all real numbers, but g(x) is a square root. Apply the composite rule ( g ◦ ƒ )(x) = g [ f (x) ] =
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( g ◦ ƒ )(x) if ƒ(x) = 3 – x, and g (x) = The domain of f(x) is all real numbers, but g(x) is a square root. Apply the composite rule ( g ◦ ƒ )(x) = g [ f (x) ] =
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( g ◦ ƒ )(x) if ƒ(x) = 3 – x, and g (x) = The domain of f(x) is all real numbers, but g(x) is a square root. Apply the composite rule ( g ◦ ƒ )(x) = g [ f (x) ] = – 2x +1 ½ – 2x < – 1
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( g ◦ ƒ )(x) if ƒ(x) = 3 – x, and g (x) = The domain of f(x) is all real numbers, but g(x) is a square root. Apply the composite rule ( g ◦ ƒ )(x) = g [ f (x) ] = – 2x +1 ½ – 2x < – 1 Any x bigger than ½ creates a negative under the square root…
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Find the domain of ( g ◦ ƒ )(x) if ƒ(x) = 3 – x, and g (x) = Therefore the domain of ( g ◦ ƒ )(x) all real numbers where x ≤ ½
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Let ƒ(x) = and g (x) = x + 4. What is the smallest value in the domain of (ƒ ◦ g )(x) ?
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Let ƒ(x) = and g (x) = x + 4. What is the smallest value in the domain of (ƒ ◦ g )(x) ?
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Let ƒ(x) = and g (x) = x + 4. What is the smallest value in the domain of (ƒ ◦ g )(x) ? Set 6x + 24 ≥ 0 and solve for x
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Let ƒ(x) = and g (x) = x + 4. What is the smallest value in the domain of (ƒ ◦ g )(x) ? Set 6x + 24 ≥ 0 and solve for x
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Let ƒ(x) = and g (x) = x + 4. What is the smallest value in the domain of (ƒ ◦ g )(x) ? So (– 4) is the smallest number in the domain of (ƒ ◦ g )(x)
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Let ƒ(x) = and g (x) = What two numbers ARE NOT in the domain of (ƒ ◦ g )(x) ?
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Let ƒ(x) = and g (x) = What two numbers ARE NOT in the domain of (ƒ ◦ g )(x) ? Set and solve for x
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FUNCTIONS : Domain values When combining functions using the composite rules, it is necessary to check the domain for values that could be restricted. Rules :a) you CAN NOT have a zero in the denominator b) you CAN NOT have a negative under an even index / root EXAMPLE : Let ƒ(x) = and g (x) = What two numbers ARE NOT in the domain of (ƒ ◦ g )(x) ? Set and solve for x These two create zero in the denominator…
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