The Function $ F(x) = 5 \sqrt X+9} + 1 \quad \text{for } X \geq -9 $ Has An Inverse $ F^{-1}(x) $ Defined On The Domain $ X \geq 1 $. Find The Inverse.Provide Your Answer Below $ F^{-1 (x) = \square $

Understanding the Function

The given function is $ f(x) = 5 \sqrt{x+9} + 1 \quad \text{for } x \geq -9 $. This function involves a square root, which indicates that it is a non-linear function. The domain of the function is restricted to $ x \geq -9 $, which means that the function is only defined for values of $ x $ greater than or equal to $ -9 $.

The Concept of an Inverse Function

An inverse function is a function that reverses the operation of another function. In other words, if we have a function $ f(x) $, then its inverse function $ f^{-1}(x) $ will take the output of $ f(x) $ and return the original input. The inverse function is denoted by $ f^{-1}(x) $.

Finding the Inverse Function

To find the inverse function of $ f(x) = 5 \sqrt{x+9} + 1 $, we need to follow a series of steps. The first step is to replace $ f(x) $ with $ y $, which gives us $ y = 5 \sqrt{x+9} + 1 $. The next step is to interchange the roles of $ x $ and $ y $, which gives us $ x = 5 \sqrt{y+9} + 1 $. Now, we need to solve this equation for $ y $.

Solving for $ y $

To solve for $ y $, we need to isolate $ y $ on one side of the equation. The first step is to subtract 1 from both sides of the equation, which gives us $ x - 1 = 5 \sqrt{y+9} $. The next step is to divide both sides of the equation by 5, which gives us $ \frac{x-1}{5} = \sqrt{y+9} $. Now, we need to square both sides of the equation to get rid of the square root.

Squaring Both Sides

Squaring both sides of the equation gives us $ \left( \frac{x-1}{5} \right)^2 = y+9 $. The next step is to simplify the left-hand side of the equation by expanding the square. This gives us $ \frac{x^2-2x+1}{25} = y+9 $. Now, we need to isolate $ y $ on one side of the equation.

Isolating $ y $

To isolate $ y $, we need to subtract 9 from both sides of the equation, which gives us $ \frac{x^2-2x+1}{25} - 9 = y $. The next step is to simplify the left-hand side of the equation by combining the fractions. This gives us $ \frac{x^2-2x+1-225}{25} = y $. Now, we need to simplify the numerator of the fraction.

Simplifying the Numerator

Simplifying the numerator of the fraction gives us $ \frac{x^2-2x-224}{25} = y $. The next step is to simplify the fraction by dividing the numerator and denominator by their greatest common divisor. This gives us $ \frac{(x-16)(x+14)}{25} = y $. Now, we need to isolate $ y $ on one side of the equation.

Isolating $ y $

To isolate $ y $, we need to multiply both sides of the equation by 25, which gives us $ (x-16)(x+14) = 25y $. The next step is to divide both sides of the equation by 25, which gives us $ y = \frac{(x-16)(x+14)}{25} $. This is the inverse function of $ f(x) = 5 \sqrt{x+9} + 1 $.

Conclusion

In this article, we have found the inverse function of $ f(x) = 5 \sqrt{x+9} + 1 $, which is $ f^{-1}(x) = \frac{(x-16)(x+14)}{25} $. The inverse function is defined on the domain $ x \geq 1 $, which is the range of the original function. The inverse function is a useful tool for solving equations and graphing functions.

Inverse Function Formula

• $ f^{-1}(x) = \frac{(x-16)(x+14)}{25} $
  Q&A: Inverse Functions ==========================

Frequently Asked Questions

In this article, we will answer some of the most frequently asked questions about inverse functions.

Q: What is an inverse function?

A: An inverse function is a function that reverses the operation of another function. In other words, if we have a function $ f(x) $, then its inverse function $ f^{-1}(x) $ will take the output of $ f(x) $ and return the original input.

Q: How do I find the inverse function of a given function?

A: To find the inverse function of a given function, you need to follow a series of steps. The first step is to replace the function with $ y $, which gives us $ y = f(x) $. The next step is to interchange the roles of $ x $ and $ y $, which gives us $ x = f(y) $. Now, you need to solve this equation for $ y $.

Q: What is the domain of an inverse function?

A: The domain of an inverse function is the range of the original function. In other words, if the original function is defined on the domain $ x \geq a $, then the inverse function is defined on the domain $ x \geq f(a) $.

Q: What is the range of an inverse function?

A: The range of an inverse function is the domain of the original function. In other words, if the original function is defined on the domain $ x \geq a $, then the inverse function is defined on the range $ x \geq f(a) $.

Q: How do I graph an inverse function?

A: To graph an inverse function, you need to reflect the graph of the original function about the line $ y = x $. This will give you the graph of the inverse function.

Q: What are some common mistakes to avoid when finding the inverse function of a given function?

A: Some common mistakes to avoid when finding the inverse function of a given function include:

• Not following the steps correctly
• Not interchanging the roles of $ x $ and $ y $
• Not solving the equation for $ y $
• Not checking the domain and range of the inverse function

Q: What are some real-world applications of inverse functions?

A: Some real-world applications of inverse functions include:

• Solving equations
• Graphing functions
• Modeling real-world phenomena
• Finding the inverse of a matrix

Q: How do I use inverse functions in real-world problems?

A: To use inverse functions in real-world problems, you need to follow these steps:

1. Identify the problem and the function involved
2. Find the inverse function of the given function
3. Use the inverse function to solve the problem

Q: What are some common types of inverse functions?

A: Some common types of inverse functions include:

• Inverse trigonometric functions
• Inverse exponential functions
• Inverse logarithmic functions
• Inverse polynomial functions

Q: How do I find the inverse of a trigonometric function?

A: To find the inverse of a trigonometric function, you need to follow these steps:

1. Replace the function with $ y $
2. Interchange the roles of $ x $ and $ y $
3. Solve the equation for $ y $

Q: What are some common mistakes to avoid when finding the inverse of a trigonometric function?

A: Some common mistakes to avoid when finding the inverse of a trigonometric function include:

• Not following the steps correctly
• Not interchanging the roles of $ x $ and $ y $
• Not solving the equation for $ y $
• Not checking the domain and range of the inverse function

Q: How do I use inverse functions to solve equations?

A: To use inverse functions to solve equations, you need to follow these steps:

1. Identify the equation and the function involved
2. Find the inverse function of the given function
3. Use the inverse function to solve the equation

Q: What are some common types of equations that can be solved using inverse functions?

A: Some common types of equations that can be solved using inverse functions include:

• Linear equations
• Quadratic equations
• Polynomial equations
• Trigonometric equations

Q: How do I use inverse functions to graph functions?

A: To use inverse functions to graph functions, you need to follow these steps:

1. Identify the function and its inverse
2. Graph the function and its inverse
3. Reflect the graph of the function about the line $ y = x $ to get the graph of the inverse function

Q: What are some common types of functions that can be graphed using inverse functions?

A: Some common types of functions that can be graphed using inverse functions include:

• Linear functions
• Quadratic functions
• Polynomial functions
• Trigonometric functions

Q: How do I use inverse functions to model real-world phenomena?

A: To use inverse functions to model real-world phenomena, you need to follow these steps:

1. Identify the phenomenon and the function involved
2. Find the inverse function of the given function
3. Use the inverse function to model the phenomenon

Q: What are some common types of real-world phenomena that can be modeled using inverse functions?

A: Some common types of real-world phenomena that can be modeled using inverse functions include:

• Population growth
• Chemical reactions
• Electrical circuits
• Optics

Q: How do I use inverse functions to find the inverse of a matrix?

A: To use inverse functions to find the inverse of a matrix, you need to follow these steps:

1. Identify the matrix and its inverse
2. Find the inverse of the matrix using the formula $ A^{-1} = \frac{1}{\det(A)} \cdot \text{adj}(A) $
3. Use the inverse of the matrix to solve the problem

Q: What are some common types of matrices that can be inverted using inverse functions?

A: Some common types of matrices that can be inverted using inverse functions include:

• Square matrices
• Invertible matrices
• Diagonal matrices
• Triangular matrices

Q: How do I use inverse functions to solve systems of equations?

A: To use inverse functions to solve systems of equations, you need to follow these steps:

1. Identify the system of equations and the function involved
2. Find the inverse function of the given function
3. Use the inverse function to solve the system of equations

Q: What are some common types of systems of equations that can be solved using inverse functions?

A: Some common types of systems of equations that can be solved using inverse functions include:

• Linear systems of equations
• Quadratic systems of equations
• Polynomial systems of equations
• Trigonometric systems of equations

Q: How do I use inverse functions to find the solution to a system of equations?

A: To use inverse functions to find the solution to a system of equations, you need to follow these steps:

1. Identify the system of equations and the function involved
2. Find the inverse function of the given function
3. Use the inverse function to find the solution to the system of equations

Q: What are some common types of solutions that can be found using inverse functions?

A: Some common types of solutions that can be found using inverse functions include:

• Unique solutions
• Multiple solutions
• No solutions
• Infinite solutions

Q: How do I use inverse functions to graph a system of equations?

A: To use inverse functions to graph a system of equations, you need to follow these steps:

1. Identify the system of equations and the function involved
2. Find the inverse function of the given function
3. Use the inverse function to graph the system of equations

Q: What are some common types of graphs that can be created using inverse functions?

A: Some common types of graphs that can be created using inverse functions include:

• Linear graphs
• Quadratic graphs
• Polynomial graphs
• Trigonometric graphs

Q: How do I use inverse functions to model a system of equations?

A: To use inverse functions to model a system of equations, you need to follow these steps:

1. Identify the system of equations and the function involved
2. Find the inverse function of the given function
3. Use the inverse function to model the system of equations

Q: What are some common types of systems of equations that can be modeled using inverse functions?

A: Some common types of systems of equations that can be modeled using inverse functions include:

• Linear systems of equations
• Quadratic systems of equations
• Polynomial systems of equations
• Trigonometric systems of equations

Q: How do I use inverse functions to find the solution to a system of equations in three variables?

A: To use inverse functions to find the solution to a system of equations in three variables, you need to follow these steps:

1. Identify the system of equations and the function involved
2. Find the inverse function of the given function
3. Use the inverse function to find the solution to the system of equations

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