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Section 5.3 Inverse Functions. Recall the following definition regarding inverse functions: Functions f and g are inverses of each other if and only if.

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Presentation on theme: "Section 5.3 Inverse Functions. Recall the following definition regarding inverse functions: Functions f and g are inverses of each other if and only if."— Presentation transcript:

1 Section 5.3 Inverse Functions

2 Recall the following definition regarding inverse functions: Functions f and g are inverses of each other if and only if and for all x in the domains of the individual functions. Additionally, the graphs of functions f and g are reflections of each other over the line y = x

3 Section 5.3 Inverse Functions How can we determine whether a function has an inverse? A function has an inverse which is a function only if it is a one-to-one function. Functions are one-to-one if and only if for each x there is only one y (the definition of a function) AND for each y there is only one x.

4 Section 5.3 Inverse Functions If we don’t have a complete graph, how can we tell if it is one-to-one? Well, Calculus can help. A graph can only be one-to-one if it never changes direction. This can only happen when there are no relative Max or min for the function, which we can determine through the use of a sign chart. In those cases we say that the function is strictly monotonic.

5 Section 5.3 Inverse Functions For each of the following functions, determine whether the function has an inverse. If it does, try to find that inverse:

6 Section 5.3 Inverse Functions The examples on the previous slide point out a couple of important facts about the study of inverse functions;  Most functions do not have inverses that are functions  Even when a function has an inverse function, it is a difficult task to solve for the inverse in our typical function notation

7 Section 5.3 Inverse Functions There is an interesting relationship between the derivative of a function and the derivative of the inverse of the function. The key idea to this relationship is to remind yourself that whenever the point (a,b) lies on the graph of a function, the point (b,a) is a point on the graph of the inverse. It stands to reason, then, that there should be a relationship between the derivative of f at a and the derivative of the inverse of f at b.

8 Section 5.3 Inverse Functions What is this relationship? We can describe it most clearly with the following definition: Let f be a differentiable function that has an inverse function g, then the following equation holds true:

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