Understanding Inverse Images and Continuity in Real Analysis

In summary, the conversation discusses the relationship between the inverse image of a function and its continuity. Part a) shows that for any set S of real numbers, the complement of f^-1(S) is equal to f^-1(S complement). This can be used to prove that a function f is continuous if and only if its inverse image of any closed set S is also closed. The definition of inverse image is given as {x: f(x) is in S}, and the definition of continuity is briefly mentioned as requiring f^-1(U) to be open for every open set U in the reals. The speaker suggests using the fact shown in part a) to prove the statement for part b) by showing f^-1(S^
  • #1
im2fastfouru
6
0
1. a) Show that (f^-1 S)compliment = f^-1(S compliment) for any set S of reals.


Then use part a) to show The function f is continuous iff f^-1(S) is closed for every closed set S.



2. inverse image = f^-1(S) = {x: f(x) [tex]\in[/tex] S}
f is continuous iff for every open set U [tex]\in[/tex] the reals, f^-1(U) is open.
 
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  • #2
part a is true for any set, so you need to show f^-1(S^c) = (f^-1(S))^c,

so take x in f^-1(S^c), so f(x) is in S^c, so f(x) is not in S, so ...

for part b, what have you tried and what is your definition of continuous, delta/epsilon?
 

What is an inverse image?

An inverse image is a mathematical concept that refers to the set of all input values of a function that produce a specific output value. It is also known as the preimage or the preimage set.

How do you find the inverse image of a function?

To find the inverse image of a function, you need to first determine the output value that you are interested in. Then, you need to solve the function for all possible input values that produce that output. The set of all these input values is the inverse image.

What is the difference between inverse image and inverse function?

Inverse image and inverse function are related concepts, but they are not the same. Inverse image refers to the set of input values that produce a specific output value, while inverse function refers to the function that reverses the input-output relationship of the original function.

Why is continuity important in inverse image?

Continuity is important in inverse image because it ensures that the function has an inverse. If a function is not continuous, it may not have a well-defined inverse image or inverse function.

How is inverse image used in real life?

Inverse image is used in many real-life applications, such as in computer graphics, data compression, and cryptography. It is also used in physics and engineering to find the input values that produce a desired output in a system or process.

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