Show that the function f is bijection

In summary, the function f(x,y) = 2^(x - 1) * (2y - 1) is both one-to-one and onto. To prove one-to-one, it is suggested to show that the inverse exists everywhere in the domain, which can be done by showing this property over the positive reals. For the inverse to exist, the derivative must be defined across the interval.
  • #1
zodiacbrave
11
0
a function f, that maps from the Cartesian Product of the positive integers to the positive integers. where
f(x,y) = 2^(x - 1) * (2y - 1).

I have to show that this function is both one-to-one and onto. I started trying to prove that it is onto, showing that there exists an n such that f(n,0) = n but I am not sure where to go from here.

Thank you
 
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  • #2
Hey zodiacbrave and welcome to the forum.

For one-to-one, one suggestion I have is to show that the inverse exists everywhere in the respective domain.

By showing that the inverse exists everywhere in the domain, you have basically shown the one-to-one property.

Even though we are only dealing with integers, if you show this property over the positive reals, then it automatically applies for the positive integers (think of it in terms of subsets).

Hint: What do we need for the derivative to be when an inverse function exists across an interval?
 

Related to Show that the function f is bijection

1. What is a bijection?

A bijection is a type of function that has a one-to-one and onto relationship between two sets. This means that for every element in the first set, there is a unique element in the second set, and vice versa.

2. How do you prove that a function is a bijection?

To prove that a function is a bijection, you need to show that it is both injective and surjective. This means that the function has a one-to-one correspondence between its domain and range, and that every element in the range is mapped to by at least one element in the domain.

3. What is the difference between a bijection and other types of functions?

A bijection is different from other types of functions, such as injections and surjections, because it has both one-to-one and onto properties. In other words, a bijection is both injective and surjective, while other types of functions may only have one of these properties.

4. Can a function be a bijection if its domain and range are infinite?

Yes, a function can be a bijection even if its domain and range are infinite. As long as the function has a one-to-one and onto relationship between its sets, it can be considered a bijection.

5. Why is it important to prove that a function is a bijection?

Proving that a function is a bijection is important because it ensures that the function has a unique inverse, which allows for easy and accurate reverse calculations. This is especially useful in mathematical and scientific applications.

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