Proving Injectivity of the Map T: L^p(E) --> (L^q(E))* for 1<p<2 and q>=2

In summary, the conversation discusses the proof of injectivity for a given map T from L^p(E) to (L^q(E))* using conjugate exponents and integrable functions. It is eventually solved by realizing that T is a linear isometry, which guarantees injectivity.
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quasar987
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[SOLVED] Show map is injective

Homework Statement


Going crazy over this.

Let 1<p<2 and q>=2 be its conjugate exponent. I want to show that the map T: L^p(E) --> (L^q(E))*: x-->T(x) where

[tex]<T(x),y> = \int_Ex(t)y(t)dt[/tex]

is injective.

This amount to showing that if

[tex]\int_Ex(t)y(t)dt=0[/tex]

for all q-integrable functions y(t), then x(t)=0 (alsmost everywhere)

Should be easy but I've been at this for an hour and I don't see it!
 
Last edited:
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  • #2
Got it. Turns out that T is a linear isometry and every linear isometry is injective! (If T(y)=0, then ||T(y)|| = ||y|| = 0 ==> y=0).
 

1. What does it mean for a "show map" to be injective?

A "show map" is a mathematical function that takes a set of inputs and produces a set of outputs. When we say that a "show map" is injective, it means that each input has a unique output. In other words, no two inputs can produce the same output.

2. How can you prove that a "show map" is injective?

To prove that a "show map" is injective, we need to show that for every pair of inputs, x and y, if x produces the same output as y, then x and y must be the same input. This can be done using a proof by contradiction, where we assume that x and y are different inputs that produce the same output, and then show that this leads to a contradiction.

3. What are the benefits of having a "show map" be injective?

Having a "show map" be injective ensures that each input has a unique output, which can be useful in many applications. For example, in data analysis, an injective map can help identify patterns and relationships between different variables. In computer science, injective maps can be used to create efficient data structures and algorithms.

4. Can a "show map" be injective and surjective at the same time?

Yes, a "show map" can be both injective and surjective. A function is surjective if every output has at least one corresponding input. So, if a "show map" is both injective and surjective, it means that each input has a unique output, and every output has at least one corresponding input.

5. Are there any drawbacks to having a "show map" be injective?

One potential drawback of having a "show map" be injective is that it may not be able to handle certain types of data. For example, if there are multiple inputs that could potentially produce the same output, an injective map would not be able to capture this information. In some cases, a more flexible map, such as a non-injective map, may be more appropriate.

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