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− | <td><strong>Theorem 1:</strong> Let <math>(f_n(x))_{n=1}^{\infty}</math> be a sequence of real-valued functions with common domain <math>X</math>. Then <math>\displaystyle{\sum_{n=1}^{\infty} f_n(x)}</math> is uniformly convergent on <math>X</math> if and only if for all <math>\varepsilon > 0</math> there exists an <math>N \in \mathbb{N}</math> such that if <math>n \geq N</math> and for all <math>x \in X</math> we have that <math>\displaystyle{ \left| \sum_{k=n+1}^{n+p} f_k(x) \right| < \varepsilon}</math> for all <math>p \in \mathbb{N}</math>.</td> | + | <blockquote style="background: white; border: 1px solid black; padding: 1em;"> <td><strong>Theorem 1:</strong> Let <math>(f_n(x))_{n=1}^{\infty}</math> be a sequence of real-valued functions with common domain <math>X</math>. Then <math>\displaystyle{\sum_{n=1}^{\infty} f_n(x)}</math> is uniformly convergent on <math>X</math> if and only if for all <math>\varepsilon > 0</math> there exists an <math>N \in \mathbb{N}</math> such that if <math>n \geq N</math> and for all <math>x \in X</math> we have that <math>\displaystyle{ \left| \sum_{k=n+1}^{n+p} f_k(x) \right| < \varepsilon}</math> for all <math>p \in \mathbb{N}</math>.</td> |
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| </table> | | </table> |
Revision as of 13:54, 27 October 2021
Recall that a sequence of functions with common domain is said to be pointwise convergent if for all and for all there exists an such that if then:
Also recall that a sequence of functions with common domain is said to be uniformly convergent if for all there exists an such that if then for all we have that:
We will now extend the concept of pointwise convergence and uniform convergence to series of functions.
Definition: Let be a sequence of functions with common domain . The corresponding series is said to be Pointwise Convergent to the sum function if the corresponding sequence of partial sums (where ) is pointwise convergent to .
For example, consider the following sequence of functions defined on the interval :
We now that this series converges pointwise for all since the result series is simply a geometric series to the sum function .
Definition: Let be a sequence of functions with common domain . The corresponding series is said to be Uniformly Convergent to the sum function if the corresponding sequence of partial sums is uniformly convergent to .
The geometric series given above actually converges uniformly on , though, showing this with the current definition of uniform convergence of series of functions is laborious. We will soon develop methods to determine whether a series of functions converges uniformly or not without having to brute-force apply the definition for uniform convergence for the sequence of partial sums.
Cauchy's Uniform Convergence Criterion for Series of Functions
If we have a sequence of functions with common domain then the corresponding series of functions is said to be uniformly convergent if the corresponding sequence of partial sums is a uniformly convergent sequence of functions.
We will now look at a nice theorem known as Cauchy's uniform convergence criterion for series of functions.
Theorem 1: Let be a sequence of real-valued functions with common domain . Then is uniformly convergent on if and only if for all there exists an such that if and for all we have that for all . |
- Proof: Suppose that is uniformly convergent to some limit function on . Let denote the sequence of partial sums for this series. Then we must have that uniformly on . So, for there exists an such that if and for all we have that:
- For any let . Then and so:
- Suppose that for all there exists an such that if and for all we have that:
- Let . Assume without loss of generality that and that for some . Then from above we see that for all :
- So converges uniformly by the Cauchy uniform convergence criterion for sequences of functions. So converges uniformly on .
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