Difference between revisions of "The Continuous Extension Theorem"
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+ | <p>The Uniform Continuity Theorem states that if a function <math>I = [a, b]</math> is a closed and bounded interval and <math>f : I \to \mathbb{R}</math> is continuous on <math>I</math>, then <math>f</math> must also be uniformly continuous on <math>I</math>. The succeeding theorem will help us determine when a function <math>f</math> is uniformly continuous when <math>I</math> is instead a bounded open interval.</p> | ||
+ | <p>Before we look at The Continuous Extension Theorem though, we will need to prove the following lemma.</p> | ||
+ | <table class="wiki-content-table"> | ||
+ | <tr> | ||
+ | <blockquote style="background: white; border: 1px solid black; padding: 1em;"> | ||
+ | <strong>Lemma 1:</strong> If <math>f : A \to \mathbb{R}</math> is a uniformly continuous function and if <math>(x_n)</math> is a Cauchy Sequence from <math>A</math>, then <math>(f(x_n))</math> is a Cauchy sequence from <math>\mathbb{R}</math>. | ||
+ | </blockquote> | ||
− | == | + | </tr> |
− | * [http://mathonline.wikidot.com/the-continuous-extension-theorem The Continuous Extension Theorem | + | </table> |
+ | <ul> | ||
+ | <li><strong>Proof:</strong> Let <math>f : A \to \mathbb{R}</math> be a uniformly continuous function and let <math>(x_n)</math> be a Cauchy sequence from <math>A</math>. We want to show that <math>(f(x_n))</math> is also a Cauchy sequence. Recall that to show that <math>(f(x_n))</math> is a Cauchy sequence we must show that <math>\forall \varepsilon > 0</math> then <math>\exists N \in \mathbb{N}</math> such that <math>\forall m, n \in \mathbb{N}</math>, if <math>m, n \geq N</math> then <math>\mid f(x_n) - f(x_m) \mid < \varepsilon</math>.</li> | ||
+ | </ul> | ||
+ | <ul> | ||
+ | <li>Since <math>f</math> is uniformly continuous on <math>A</math>, then for any <math>\varepsilon > 0</math>, <math>\exists \delta_{\varepsilon} . 0</math> such that for all <math>x, y \in A</math> where <math>\mid x - y \mid < \delta_{\varepsilon}</math> we have that <math>\mid f(x) - f(y) \mid < \varepsilon</math>.</li> | ||
+ | </ul> | ||
+ | <ul> | ||
+ | <li>Now for <math>\delta_{\varepsilon} > 0</math>, since <math>(x_n)</math> is a Cauchy sequence then <math>\exists N_{\delta_{\varepsilon}} \in \mathbb{N}</math> such that <math>\forall m, n \geq N_{\delta_{\varepsilon}}</math> we have that <math>\mid x_n - x_M \mid < \delta_{\varepsilon}</math>. So this <math>N_{\delta_{\varepsilon}}</math> will do for the sequence <math>(f(x_n))</math>. So for all <math>n, m \geq N_{\delta_{\varepsilon}}</math> we have that <math>\mid x_n - x_m \mid < \delta_{\varepsilon}</math> and from the continuity of <math>f</math> this implies that <math>\mid f(x_n) - f(x_m) \mid < \varepsilon</math> and so <math>(f(x_n))</math> is a Cauchy sequence. <math>\blacksquare</math></li> | ||
+ | </ul> | ||
+ | <p>We are now ready to look at The Continuous Extension Theorem.</p> | ||
+ | <table class="wiki-content-table"> | ||
+ | <tr> | ||
+ | |||
+ | <blockquote style="background: white; border: 1px solid black; padding: 1em;"> | ||
+ | <strong>Theorem 1 (The Continuous Extension Theorem):</strong> If <math>I = (a,b)</math> is an interval, then <math>f : I \to \mathbb{R}</math> is a uniformly continuous function on <math>I</math> if and only if <math>f</math> can be defined at the endpoints <math>a</math> and <math>b</math> such that <math>f</math> is continuous on <math>[a, b]</math>. | ||
+ | </blockquote> | ||
+ | |||
+ | </tr> | ||
+ | </table> | ||
+ | <ul> | ||
+ | <li><strong>Proof:</strong> <math>\Rightarrow</math> Suppose that <math>f</math> is uniformly continuous on <math>I = (a, b)</math>. Let <math>(x_n)</math> be a sequence in <math>(a,b)</math> that converges to <math>a</math>. Then since <math>(x_n)</math> is a convergent sequence, it must also be a Cauchy sequence. By lemma 1, since <math>(x_n)</math> is a Cauchy sequence then <math>(f(x_n))</math> is also a Cauchy sequence, and so <math>(f(x_n))</math> must converge in <math>\mathbb{R}</math>, that is <math>\lim_{n \to \infty} f(x_n) = L</math> for some <math>L \in \mathbb{R}</math>.</li> | ||
+ | </ul> | ||
+ | <ul> | ||
+ | <li>Now suppose that <math>(y_n)</math> is another sequence in <math>(a, b)</math> that converges to <math>a</math>. Then <math>\lim_{n \to \infty} (x_n - y_n) = a - a = 0</math>, and so by the uniform continuity of <math>f</math>:</li> | ||
+ | </ul> | ||
+ | |||
+ | ::: <math>\lim_{n \to \infty} f(y_n) = \lim_{n \to \infty} [f(y_n) - f(x_n) + f(x_n)]</math> | ||
+ | ::: <math>\lim_{n \to \infty} f(y_n) = \lim_{n \to \infty} [f(y_n) - f(x_n) ] + \lim_{n \to \infty} f(x_n)</math> | ||
+ | ::: <math>\lim_{n \to \infty} f(y_n) = 0 + L = L</math> | ||
+ | |||
+ | <ul> | ||
+ | <li>So for every sequence <math>(y_n)</math> in <math>(a, b)</math> that converges to <math>a</math>, we have that <math>(f(y_n))</math> converges to <math>L</math>. Therefore by the Sequential Criterion for Limits, we have that <math>f</math> has the limit <math>L</math> at the point <math>a</math>. Therefore, define <math>f(a) = L</math> and so <math>f</math> is continuous at <math>a</math>. We use the same argument for the endpoint <math>b</math>, and so <math>f</math> is can be extended so that <math>f</math> is continuous on <math>[a, b]</math>.</li> | ||
+ | </ul> | ||
+ | <ul> | ||
+ | <li><math>\Leftarrow</math> Suppose that <math>f</math> is continuous on <math>[a, b]</math>. By the Uniform Continuity Theorem, since <math>[a, b]</math> is a closed and bounded interval then <math>f</math> is uniformly continuous. <math>\blacksquare</math></li> | ||
+ | </ul> | ||
+ | |||
+ | |||
+ | == Licensing == | ||
+ | Content obtained and/or adapted from: | ||
+ | * [http://mathonline.wikidot.com/the-continuous-extension-theorem The Continuous Extension Theorem, mathonline.wikidot.com] under a CC BY-SA license |
Latest revision as of 11:05, 6 November 2021
The Uniform Continuity Theorem states that if a function is a closed and bounded interval and is continuous on , then must also be uniformly continuous on . The succeeding theorem will help us determine when a function is uniformly continuous when is instead a bounded open interval.
Before we look at The Continuous Extension Theorem though, we will need to prove the following lemma.
Lemma 1: If is a uniformly continuous function and if is a Cauchy Sequence from , then is a Cauchy sequence from .
- Proof: Let be a uniformly continuous function and let be a Cauchy sequence from . We want to show that is also a Cauchy sequence. Recall that to show that is a Cauchy sequence we must show that then such that , if then .
- Since is uniformly continuous on , then for any , such that for all where we have that .
- Now for , since is a Cauchy sequence then such that we have that . So this will do for the sequence . So for all we have that and from the continuity of this implies that and so is a Cauchy sequence.
We are now ready to look at The Continuous Extension Theorem.
Theorem 1 (The Continuous Extension Theorem): If is an interval, then is a uniformly continuous function on if and only if can be defined at the endpoints and such that is continuous on .
- Proof: Suppose that is uniformly continuous on . Let be a sequence in that converges to . Then since is a convergent sequence, it must also be a Cauchy sequence. By lemma 1, since is a Cauchy sequence then is also a Cauchy sequence, and so must converge in , that is for some .
- Now suppose that is another sequence in that converges to . Then , and so by the uniform continuity of :
- So for every sequence in that converges to , we have that converges to . Therefore by the Sequential Criterion for Limits, we have that has the limit at the point . Therefore, define and so is continuous at . We use the same argument for the endpoint , and so is can be extended so that is continuous on .
- Suppose that is continuous on . By the Uniform Continuity Theorem, since is a closed and bounded interval then is uniformly continuous.
Licensing
Content obtained and/or adapted from:
- The Continuous Extension Theorem, mathonline.wikidot.com under a CC BY-SA license