|
|
Line 66: |
Line 66: |
| <div style="text-align: center;"><math>\begin{align} \quad S \cap T \subseteq T \end{align}</math></div> | | <div style="text-align: center;"><math>\begin{align} \quad S \cap T \subseteq T \end{align}</math></div> |
| <ul> | | <ul> |
− | <li>Furthermore, <span class="math-inline"><math>S \cap T</math></span> is closed. This is because <span class="math-inline"><math>S</math></span> is given as closed, and since <span class="math-inline"><math>T</math></span> is compact we know that <span class="math-inline"><math>T</math></span> is closed (and bounded). So the finite intersection <span class="math-inline"><math>S \cap T</math></span> is closed. But any closed subset of a compact set is also compact as we proved on the <a href="/closed-subsets-of-compact-sets-in-metric-spaces">Closed Subsets of Compact Sets in Metric Spaces</a> page, so <span class="math-inline"><math>S \cap T</math></span> is compact in <span class="math-inline"><math>M</math></span>. <span class="math-inline"><math>\blacksquare</math></span></li> | + | <li>Furthermore, <span class="math-inline"><math>S \cap T</math></span> is closed. This is because <span class="math-inline"><math>S</math></span> is given as closed, and since <span class="math-inline"><math>T</math></span> is compact we know that <span class="math-inline"><math>T</math></span> is closed (and bounded). So the finite intersection <span class="math-inline"><math>S \cap T</math></span> is closed. But any closed subset of a compact set is also compact, so <span class="math-inline"><math>S \cap T</math></span> is compact in <span class="math-inline"><math>M</math></span>. <span class="math-inline"><math>\blacksquare</math></span></li> |
| </ul> | | </ul> |
| <blockquote style="background: white; border: 1px solid black; padding: 1em;"> | | <blockquote style="background: white; border: 1px solid black; padding: 1em;"> |
Line 96: |
Line 96: |
| <li>Furthermore, since each <span class="math-inline"><math>C \in \mathcal C</math></span> is compact, then each <span class="math-inline"><math>C</math></span> is closed (and bounded). An arbitrary intersection of closed sets is closed, and so <span class="math-inline"><math>\displaystyle{\bigcap_{C \in \mathcal C}}</math></span> is a closed subset of the compact set <span class="math-inline"><math>C</math></span>. Therefore by the theorem referenced earlier, <span class="math-inline"><math>\displaystyle{\bigcap_{C \in \mathcal C} C}</math></span> is compact in <span class="math-inline"><math>M</math></span>. <span class="math-inline"><math>\blacksquare</math></span></li> | | <li>Furthermore, since each <span class="math-inline"><math>C \in \mathcal C</math></span> is compact, then each <span class="math-inline"><math>C</math></span> is closed (and bounded). An arbitrary intersection of closed sets is closed, and so <span class="math-inline"><math>\displaystyle{\bigcap_{C \in \mathcal C}}</math></span> is a closed subset of the compact set <span class="math-inline"><math>C</math></span>. Therefore by the theorem referenced earlier, <span class="math-inline"><math>\displaystyle{\bigcap_{C \in \mathcal C} C}</math></span> is compact in <span class="math-inline"><math>M</math></span>. <span class="math-inline"><math>\blacksquare</math></span></li> |
| </ul> | | </ul> |
− |
| |
| | | |
| ==Licensing== | | ==Licensing== |
Compact Sets in a Metric Space
If is a metric space and then a cover or covering of is a collection of subsets in such that:
Furthermore, we said that an open cover (or open covering) is simply a cover that contains only open sets.
We also said that a subset is a subcover/subcovering (or open subcover/subcovering if is an open covering) if is also a cover of , that is:
We can now define the concept of a compact set using the definitions above.
Definition: Let be a metric space. The subset is said to be Compact if every open covering of has a finite subcovering of .
In general, it may be more difficult to show that a subset of a metric space is compact than to show a subset of a metric space is not compact. So, let's look at an example of a subset of a metric space that is not compact.
Consider the metric space where is the Euclidean metric and consider the set . We claim that this set is not compact. To show that is not compact, we need to find an open covering of that does not have a finite subcovering. Consider the following open covering:
Clearly is an infinite subcovering of and furthermore:
Let be a finite subset of containing elements. Then:
Let . Then due to the nesting of the open covering , we see that:
But for we need . But , so and , so . Therefore any finite subset of cannot cover . Hence, is not compact.
Boundedness of Compact Sets in a Metric Space
Recall that if is a metric space then a subset is said to be compact in if for every open covering of there exists a finite subcovering of .
We will now look at a rather important theorem which will tell us that if is a compact subset of then we can further deduce that is also a bounded subset.
Theorem 1: If be a metric space and is a compact subset of then is bounded.
- Proof: For a fixed and for , consider the ball centered at with radius , i.e., . Let denote the collection of balls centered at with varying radii :
- It should not be hard to see that is an open covering of , since for all we have that , so .
- Now since is compact and since is an open covering of , there exists a finite open subcovering subset that covers . Since is finite, we have that:
- And by definition covers so:
- Each of the open balls in the open subcovering is centered at with . Since the set is a finite set, there exists a maximum value. Let:
- Then for all we have that and therefore:
- Hence is bounded.
Basic Theorems Regarding Compact Sets in a Metric Space
Recall that if is a metric space then a set is said to be compact in if for every open covering of there exists a finite subcovering of .
We will now look at some theorems regarding compact sets in a metric space.
Theorem 1: Let be a metric space and let . Then if is closed and is compact in then is compact in .
- Proof: Let be closed and let be compact in . Notice that:
- Furthermore, is closed. This is because is given as closed, and since is compact we know that is closed (and bounded). So the finite intersection is closed. But any closed subset of a compact set is also compact, so is compact in .
Theorem 2: Let be a metric space and let be a finite collection of compact sets in . Then is also compact in .
- Proof: Let be a finite collection of compact sets in . Consider the union and let be any open covering of , that is:
- Now since for all we see that is also an open covering of and so there exists a finite subcollection that also covers , i.e.:
- Let . Then is finite since it is equal to a finite union of finite sets. Furthermore:
- So is a finite open subcovering of . So for all open coverings of there exists a finite open subcovering of , so is compact in .
Theorem 3: Let be a metric space and let be an arbitrary collection of compact sets in . Then is also compact in .
- Proof: Let be an arbitrary collection of compact sets in . Notice that for all that:
- Furthermore, since each is compact, then each is closed (and bounded). An arbitrary intersection of closed sets is closed, and so is a closed subset of the compact set . Therefore by the theorem referenced earlier, is compact in .
Licensing
Content obtained and/or adapted from: