Advanced Calculus: Difference between revisions

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* (Topology)
* (Topology)


; Notes
* Union of infinitely many closed sets can be open.
* Intersection of infinitely many open sets can be closed.
* <math>\{\}</math and <math>\mathbb{R}</math> are both open and closed


Union of infinitely many closed sets can be open.
Intersection of infinitely many open sets can be closed.
===Compact===
===Compact===
Compactness is a generalization of closed and bounded.<br>
Compactness is a generalization of closed and bounded.<br>

Revision as of 05:03, 10 November 2019

Advanced Calculus as taught in Fitzpatrick's book.


Sequences

Topology

Closed

The folllowing definitions of Closed Sets are equivalent.

  • (Order)
  • (Sequences) A set \(\displaystyle S\) is clsoed if it contains all its limit points. That is \(\displaystyle \forall \{x_i\} \subseteq S\), \(\displaystyle \{x_i\} \rightarrow x_0 \implies x_0 \in S\).
  • (Topology)
Notes
  • Union of infinitely many closed sets can be open.
  • Intersection of infinitely many open sets can be closed.
  • \(\displaystyle \{\}\lt /math and \lt math\gt \mathbb{R}\) are both open and closed

Compact

Compactness is a generalization of closed and bounded.

Definitions
  • (Sequence) A set is sequentially compact if for every sequence from the set, there exists a subsequence which converges to a point in the set.
  • (Topology) A set is compact if for every covering by infinitely many open sets, there exists a covering by a finite subset of the open sets.
Notes
  • A set is sequentially compact iff it is closed and bounded

Metric Space

Continuity

Definitions of Continuity

The following definitions of Continuity are equivalent.

  • (Order) A function \(\displaystyle f\) is continuous at \(\displaystyle x_0\) if for all \(\displaystyle \epsilon\) there exists \(\displaystyle \delta\) such that \(\displaystyle |x - x_0| \leq \delta \implies |f(x) - f(x_0)| \leq \epsilon\)
  • (Sequences) A function \(\displaystyle f\) is continuous at \(\displaystyle x_0\) if \(\displaystyle \{x_n\} \rightarrow x_0 \implies \{f(x_n)\} \rightarrow f(x_0)\)
  • (Topology) A function \(\displaystyle f\) is continuous at \(\displaystyle x_0\) if for all open sets \(\displaystyle V\) s.t. \(\displaystyle f(x_0) \in V\), \(\displaystyle f^{-1}(V)\) is an open set.
    • The preimage of an open set is open.
    • Continuous functions map compact sets to compact sets.

Differentiation

Integration

Approximation

Series

Inverse Function Theorem

Implicit Function Theorem

Line and Surface Integrals