Queue

# Queue

###### 2.2. Completeness of L^p(E

- Lemma to the Riesz-Fischer Theorem (1 ≤ p < ∞) X
- Lemma to the Riesz-Fischer Theorem (p = ∞) X
- The Riesz-Fischer Theorem X

###### 2.1. Linear Operators on Linear Spaces

###### 2.2. Banach Spaces

###### 2.3. Finite-Dimensional Linear Spaces

- Equivalence of Norms in a Finite-Dimensional Linear Space X
- Every Linear Operator on a Finite-Dimensional Normed Linear Space is Bounded
- Isometries on Normed Linear Spaces X
- Isomorphism Linear Operators on Normed Linear Spaces X
- Two Finite-Dimensional Normed Linear Spaces of the Same Dimension are Isomorphic X
- Every Finite-Dimensional Normed Linear Space is a Banach Space X
- Riesz's Lemma X
- A Normed Linear Space is Finite-Dimensional If and Only If The Closed Unit Ball is Compact X
- Finite-Dimensional Linear Spaces Review X

###### 2.4. The Baire Category Theorem

- The Cantor Intersection Theorem for Complete Metric Spaces X
- The Baire Category Theorem for Complete Metric Spaces X
- Corollary to the Baire Category Theorem for Complete Metric Spaces X
- The Baire Category Theorem Review X

###### 2.5. The Open Mapping and Closed Graph Theorems

- Criterion for the Range of a BLO to be Closed when X is a Banach Space
- Closed Ranges of BLOs when Y is a Banach Space
- IFF Criterion for the Range of a BLO to be Closed when X and Y are Banach Spaces
- Second IFF Criterion for the Range of a BLO to be Closed when X and Y are Banach Spaces
- Open and Closed Mappings
- The Open Mapping Theorem
- Isomorphisms Between Banach Spaces X
- Equivalence of Norms on Banach Spaces X
- The Closed Graph Theorem
- The Open Mapping and Closed Graph Theorems Review

###### 2.6. Algebraic and Topological Complements of Linear Subspaces

- Projection/Idempotent Linear Operators
- Algebraic Complements of Linear Subspaces
- Topological Complements of Normed Linear Subspaces
- Topological Complement Criterion for the Range of a BLO to be Closed when X and Y are Banach Spaces
- T(X) Finite Co-Dimensional Criterion for the Range of a BLO to be Closed when X and Y are Banach Spaces
- Algebraic and Topological Complements of Linear Subspaces Review

###### 2.7. The Uniform Boundedness Principle

## 3. Linear Functionals, Duality

###### 3.1. Linear Functionals

- Linear Functionals on Linear Spaces
- The Algebraic Dual of a Linear Space
- Extensions of Linear Functionals on Subspaces of a Linear Space
- Expressing a Linear Functional as a Linear Combination of Other Linear Functionals
- The Topological Dual of a Normed Linear Space
- A Normed Linear Space is Finite-Dimensional IFF the Algebraic Dual and Topological Dual are the Same
- Linear Functionals Review

###### 3.2. Weak Topologies on Linear Spaces

- Weaker and Stronger Topologies X
- The F-Weak Topology on a Normed Linear Space X
- The W-Weak Topology on a Normed Linear Space X
- The Weak Topology (X*-Weak) Topology on a Normed Linear Space X

- The Second Topological Dual of a Normed Linear Space
- The Canonical Embedding of X into X**
- The Weak* (J(X)-Weak) Topology on the Topological Dual of a Normed Linear Space
- Reflexive Normed Linear Spaces X

###### 3.3. The Hahn-Banach Theorem

- Positively Homogeneous and Subadditive Functions X
- The Hahn-Banach Lemma X
- The Hahn-Banach Theorem (Real Version) X
- The Hahn-Banach Theorem (Complex Version) X

- Extensions of Linear Functionals with Equal Norms
- Finite-Dimensional Subspaces of Normed Linear Spaces have Topological Complements
- Criterion for a Point to be in the Closure of a Subspaces of Normed Linear Spaces
- The Canonical Embedding J is an Isometry

###### 3.4. Separable Spaces and Alaoglu's Theorem

- Helly's Theorem
- If a Normed Linear Space X* is Separable then X is Separable X
- A Reflexive Linear Space X is Separable IFF X* is Separable X
- Closed Subspaces of Reflexive Spaces are Reflexive
- Separable Criterion for the Compactness and Sequential Compactness of the Closed Unit Ball of X* in the Weak* Topology
- Alaoglu's Theorem
- Every Normed Linear Space is Isometrically Isomorphic to C(K) where K is a Compact Hausdorff Space
- Every Bounded Sequence in a Reflexive Space has a Weak* Convergent Subsequence
- Separable Spaces and Alaoglu's Theorem Review