Metric and Hilbert Space Problems 2014

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last update: 4 March 2014

Homework

Define the standard metric on $ℂ$ and show that $ℂ,$ with this metric, is a metric space.
Let $d$ be the standard metric on $ℂ .$ Show that $ℝ$ is a metric subspace of $(ℂ, d) .$
Let $X$ be a set. Define the standard metric on $X$ and show that $X,$ with this metric, is a metric space.
Let $(X_{1}, d_{1}), \dots, (X_{n}, d_{n})$ be metric spaces. Define the product metric $d$ on $X_{1} \times \dots \times X_{n}$ and show that $(X_{1} \times \dots \times X_{n}, d)$ is a metric space.
Let $(X, ‖ ‖)$ be a normed vector space. Define the standard metric on $X$ and show that $X,$ with this metric, is a metric space.
Define the standard metric on $ℝ^{n}$ and show that $ℝ^{n},$ with this metric, is a metric space.
Define the standard norm on $ℝ^{n}$ and show that $ℝ^{n},$ with this norm, is a normed vector space.
Define the norm ${‖ ‖}_{p}$ on $ℝ^{n}$ and show that $(ℝ^{n}, {‖ ‖}_{p})$ is a normed vector space.
Let $X$ be a nonempty set. Define the set of bounded functions $B (X, ℝ)$ and the sup norm on $B (X, ℝ) .$ Show that $B (X, ℝ),$ with this norm, is a normed vector space.
Let $a, b \in ℝ$ with $a < b .$ Define the set of continuous functions $C ([a, b], ℝ)$ and the $L^{1} -norm$ on $C ([a, b], ℝ) .$ Show that $C ([a, b], ℝ),$ with this norm, is a normed vector space.
Let $a, b \in ℝ$ with $a < b .$ Show that the set $C_{bd} ([a, b], ℝ)$ of bounded continuous functions is a metric subspace of $C ([a, b], ℝ)$ with the $L^{1} -norm.$
Let $X$ be a metric space and let $x_{1}, x_{2}, \dots$ be a sequence in $X .$ Show that $lim_{n \to \infty} x_{n}$ is unique, if it exists.
Let $(X_{1}, d_{1}), \dots, (X_{ℓ}, d_{ℓ})$ be metric spaces. Show that a sequence $\overline{x_{n}} = (x_{n}^{(1)}, \dots, x_{n}^{(ℓ)})$ in $X_{1} \times \dots \times X_{ℓ}$ converges if and only if each of the sequences $x_{n}^{(i)}$ (in $X_{i})$ converges.
Let $(X, d)$ be a metric space. Show that the metric $d' : X \times X \to ℝ$ given by $d' (x, y) = \frac{d (x, y)}{1 + d (x, y)}$ is equivalent to $d .$
Let $(X, d)$ be a metric space. Show that $(X, d')$ is a bounded metric space, where $d' (x, y) = \frac{d (x, y)}{1 + d (x, y)} .$
Give an example of $X$ and two metrics $d$ and $d'$ on $X$ such that $d$ is equivalent to $d'$ and $(X, d)$ is not bounded and $(X, d')$ is bounded.
Let $(X_{1}, d_{1}), \dots, (X_{ℓ}, d_{ℓ})$ be metric spaces and let $(X_{1} \times \dots \times X_{ℓ}, d)$ be the product metric space. Let $σ : (X_{1} \times \dots \times X_{ℓ}) \times (X_{1} \times \dots \times X_{ℓ}) \to ℝ$ given by $σ (x, y) = max {d_{i} (x_{i}, y_{i}) | 1 \leq i \leq ℓ} .$ Show that $σ$ is a metric on $X_{1} \times \dots \times X_{ℓ}$ and $d$ is equivalent to $σ .$
Let $(X_{1}, d_{1}), \dots, (X_{ℓ}, d_{ℓ})$ be metric spaces and let $(X_{1} \times \dots \times X_{ℓ}, d)$ be the product metric space. Let $ρ : (X_{1} \times \dots \times X_{ℓ}) \times (X_{1} \times \dots \times X_{ℓ}) \to ℝ$ be given by $ρ (x, y) = {(\sum_{i = 1}^{ℓ} d_{i} {(x_{i}, y_{i})}^{2})}^{\frac{1}{2}} .$ Show that $ρ$ is a metric on $X_{1} \times \dots \times X_{ℓ}$ and $d$ is equivalent to $ρ .$
Let $X$ be a set and let $d$ and $d'$ be metrics on $X .$ Show that $d$ and $d'$ are equivalent if and only if $d$ and $d'$ satisfy the condition if $x, y \in X$ then there exist $k, k' \in ℝ$ such that $d (x, y) \leq k d' (x, y) \leq k' d (x, y) .$
Let $(X, d)$ be a metric space. Define the metric space topology on $X$ and show that it is a topology on $X .$
Let $X$ be a set and let $d$ be the discrete metric on $X .$ Determine which subsets of $X$ are in the metric space topology on $X .$
Give two metrics $d$ and $d'$ on $ℝ$ such that $ℚ$ is open in the metric space topology on $(ℝ, d)$ and $ℚ$ is not open in the metric space topology on $(ℝ, d') .$
Let $X$ be a topological space and let $E$ be a subset of $X .$ Let $E^{\circ}$ be the interior of $E .$ Show that $E$ is open if and only if $E = E^{\circ} .$
Let $X$ be a topological space and let $E$ be a subset of $X .$ Let $E^{\circ}$ be the interior of $E .$ Show that $E^{\circ}$ is the set of interior points of $E .$
Let X be a topological space and let x∈X. Consider the following definitions of "neighborhood of x":
1. A neighborhood of $x$ is a set $N \subseteq X$ such that $x \in N^{\circ} .$
2. A neighborhood of $x$ is a set $V \subseteq X$ such that there exists an open set $U$ of $X$ with $x \in U \subseteq V .$
Show that these two definitions of "neighborhood of x" are equivalent.
Let $X$ be a topological space and let $E$ be a subset of $X .$ Let $\overline{E}$ be the closure of $E .$ Show that $E$ is closed if and only if $E = \overline{E} .$
Let $X$ be a topological space and let $E$ be a subset of $X .$ Let $x \in X .$ Show that $x$ is a closed point of $E$ if and only if there exists a sequence $x_{1}, x_{2}, \dots$ of points in $E$ such that $lim_{n \to \infty} x_{n} = x .$
Let $(X, d)$ be a metric space and let $x \in X$ and $r \in ℝ_{>0} .$ Show that the closed ball $\overline{B} (x, r) = {y \in X | d (x, y) \leq r}$ is a closed set in the metric space topology on $X .$
Give an example of a metric space $(X, d)$ and a point $x \in X$ such that $\overline{B} (x, 1) \neq \overline{B (x, 1)} .$
Let $(X, d)$ be a metric space and let $x \in X$ and $r \in ℝ_{> 0} .$ Show that $\overline{B (x, r)} \subseteq \overline{B} (x, r) .$
In ℝ with the usual topology give an example of
1. a set $A \subseteq ℝ$ which is both open and closed,
2. a set $B \subseteq ℝ$ which is open and not closed,
3. a set $C \subseteq ℝ$ which is closed and not open,
4. a set $D \subseteq ℝ$ which is not open and not closed.
Let X=ℝ with the usual topology. Show that
1. $[0, 1) \subseteq ℝ$ is not open and not closed,
2. $ℚ \subseteq ℝ$ is not open and not closed.
Let $X$ be a set with the discrete metric $d .$ Show that every subset of $X$ is both open and closed (in the metric space topology on $X).$
Let X be a set and let 𝒞 be a collection of subsets of X. Show that 𝒞 is the set of closed sets for a topology on X if and only if 𝒞 satisfies
1. finite unions of elements of $𝒞$ are in $𝒞,$
2. Arbitrary intersections of elements of $𝒞$ are in $𝒞,$
3. $\emptyset \in 𝒞$ and $X \in 𝒞 .$
Let X be a topological space and let Y⊆X with the subspace topology. Show that
1. $B \subseteq Y$ is open in $Y$ if and only if $B = Y \cap A$ for some set $A \subseteq X$ which is open in $X .$
2. $B \subseteq Y$ is closed in $Y$ if and only if there exists $F \subseteq X$ closed in $X$ such that $B = Y \cap F .$
Let X1,…,Xℓ be topological spaces and let X1×⋯×Xℓ have the product topology. Show that
1. If $A_{1} \subseteq X_{1}, \dots, A_{ℓ} \subseteq X_{ℓ}$ are open then $A_{1} \times \dots \times A_{ℓ} \subseteq X_{1} \times \dots \times X_{ℓ}$ is open.
2. If $F_{1} \subseteq X_{1}, \dots, F_{ℓ} \subseteq X_{ℓ}$ are closed then $F_{1} \times \dots \times F_{ℓ} \subseteq X_{1} \times \dots \times X_{ℓ}$ is closed.
Let $(X_{1}, d_{1}), \dots, (X_{ℓ}, d_{ℓ})$ be metric spaces and let $d$ be the product metric on $X_{1} \times \dots \times X_{ℓ} .$ Show that the metric space topology on $(X_{1} \times \dots \times X_{ℓ}, d)$ is the product topology for $X_{1} \times \dots \times X_{ℓ},$ where $X_{1}, \dots, X_{ℓ}$ have the metric space topology.
Let $X$ be a topological space and let $A \subseteq X .$ Show that if $x \in X$ satisfies if $r \in ℝ_{> 0}$ then $B (x, r) \cap A \neq \emptyset$ and $B (x, r) \cap A^{c} \neq \emptyset$ then $x \in \partial A .$
Let $X$ be a topological space and let $A \subseteq X .$ Show that $\partial A$ is a closed subset of $X .$
Let X=ℝ with the usual topology.
1. Determine (with proof) $\partial ([0, 1]) .$
2. Determine $\partial ℚ$ (with proof, of course).
Let $(X, d)$ be a metric space. Let $x \in X .$ Show that ${x} \subseteq X$ is closed (in the metric space topology on $X).$
Let $(X, d)$ be a metric space and let $x \in X .$ Show that $x$ is isolated if and only if there exists $ε \in ℝ_{> 0}$ such that $B (x, ε) = {x} .$
Let X=ℝ with the usual topology. Show that
1. $ℤ_{> 0} \subseteq ℝ$ is a discrete set in $ℝ,$
2. ${\frac{1}{n} | n \in ℤ_{> 0}} \subseteq ℝ$ is a discrete set in $ℝ .$
Let $X$ be a discrete topological space. Show that every subset of $X$ is both open and closed.
Let $X$ be a topological space. Show that $X$ is discrete if and only if the only convergent sequences are those which are eventually constant.
Let X=ℝ with the usual topology.
1. Show that $ℚ$ is dense in $ℝ .$
2. Show that $ℚ^{c}$ is dense in $ℝ .$
3. Show that $ℤ_{> 0}$ is nowhere dense in $ℝ .$
4. Show that $ℤ$ is nowhere dense in $ℝ .$
5. Show that $ℝ$ is nowhere dense in $ℝ^{2} .$
Let C be the Cantor set in ℝ, where ℝ has the usual topology.
1. Show that $C$ is closed in $ℝ .$
2. Show that $C$ does not contain any interval in $ℝ .$
3. Show that $C$ has nonempty interior.
4. Show that $C$ is nowhere dense in $ℝ .$
Let $(X, d)$ and $(Y, ρ)$ be metric spaces and let $f : X \to Y$ be a function. Let $a \in X .$ Show that $f$ is continuous at $a$ if and only if $f$ satisfies: if $ε \in ℝ_{> 0}$ then there exists $δ \in ℝ_{> 0}$ such that
if $x \in X$ and $d (x, a) < δ$ then $ρ (f (x), f (a)) < ε .$
Let $X$ and $Y$ be topological spaces and let $f : X \to Y$ be a function. Show that $f$ is continuous if and only if $f$ satisfies: if $a \in X$ then $f$ is continuous at $a .$
Let $X$ and $Y$ be metric spaces and let $f : X \to Y$ be a function. Let $a \in X .$ Show that $f$ is continuous at $a$ if and only if $f$ satisfies: if $ε \in ℝ_{> 0}$ then there exists $δ \in ℝ_{> 0}$ such that $f (B (a, δ)) \subseteq B (f (a), ε) .$
Let $X$ and $Y$ be metric spaces and let $f : X \to Y$ be a function. Let $a \in X .$ Show that $f$ is continuous at $a$ if and only if $f$ satisfies if $x_{1}, x_{2}, \dots$ is a sequence in $X$ and $lim_{n \to \infty} x_{n} = x_{0}$ then $lim_{n \to \infty} f (x_{n}) = f (x_{0}) .$
Let $X$ and $Y$ be metric spaces and let $f : X \to Y$ be a function. Let $a \in X .$ Show that $f$ is continuous at $a$ if and only if $f$ satisfies: if $x_{1}, x_{2}, \dots$ is a convergent sequence in $X$ then $lim_{n \to \infty} f (x_{n}) = f (lim_{n \to \infty} x_{n}) .$
Let $X$ and $Y$ be topological spaces. Let $f : X \to Y$ be a function. Show that $f$ is continuous if and only if $f$ satisfies: if $F \subseteq Y$ is closed then $f^{- 1} (F)$ is closed in $X .$
Let $X, Y$ and $Z$ be topological spaces and let $f : X \to Y$ and $g : Y \to Z$ be continuous functions. Show that $g \circ f$ is a continuous function.
Let $X, Y$ be topological spaces and let $f : X \to Y$ be a continuous function. Let $A \subseteq X .$ Show that the restriction of $f$ to $A,$ $f |_{A} : A \to Y$ is continuous.
Let $(X, d), (Y_{1}, ρ_{1})$ and $(Y_{2}, ρ_{2})$ be metric spaces. Let $f : X \to Y_{1}$ and $g : X \to Y_{2}$ be functions. Define $h : X \to Y_{1} \times Y_{2}$ by $h (x) = (f (x), g (x)) .$ Let $a \in X .$ Show that $h$ is continuous at $a$ if and only if $f$ and $g$ are continuous at $a .$ $\begin{matrix} X & \overset{Δ}{⟶} & X \times X \\ ↓ f \times g \\ Y_{1} \times Y_{2} \end{matrix} \begin{matrix} x & ⟼ & (x, x) \\ ↧ \\ (f (x), g (x)) \end{matrix}$
Let $(X, d), (Y_{1}, ρ_{1})$ and $(Y_{2}, ρ_{2})$ be metric spaces. Let $f : X \to Y_{1}$ and $g : X \to Y_{2}$ be functions. Define $h : X \to Y_{1} \times Y_{2}$ by $h (x) = (f (x), g (x)) .$ Let $a \in X .$ Show that $h$ is continuous if and only if $f$ and $g$ are continuous.
Let (X,d) be a metric space and let f:X→ℝ and g:X→ℝ be continuous functions.
1. Show that $f + g$ is continuous.
2. Show that $f \cdot g$ is continuous.
3. Show that $f - g$ is continuous.
4. Show that if $g$ satisfies: if $x \in X$ then $g (x) \neq 0$ then $f / g$ is continuous.
Let X be a topological space and let f:X→ℝ and g:X→ℝ be continuous functions.
1. Show that $f + g$ is continuous.
2. Show that $f \cdot g$ is continuous.
3. Show that $f - g$ is continuous.
4. Show that if $g$ satisfies: if $x \in X$ then $g (x) \neq 0$ then $f / g$ is continuous.
Let $(X, d)$ be a metric space. Show that $d : X \times X \to ℝ$ is continuous.
Let f:ℝ×ℝ→ℝ be given by f(x,y)= { xyx2+y2, if (x,y)≠ (0,0) 0, if (x,y)= (0,0). If a∈ℝ let ℓa:ℝ→ℝ be given by ℓa(y)=f(a,y). If b∈ℝ let rb:ℝ→ℝ be given by rb(x)=f(x,b).
1. Let $a \in ℝ .$ Show that $ℓ_{a} : ℝ \to ℝ$ is continuous.
2. Let $b \in ℝ .$ Show that $r_{b} : ℝ \to ℝ$ is continuous.
3. Show that $f$ is not continuous at $(0, 0) .$
Give an example of metric spaces X,Y and Z and a function f:X×Y→ℤ such that
1. if $x \in X$ then $\begin{matrix} ℓ_{x} : & Y & ⟶ & Z \\ y & ⟼ & f (x, y) \end{matrix}$ is continuous,
2. if $y \in Y$ then $\begin{matrix} r_{y} : & X & ⟶ & Z \\ x & ⟼ & f (x, y) \end{matrix}$ is continuous,
3. $f : X \times Y \to Z$ is not continuous.
Let $X$ be a topological space and let $A \subseteq X$ and $B \subseteq X$ be closed subsets of $X$ such that $X = A \cup B .$ Let $Y$ be a topological space and let $f : A \to Y$ and $g : B \to Y$ be continuous functions such that if $x \in A \cap B$ then $f (x) = g (x) .$ Define $h : X \to Y$ by $h (x) = {\begin{matrix} f (x), & if x \in A, \\ g (x), & if x \in B . \end{matrix}$ Show that $h : X \to Y$ is continuous.
Show that the function $f : ℝ \to ℝ$ given by $f (x) = \frac{x}{1 + x^{2}},$ is uniformly continuous.
Show that the function $f : ℝ \to ℝ$ given by $f (x) = x^{2},$ is not uniformly continuous.
Let $(X, d)$ and $(Y, ρ)$ be metric spaces and let $f : X \to Y$ be a function. Show that if $f$ is uniformly continuous then $f$ is continous.
Let $(X, d)$ and $(Y, ρ)$ be metric spaces. Let ${f_{k}}$ be a sequence of functions $f_{k} : X \to Y$ and let $f : X \to Y$ be a function. Show that ${f_{k}}$ converges uniformly to $f$ if and only if $sup {ρ (f_{k} (x), f (x)) | x \in X} \to 0 .$
Let ${f_{k}}$ be a sequence of continuous functions from a metric space $(X, d)$ to a metric space $(Y, ρ) .$ Suppose that ${f_{k}}$ converges uniformly to $f : X \to Y .$ Show that $f : X \to Y$ is continuous.
Let $(X, d)$ be a metric space and let $x_{1}, x_{2}, \dots$ be a sequence in $X .$ Show that if $(x_{1}, x_{2}, \dots)$ is a Cauchy sequence then ${x_{1}, x_{2}, \dots}$ is bounded.
Let $(X, d)$ be a metric space and let $(x_{1}, x_{2}, \dots)$ be a sequence in $X .$ Show that if $(x_{1}, x_{2}, \dots)$ converges then $(x_{1}, x_{2}, \dots)$ is a Cauchy sequence.
Let $(X, d)$ be a metric space and let $(x_{1}, x_{2}, \dots)$ be a sequence in $X .$ Show that if $(x_{1}, x_{2}, \dots)$ is a Cauchy sequence and contains a convergent subsequence then $(x_{1}, x_{2}, \dots)$ converges.
Give an example of a metric space $(X, d)$ and a Cauchy sequence $(x_{1}, x_{2}, \dots)$ in $X$ that does not converge.
Give an example of a metric space $(X, d)$ that is not complete.
Show that $ℝ$ with the usual metric is a complete metric space.
Let $(X, d)$ be a complete metric space. Let $Y \subseteq X$ be a subspace of $X .$ Show that if $Y$ is closed then $(Y, d)$ is complete.
Give an example of a metric space $(X, d)$ and a subspace $Y \subseteq X$ such that $(X, d)$ is a complete metric space and $(Y, d)$ is not complete.
Let $(X, d)$ be a metric space and let $Y \subseteq X$ be a subspace of $X .$ Show that if $(Y, d)$ is complete then $Y$ is a closed subset of $X .$
Let $(X_{1}, d_{1}), \dots, (X_{ℓ}, d_{ℓ})$ be metric spaces and let $(X_{1} \times \dots \times X_{ℓ}, d)$ be the product metric space. Show that if $(X_{1}, d_{1}), \dots, (X_{ℓ}, d_{ℓ})$ are complete then $(X_{1} \times \dots \times X_{ℓ}, d)$ is complete.
Let $(X, d)$ and $(Y, d')$ be metric spaces and let $C_{b} (X, Y)$ be the set of bounded continuous functions $f : X \to Y$ with the metric given by $ρ (f, g) = sup {d' (f (x), g (x)) | x \in X} .$ Show that if $(Y, d')$ is complete then $(C_{b} (X, y), ρ)$ is a complete metric space.
Let $(X, d)$ and $(Y, d')$ be metric spaces and let $C_{b} (X, Y)$ be the set of bounded continuous functions $f : X \to Y$ with the metric $ρ : C_{b} (X, Y) \times C_{b} (X, Y) \to ℝ_{> 0}$ given by $ρ (f, g) = sup {d' (f (x), g (x)) | x \in X} .$ Show that $(C_{b} (X, Y), ρ)$ is a metric space.
Let $(X, d)$ be a metric space and let $U \subseteq X$ and $V \subseteq X .$ Show that if $U$ and $V$ are open and dense then $U \cap V$ is open and dense.
Let $X = ℝ$ with the usual metric and let $U = ℚ$ and $V = ℚ^{c} .$ Show that $U$ and $V$ are dense and $U \cap B = \emptyset .$
Let X=ℚ with the usual metric and let ℚ={q1,q2,q3,…} be an enumeration of ℚ. For n∈ℤ>0 let Qn=ℚ\{qn}.
1. Show that if $n \in ℤ_{> 0}$ then $Q_{n}$ is open and dense.
2. Show that $⋂_{n \in ℤ_{> 0}} Q_{n} = \emptyset .$
Let $(X, d)$ be a complete metric space and let ${U_{1}, U_{2}, U_{3}, \dots}$ be a sequence of open and dense subsets of $X .$ show that $⋂_{n \in ℤ_{> 0}} U_{n}$ is dense in $X .$
Let $(X, d)$ be a complete metric space and let ${F_{1}, F_{2}, F_{3}, \dots}$ be a sequence of nowhere dense subsets of $X .$ Show that $⋃_{n \in ℤ_{> 0}} F_{n}$ has empty interior.
Show that $ℝ,$ with the standard topology, cannot be be written as a countable union of nowhere dense sets.
Let X=ℚ, with the standard topology. Let ℚ={q1,q2,q3,…} be an enumeration of ℚ.
1. Show that ${q_{n}}$ is nowhere dense.
2. Determine the interior of $⋃_{n \in ℤ_{> 0}} {q_{n}} .$
Let $(X, d)$ be a complete metric space and let ${f_{1}, f_{2}, f_{3}, \dots}$ be a sequence of continuous functions $f_{n} : X \to ℝ, for n \in ℤ_{> 0} .$ Assume that if $x \in X$ then ${f_{1} (x), f_{2} (x), \dots}$ is bounded in $X .$ Show that there exists and open set $U \subseteq X$ such that there exists $M \in ℝ_{> 0}$ such that
if $x \in U$ and $n \in ℤ_{> 0}$ then $| f_{n} (x) | \leq M .$
Show that the completion of $(0, 1)$ with the usual metric is $[0, 1]$ with the usual metric.
Let $(X, d)$ and $(Y, ρ)$ be metric spaces and let $f : X \to Y$ be an isometry. Show that $f$ is injective.
Give an example of an isometry $f : X \to Y$ that is not surjective.
Let $(X, d)$ be a metric space. Show that a completion of $(X, d)$ exists.
Let $(X, d)$ be a metric space. Show that the completion of $(X, d)$ is unique (if it exists).
Let $(X, d)$ be a metric space. Let $((X_{1}, d_{1}), φ_{1})$ and $((X_{2}, d_{2}), φ_{2})$ be completions of $(X, d) .$ Show that there is a surjective isometry $f : X_{1} \to X_{2}$ such that $f \circ φ_{1} = φ_{2} .$
Let X={0,1} and let 𝒯={∅,X,{0}}.
1. Show $𝒯$ is a topology on $X .$
2. Show that there does not exist a metric $d : X \times X \to ℝ_{\geq 0}$ such that $𝒯$ is the metric space topology of $(X, d) .$
Let $X$ be a complete metric space and let $f : X \to X$ be a contraction. Show that $f$ has a unique fixed point.
Let α∈ℝ with 0<α<1. Let X be a complete metric space and let f:X→X be a α-contraction. Let x∈X, x0=x and xn+1=f(xn), for n∈ℤ≥0.
1. Show that the sequence $x_{0}, x_{1}, x_{2}, \dots$ converges in $X .$
Let p=limn→∞xn.
1. Show that $d (x, p) \leq \frac{d (x, f (x))}{1 - α} .$
2. Show that $f (p) = p .$
Let $U$ be an open subset of $ℝ^{2} .$ Let $f : U \to ℝ$ be a continuous function which satisfies the Lipschitz condition with respect to the second variable: There exists $α \in ℝ_{> 0}$ such that
if $(x, y_{1}), (x, y_{2}) \in U$ then $| f (x, x_{1}) - f (x, y_{2}) | \leq α | y_{1}, y_{2} | .$ Show that if $(x_{0}, y_{0}) \in U$ then there exists $δ \in ℝ_{> 0}$ such that $y' (x) = f (x, y (x))$ has a unique solution $y : [x_{0} - δ, x_{0} + δ] \to ℝ$ such that $y (x_{0}) = y_{0} .$
Let $(X, ‖ ‖)$ be a normed vector space. Show that $(X, ‖ ‖)$ is complete if and only if every norm absolutely convergent series is convergent in $X .$
Let S be the set of linear combinations of step functions f:ℝk→ℝ. Let ‖f‖=∫|f| andd(f,g)= ‖f-g‖ for f,g∈S.
1. show that $‖ ‖ : S \to ℝ_{\geq 0}$ is not a norm on $S .$
2. Show that $d : S \times S \to ℝ_{\geq 0}$ is not a metric on $S .$
Let $S$ be the set of linear combinations of step functions $f : ℝ^{k} \to ℝ .$ Let $\sum_{i \in ℤ_{> 0}} f_{i}$ be a series in $S$ which is norm absolutely convergent. Show that there exists a full set in $ℝ^{k}$ on which $\sum_{i \in ℤ_{\geq 0}} f_{i}$ converges.
Let $S$ be the set of linear combinations of step functions $f : ℝ^{k} \to ℝ .$ Let $\sum_{n \in ℤ_{> 0}} f_{k}$ be a series in $S$ which is norm absolutely convergent. Show that $\sum_{n \in ℤ_{> 0}} f_{n} = 0$ almost everywhere if and only if the limit of the norms of the partial sums of $f_{n}$ converge to $0 .$
Let L′ be the set of functions which are equal almost everywhere to limits of norm absolutely convergent series in S, where S is the set of linear combinations of step functions f:ℝk→ℝ. Define ‖f‖=∫fand d(f,g)=‖f-g‖ for f,g∈L′.
1. Show that $‖ ‖ : L' \to ℝ_{\geq 0}$ is a norm on $L' .$
2. Show that $d : L' \times L' \to ℝ_{\geq 0}$ is a metric on $L' .$
Let $I$ be a closed and bounded interval in $ℝ .$ Let $x_{1}, x_{2}, x_{3}, \dots,$ be a sequence in $I .$ Show that there exists a subsequence $x_{n_{1}}, x_{n_{2}}, x_{n_{3}}, \dots$ of $x_{1}, x_{2}, x_{3}, \dots$ such that $x_{n_{1}}, x_{n_{2}}, x_{n_{3}}, \dots$ converges in $I .$
Let $X$ be a compact topological space. Let $C$ be a closed subset of $X .$ Show that $C$ is compact.
Let $X$ be a metric space and let $E$ be a compact subset of $X .$ Show that $E$ is closed and bounded.
Let C([0,1],ℝ)={f:[0,1]→ℝ | f is continuous} and let d(f,g)=sup { |f(x)-g(x)| | x∈[0,1] } .
1. Show that $d : C ([0, 1], ℝ) \times C ([0, 1], ℝ)$ is a metric on $C ([0, 1], ℝ) .$
2. Let $A = {\overline{B}}_{1} (0) = {f \in C ([0, 1], ℝ) | d (f, 0) \leq 1} .$ Show that $A$ is closed and bounded.
3. Show that $A$ is not compact.
Let $K \subseteq ℝ .$ Show that $K$ is compact if and only if $K$ is closed and bounded.
Let $(X, d)$ and $(Y, d')$ be metric spaces and let $f : X \to Y$ be a continuous function. Let $K$ be a compact subset of $X .$ Show that $f (K)$ is compact in $Y .$
Let $X$ be a compact metric space. Let $f : X \to ℝ$ be a continuous function. Show that $f$ attains a maximum and a minimum value.
Let $X$ be a compact metric space. Let $f : X \to Y$ be a continuous function. Show that $f$ is uniformly continuous.
Let $X$ be a set with the discrete metric. Show that $X$ is compact if and only if $X$ is finite.
Let $X$ be a metric space and let $A \subseteq X .$ Show that if $A$ is totally bounded then $A$ is bounded.
Let X=ℝ with metric given by d(x,y)=min {|x-y|,1}.
1. Show that $X$ is bounded.
2. Show that $X$ is not totally bounded.
Let X be a metric space and let A⊆X. Show that the following are equivalent:
1. Every sequence in $A$ has a convergent subsequence.
2. $A$ is complete and totally bounded.
3. Every open cover of $A$ has a finite subcover.
Let $X$ be a topological space. Show that $X$ is compact if and only if $X$ satisfies if $𝒞$ is a collection of closed sets such that if $ℓ \in ℤ_{> 0}$ and $C_{1}, \dots, C_{ℓ} \in 𝒞$ then $C_{1} \cap \dots \cap C_{ℓ} \neq \emptyset$ then $⋂_{C \in 𝒞} C \neq \emptyset .$
Let $X$ be a topological space and let $K \subseteq X .$ Assume $X$ is compact. Show that if $K$ is closed then $K$ is compact.
Let $X$ be a topological space and let $K \subseteq X .$ Assume $X$ is Hausdorff. Show that if $K$ is compact then $K$ is closed.
Show that a compact Hausdorff space is normal.
Let $X$ and $Y$ be topological spaces and let $f : X \to Y$ be a continuous function. Let $K \subseteq X .$ Show that if $K$ is compact then $f (K)$ is compact.
Let $X$ and $Y$ be topological spaces and let $f : X \to Y$ be a continuous function. Assume $f$ is a bijection, $X$ is compact and $Y$ is Hausdorff. Show that the inverse function $f^{- 1} : Y \to X$ is continuous.
Let X=[0,2π) and Y=S1={(x,y)∈ℝ2 | x2+y2=1}. Let f:[0,2π)→S1 be given by f(x)=(cos x,sin x).
1. Show that $f$ is continuous.
2. Show that $f$ is a bijection.
3. Show that $f^{- 1} : S^{1} \to [0, 2 π)$ is not continuous.
4. Why does this not contradict the previous problem?
Let X be a set with Card(X)>1.
1. Show that $X$ with the discrete topology is disconnected.
2. Show that $X$ with the indiscrete topology is connected.
Let $X_{1}$ and $X_{2}$ be the subspaces of $ℝ$ given by $X_{1} - ℝ \ {0}$ and $X_{2} = ℚ .$ Show that $X_{1}$ and $X_{2}$ are disconnected.
Let $Y = {0, 1}$ with the discrete topology. Let $X$ be a topological space. Show that $X$ is connected if and only if every continuous function $f : X \to Y$ is constant.
Let $X$ and $Y$ be topological spaces and let $f : X \to Y$ be a continuous function. Let $E \subseteq X .$ Show that if $E$ is connected then $f (E)$ is connected.
Let $X$ be a connected topological space and let $A \subseteq X .$ Show that if $A$ is connected then the closure of $A,$ $\overline{A},$ is connected.
Let $A = (- \infty, 0)$ and $B = (0, \infty)$ as subsets of $ℝ .$ Show that $A$ is connected, $B$ is connected and $A \cup B$ is not connected.
Let $X$ be a topological space. Let $𝒮$ be a collection of subsets of $X$ such that $⋂_{A \in 𝒮} A \neq \emptyset .$ Show that $⋃_{A \in 𝒮} A$ is connected.
Let $X$ be a topological space such that if $x, y \in X$ then there exists $A \subseteq X$ such that $x \in A,$ $y \in A$ and $A$ is connected. Show that $X$ is connected.
Let X be a topological space. For x∈X let Cx be the connected component containing x.
1. Let $y \in X .$ Show that $C_{y}$ is connected and closed.
2. Show that the connected components of $X$ partition $X .$
Let $X$ be a set with the discrete topology. Determine (with proof) the connected components of $X$ .
Show that a subset of $ℝ$ is connected if and only if it is an interval.
Carefully state the Intermediate Value Theorem.
State and prove the Intermediate Value Theorem.
Let $X$ be a connected topological space and let $f : X \to ℝ$ be a continuous function. Show that if $x, y \in X$ and $r \in ℝ$ such that $f (x) \leq r \leq f (y)$ then there exists $c \in X$ such that $f (c) = r .$
Let $X$ be a topological space. Show that if $X$ is path connected then $X$ is connected.
Let X={(t,sin(πt)) | t∈(0,2]}.
1. Let $φ : ℝ^{2} \to ℝ$ be given by $φ (x, y) = x .$ Show that $φ : X \to (0, 2]$ is a homeomorphism.
2. Show that $X$ is connected.
3. Show that $\overline{X}$ is connected.
4. Show that $\overline{X}$ is not path connected.
Let $p \in ℝ_{\geq 1} .$ Let $V = ℝ^{n}$ with ${‖ (a_{1}, \dots, a_{n}) ‖}_{p} = {({| a_{1} |}^{p} + \dots + {| a_{n} |}^{p})}^{\frac{1}{p}} .$ Show that $(V, {‖ ‖}_{p})$ is a Banach space.
Let $V = ℝ^{n}$ with ${‖ (a_{1}, \dots, a_{n}) ‖}_{\infty} = sup {| a_{1} |, | a_{2} |, \dots, | a_{n} |} .$ Show that $(V, {‖ ‖}_{\infty})$ is a Banach space.
Let $ℓ^{p}$ be the vector space of sequences $(a_{1}, a_{2}, \dots)$ in $ℝ$ such that $\sum_{n \in ℤ_{> 0}} {| a_{n} |}^{p} < \infty .$ Let ${‖ (a_{1}, a_{2}, \dots) ‖}_{q} = {(\sum_{n \in ℤ_{> 0}} {| a_{n} |}^{p})}^{\frac{1}{p}} .$ Show that $(ℓ^{p}, {‖ ‖}_{p})$ is a Banach space.
Let $ℓ^{\infty}$ be the vector space of bounded sequences $(a_{1}, a_{2}, \dots)$ in $ℝ$ with ${‖ (a_{1}, a_{2}, \dots) ‖}_{\infty} = sup {| a_{i} | | i \in ℤ_{> 0}} .$ Show that $(ℓ^{\infty}, {‖ ‖}_{\infty})$ is a Banach space.
Let $X$ be a topological space. Let $F = ℝ$ or $ℂ .$ Let $C_{b} (X, F)$ be the vector space of bounded continuous functions with $‖ f ‖ = sup {| f (x) | | x \in X} .$ Show that $(C_{b} (X, F), ‖ ‖)$ is a Banach space.
Let $(V, ‖ ‖)$ be a normed vector space. Show that $(V, ‖ ‖)$ is a Banach space if and only if every norm absolutely convergent series is convergent.
Let $(V, ‖ ‖)$ be a normed vector space. Show that a Schauder basis of $V$ is a total set.
Let $(V, ‖ ‖)$ be a normed vector space. Show that if $V$ has a Schauder basis then $V$ is separable.
Let $(V, ‖ ‖)$ be a normed vector space. Show that there exists a countable dense set in $V$ is and only if there exists a countable total set in $V .$
Let $e_{i} = (0, 0, \dots, 0, 1, 0, 0, \dots)$ with $1$ in the $i^{th}$ entry. Show that ${e_{1}, e_{2}, e_{3}, \dots}$ is a Schauder basis of $ℓ^{p} .$
Show that $ℓ^{\infty}$ is not separable.
Show that $ℓ^{\infty}$ does not have a Schauder basis.
Let Cb([0,1],ℝ) be the vector space of bounded continuous functions on [0,1].
1. Show that the set of polynomials is dense in the space of continuous functions on $[0, 1]$ with the supremum norm.
2. Show that the polynomials with rational coefficients form a countable dense set in $C_{b} ([0, 1], ℝ) .$
3. Show that $C_{b} ([0, 1], ℝ)$ is separable.
Let (V,‖‖) be a Banach space.
1. Show that if $dim (V) < \infty$ then the closed unit ball in $V$ is compact.
2. Show that if $V$ is infinite dimensional then the closed unit ball in $V$ is not compact.
Let $V$ be a finite dimensional vector space. Let ${‖ ‖}_{1}$ and ${‖ ‖}_{2}$ be norms on $V .$ Show that ${‖ ‖}_{1}$ and ${‖ ‖}_{2}$ are equivalent.
Let $(V, ‖ ‖)$ be a normed vector space. Show that if $V$ is finite dimensional then the closed unit ball in $V$ is compact.
Let $(V, ‖ ‖)$ be an infinite dimensional Banach space. Construct a sequence $(e_{1}, e_{2}, \dots)$ of unit vectors in $V$ such that if $i, j \in ℤ_{> 0}$ and $i \neq j$ then $d (e_{i}, e_{j}) > \frac{1}{2} .$
Let $V = ℂ^{n}$ with $⟨ (x_{1}, x_{2}, \dots, x_{n}), (y_{1}, y_{2}, \dots, y_{n}) ⟩ = \sum_{i = 1}^{n} x_{i} \overline{y_{i}} .$ show that $(V, ⟨ ⟩)$ is a Hilbert space.
Let $ℓ^{2}$ be the set of sequences $(a_{1}, a_{2}, \dots)$ in $ℂ$ such that $\sum_{i \in ℤ_{> 0}} {| a_{i} |}^{2} < \infty .$ Let $⟨ (x_{1}, x_{2}, \dots), (y_{1}, y_{2}, \dots) ⟩ = \sum_{i \in ℤ_{> 0}} x_{i} \overline{y_{i}} .$ Show that $(ℓ^{2}, ⟨ ⟩)$ is a Hilbert space.
Carefully define the space $L^{2} ([a, b])$ and show that if $⟨ f, g ⟩ = \int_{a}^{b} f (t) \overline{g (t)} d t$ then $(L^{2} ([a, b]), ⟨, ⟩)$ is a Hilbert space.
Let $(V, ⟨ ⟩)$ be an inner product space and let $‖ x ‖ = ⟨ x, x ⟩$ for $x \in V .$ Show that if $x, y \in V$ then ${‖ x + y ‖}^{2} + {‖ x - y ‖}^{2} = 2 {‖ x ‖}^{2} + 2 {‖ y ‖}^{2} .$
Let $(V, ‖ ‖)$ be a normed vector space. Define $⟨ x, y ⟩ = \frac{1}{4} ({‖ x + y ‖}^{2} - {‖ x - y ‖}^{2} + i {‖ x + i y ‖}^{2} - i {‖ x - i y ‖}^{2})$ for $x, y \in V .$ Show that if $‖ ‖$ satisfies if $x, y \in V$ then ${‖ x + y ‖}^{2} + {‖ x - y ‖}^{2} = 2 {‖ x ‖}^{2} + 2 {‖ y ‖}^{2}$ then $⟨ ⟩$ is a norm on $V .$
Let $(V, ⟨ ⟩)$ be an inner product space. Show that the Gram-Schmidt process produces an orthonormal basis of $V .$
Let $(V, ⟨ ⟩)$ be an inner product space. Let $W$ be a vector subspace of $V .$ Show that if $W$ admits an orthogonal projection $P$ then $P$ is unique.
Let $(V, ⟨ ⟩)$ be a Hilbert space. Let $W$ be a vector subspace of $V .$ Show that if there is an orthogonal projection $P$ onto $W$ then $W$ is closed.
Let $(V, ⟨ ⟩)$ be a Hilbert space. Let $(a_{1}, a_{2}, \dots)$ be an orthonormal sequence in $V .$ Let $W = span {a_{1}, a_{2}, \dots}$ and let $M = \overline{W}$ be the closure of $W .$ Show that $P : V \to V$ given by $P (x) = \sum_{n \in ℤ_{> 0}} ⟨ x, a_{n} ⟩ a_{n}$ is an orthonormal projection onto $M .$
Let $(V, ⟨ ⟩)$ be a Hilbert space. Let $(a_{1}, a_{2}, \dots)$ be an orthonormal sequence in $V .$ Let $x \in V .$ Show that $P (x) = \sum_{n \in ℤ_{> 0}} ⟨ x, a_{n} ⟩ a_{n}$ is independent of the order of the terms in the sum.
Let $(V, ⟨ ⟩)$ be a Hilbert space. Let $(a_{1}, a_{2}, \dots)$ be an orthonormal sequence in $V .$ Let $x \in V .$ Show that $\sum_{n \in ℤ_{> 0}} {| ⟨ x, a_{n} ⟩ |}^{2} \leq {‖ x ‖}^{2} .$
Let $(V, ⟨ ⟩)$ be a separable Hilbert space. Show that $V$ has a Schauder basis.
Let $(V, ⟨ ⟩)$ be a Hilbert space. Assume that $V$ has a countable orthonormal set ${a_{1}, a_{2}, \dots}$ which is a total set. Show that ${a_{1}, a_{2}, \dots}$ is a Schauder basis for $V .$
Show that the functions $e_{m} (t) = \frac{1}{\sqrt{2 π}} e^{i m t}, for m \in ℤ,$ form an orthonormal basis of $L^{2} ([0, 2 π]) .$
Let $(V, ⟨ ⟩)$ be a Hilbert space and let $W$ be a closed subspace of $V .$ Show that $V = W \oplus W^{⊥} .$
Let $V$ and $W$ be normed vector spaces and let $T : V \to W$ be a linear transformation. Show that if $V$ is finite dimensional then $T$ is bounded.
Let V=C([0,1]) be the vector space of continuous functions f:[0,1]→ℝ with norm given by ‖f‖=∫01 |f(t)|dt. Let T:V→ℝ be given by T(f)=f(0).
1. Show that $V$ is infinite dimensional.
2. Show that $T$ is not bounded.
Let $V, W$ be normed vector spaces and let $T : V \to W$ be a linear transformation. Show that if $T$ is continuous then $T$ is bounded.
Let $V, W$ be normed vector spaces and let $T : V \to W$ be a linear transformation. Show that if $T$ is bounded then $T$ is uniformly continuous.
Let $V, W$ be normed vector spaces. Show the identity operator ${id}_{V} : V \to V$ has operator norm $1$ and the zero operator $0 : V \to W$ has operator norm $0 .$
Let ℓ∞ be the vector space of bounded sequences (a1,a2,…) in ℝ with norm given by ‖(a1,a2,…)‖=sup {|a1|,|a2|,…}. Let (λ1,λ2,…) be a bounded sequence in ℝ. Define T:ℓ∞→ℓ∞ by T(a1,a2,…)= (λ1a1,λ2a2,…).
1. Show that $T$ is a well defined linear transformation.
2. Show that $‖ T ‖ = sup {| λ_{1} |, | λ_{2} |, \dots} .$
Let a,b∈ℝ with a<b. Let k:[a,b]×[a,b]→ℂ be a continuous function. Let X={f:[a,b]→ℂ | f is continuous} with the supremum norm. Define T:X→X by (Tf)(t)=∫abk(t,s)x(s)ds.
1. Show that $X$ is a Banach space.
2. Show that if $f \in X$ then $T f \in X .$
3. Show that $T$ is a bounded linear transformation.
Let $V, W$ be normed vector spaces. Let $B (V, W)$ be the vector space of bounded linear operators with the operator norm. Show that if $W$ is a Banach space then $B (V, W)$ is a Banach space.
Let $a, b \in ℝ$ with $a < b .$ Let $C ([a, b])$ be the vector space of continuous functions $f : [a, b] \to ℂ$ with the supremum norm. Define $T : C ([a, b]) \to ℂ$ by $T f = \int_{a}^{b} f (t) d t$ Show that the operator norm of $T$ is $‖ T ‖ = b - a .$
Let H1 and H2 be Hilbert spaces and let T:H1→H2 be a bounded linear transformation.
1. Show that there exists a unique function $T^{*} : H_{2} \to H_{1}$ such if $x \in H_{1}$ and $y \in H_{2}$ then ${⟨ T x, y ⟩}_{2} = {⟨ x, T^{*} y ⟩}_{1} .$
2. Show that $T^{*}$ is a linear transformation.
3. Show that $T^{*}$ is bounded.
4. Show that $‖ T^{*} ‖ = ‖ T ‖ .$
Let $H$ be a Hilbert space and let $f : H \to ℂ$ be a bounded linear functional. Show that there exists a unique $a \in H$ such that if $x \in H$ then $f (x) = ⟨ x, a ⟩ .$
Let $H_{1}$ and $H_{2}$ be Hilbert spaces and let $T : H_{1} \to H_{2}$ be a bounded linear transformation. Show that ${T^{*}}^{*} = T .$
Let $a, b \in ℝ$ with $a < b .$ Let $C ([a, b])$ be the Banach space of continuous functions $f : [a, b] \to ℝ$ with the supremum norm. Let $t_{0} \in [a, b] .$ Define $A : C ([a, b]) \to ℝ$ by $A f = f (t_{0}) .$ Show that $A$ is a bounded linear functional with $‖ A ‖ = 1 .$
Let T:ℂm→ℂn be a linear transformation. Let A be the matrix of T and let A*=A‾t.
1. Show that the matrix of $T^{*}$ is $A^{*} .$
2. Show that $‖ T ‖ = \sqrt{γ},$ where $γ$ is the largest eigenvalue of $A^{*} A .$
Let $V$ and $W$ be normed vector spaces and let $T : V \to W$ be a bounded linear operator. Show that $T^{*} T$ is self adjoint and positive.
Let $p \in ℝ_{\geq 1}$ and let $q$ be defined by $\frac{1}{p} + \frac{1}{q} = 1 .$ Show that the dual of the Banach space $ℓ^{p}$ is $ℓ^{q} .$
Let $p \in ℝ_{\geq 1} .$ Show that $ℓ^{p}$ is a reflexive Banach space.
Let $X$ be a normed vector space and let $B = {x \in X | ‖ x ‖ \leq 1} .$ Let $T : X \to X$ be a compact operator. Show that $\overline{T (B)}$ is compact.
Let $X$ be a normed vector space and let $A$ be a bounded subset of $X .$ Let $T : X \to X$ be a compact operator. Show that $\overline{T (A)}$ is compact.
Let $X$ be a finite dimensional normed vector space and let $T : X \to X$ be a linear transformation. Show that $T$ is a compact operator.
Let $X = ℂ ([a, b])$ be the space of continuous functions $f : [a, b] \to ℝ$ with the supremum norm. Let $k : [a, b] \times [a, b] \to ℂ$ be a continuous function and define $T : X \to X$ by $(T f) (t) = \int_{a}^{b} k (t, s) f (s) d s$ Show that $T$ is a compact operator.
Let $H$ be a Hilbert space and let $T : H \to H$ be a bounded self adjoint operator. Show that $‖ T ‖ = sup {| ⟨ T x, x ⟩ | | x \in H, ‖ x ‖ = 1} .$
Let H be a Hilbert space and let T:H→H be a nonzero compact self adjoint operator.
1. Show that there exists an eigenvalue $λ$ of $T$ such that $| λ | = ‖ T ‖ .$
2. Show that if $v$ is an eigenvector of $T$ with eigenvalue $λ$ such that $| λ | = ‖ T ‖$ then $v$ is a solution of the extremal problem $max {⟨ T u, u ⟩ | u \in H, ‖ u ‖ = 1} .$
Let $H$ be a Hilbert space and let $T : H \to H$ be a nonzero compact self adjoint operator. Show that there exists an orthonormal basis of eigenvectors for $H .$
Let $H$ be a Hilbert space and let $T : H \to H$ be a nonzero compact self adjoint operator. Let $Λ$ be the set of eigenvalues of $T .$ If $μ \in Λ$ let $P (μ)$ be the orthogonal projection onto the subspace $X_{μ}$ of eigenvectors with eigenvalue $μ .$ Show that if $x \in H$ then $T x = \sum_{μ \in Λ} μ P (μ) x .$
Let $V$ and $W$ be Banach spaces. Let $V'$ be the dual of $V$ and let $W'$ be the dual of $W .$ Let $T : V \to W$ be a bounded linear operator. Define $T^{*} : W' \to V'$ by $T * f = f \circ T .$ Show that $T^{*}$ is a well defined bounded linear operator.
Let $V$ be a Banach space and let $V ″$ be the dual of the dual of $V .$ Define $φ : V \to V ″$ by $(φ (x)) (f) = f (x), for f \in V' .$ Show that $φ$ is injective.
Let V and W be reflexive Banach spaces and let T:V→W be a bounded linear operator.
1. Show that $T$ is transformed to ${T^{*}}^{*}$ by the isomorphisms $V ≅ V ″$ and $W ≅ W ″ .$
2. Show that $‖ T^{*} ‖ = ‖ T ‖ .$
3. Show that if $V$ and $W$ are Hilbert spaces then $T$ is transformed to $T^{*}$ by the natural isomorphisms $V ≅ V'$ and $W ≅ W' .$
Let $H$ be an infinite dimensional Hilbert space. Let $T : H \to H$ be a bounded self adjoint compact operator. Show that the eigenvalues of $T$ form a sequence converging to $0$ and every eigenspace for $T$ is finite dimensional.
Let a,b∈ℝ with a<b. Let λ∈ℝ and let p:[a,b]→ℝ>0 and q:[a,b]→ℝ with p∈C1([a,b]) and q∈C2([a,b]). Let a1,a2,b1,b2∈ℝ with (a1,a2)≠(0,0) and (b1,b2)≠(0,0). Let L:C2([a,b])→C([a,b]) be given by Ly=(-py′)′+qy. Let u,v∈C2([a,b]) such that Lu=0,Lv=0, a1u(a)+a2u′ (a)=0,and b1v(b)+ b2v′(b)=0. Let G:[a,b]×[a,b]→ℝ be given by G(s,t)= { v(t)u(s), if s≤t u(t)v(s), if t≤s. Define T:L2([a,b])→L2([a,b]) by (Tf)(t)= ∫abG(t,s)f(s) ds,for t∈[a,b].
1. Show that the eigenvalues of $T$ are nonzero and each eigenvector $f$ satisfies $a_{1} f (a) + a_{2} f' (a) = 0$ and $b_{1} f (b) + b_{2} f' (b) = 0 .$
2. Show that $f$ is an eigenvector of $T$ with eigenvalue $μ$ if and only if $f$ is an eigenvector of $L$ with eigenvalue $\frac{1}{μ} .$
3. Show that $L$ has a sequence of eigenvalues $λ \to \infty,$ each eigenspace of $L$ is one dimensional and there is an orthonormal basis of $L^{2} ([a, b])$ of eigenvectors of $L .$
Let G:[0,π]×[0,π]→ℝ be given by G(t,s)= { t-stπ, if s≤t, s-stπ, if s≥t and let T:L2([0,π])→L2([0,π]) be given by (Tf)(t)=∫0π G(t,s)f(s)ds fort∈[0,π].
1. Show that $T$ has eigenvalues $λ_{n} = n^{2},$ $n \in ℤ_{> 0},$ and corresponding eigenvectors $s_{n} (t) = \sqrt{\frac{2}{π}} sin n t .$
2. Show that the functions $s_{n} (t) = \sqrt{2 π} sin n t,$ $n \in ℤ_{> 0}$ form an orthonormal basis of $L^{2} ([0, π]) .$

Notes and References

This material is a conversion of the Metric and Hilbert Space notes of J. Hyam Rubinstein into a Homework question form. This is a way to create a curriculum for a course.

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