#24

2C2025 - Teo Integral 1

28 min de lectura

Thu-20-11-2025 08:56 profe: Pablo Turco - Cecilia De Vita | Leonard Ehrhorn - Tomer Damián Cohen Mizrahi - Iván Moyano Tassara
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Lo que quedó pendiente de la teo anterior

Prop. :{\color{Orange} \text{Prop. :} }

Si f,g:ER medibles     f+g medible.\begin{array}{l} \text{Si $f,g:E\to \mathbb{R}$ medibles $\implies f+g$ medible.} \end{array}

Dem:{\color{Orange} \text{Dem:} } Supongamos que {f=+}=={g=±}\{ f=+\infty \}=\emptyset=\{ g=\pm \infty \}

Si aRa \in \mathbb{R} {f+g<a}\{ f+g<a \} es medible Veamos que

{f+g<a}=qQ{f<g}medible{g<aq}medible\{ f+g<a \}=\bigcup_{q \in \mathbb{Q}}\underbrace{ \{ f<g \} }_{ \text{medible} }\cap \underbrace{ \{ g<a-q \} }_{ \text{medible} }

-- 00:00

)\supseteq) Si x{f<q}{q<ag}x \in \{ f<q \}\cap \{ q<a-g \}

    f(x)+g(x)<q+g(x)<ag(x)+g(x)=a\implies f(x)+g(x)<q+g(x)<a-g(x)+g(x)=a

)\subseteq) Usamos esto: AB    XBXAA\subseteq B\implies X \setminus B \subseteq X \setminus A Tomemos xE.x \in E. qQf(x)<q\:\exists\:q \in \mathbb{Q}\bigm|f(x)<q

(qn)nNQf(x)<qnqnf(x)\:\exists\:( q_{n} )_{n \in \mathbb{N}}\subset \mathbb{Q}\bigm| f(x)<q_{n}\land q_{n}\searrow f(x)

Si xqQ{f<q}{g<aq}x\neq \bigcup_{q \in \mathbb{Q}}\{ f<q \}\cap \{ g<a-q \}     f(x)<qn    g(x)aqn\implies f(x)<q_{n}\implies g(x)\geq a- q_{n}

    f(x)+g(x)f(x)+aqnnN\implies f(x)+g(x)\geq f(x)+a-q_{n}\quad\forall n\in \mathbb{N}     f(x)+g(x)f(x)+af(x)=a\implies f(x)+g(x)\geq f(x)+a-f(x)=a     x∉{f+g<a}\implies x \not\in \{ f+g<a \}

Sea φ:ER{\Large\varphi}:E\to \mathbb{R} simple medible y φ0{\Large\varphi}\geq 0 Existe partición finita E1,,EnE_{1},\dots,E_{n} medibles E=i=1˙Ei\bigm|\displaystyle E=\dot{\bigcup_{i=1}}E_{i} y α1,,αn0l=αiXEi    I(l)=i=1nαiμ(Ei)\alpha_{1},\dots,\alpha_{n}\geq 0\bigm|\mathscr{l}=\sum \alpha_{i}\cdot\mathcal{X}_{E_{i}}\implies I(\mathscr{l})=\displaystyle \sum_{i=1}^{n}\alpha_{i}\cdot \mu(E_{i})

Prop. :{\color{Orange} \text{Prop. :} }

Sean φ,ϕ:ER con φ,ϕ0 simples medibles. 1. I(φ+ϕ)=I(φ)+I(ϕ) 2. I(αφ)=αI(φ) \begin{array}{l} \text{Sean ${\Large\varphi},\phi:E\to \mathbb{R}$ con ${\Large\varphi},\phi\geq 0$ simples medibles. }\\ \text{1. $I({\Large\varphi}+\phi)=I({\Large\varphi})+I(\phi )$ } \\ \text{2. $I(\alpha\cdot {\Large\varphi})=\alpha\cdot I({\Large\varphi})$ } \end{array}

Dem 1):{\color{Orange} \text{Dem 1):} } Sean E1,,EnE_{1},\dots,E_{n} medibles disjuntos, α1,,αn0\alpha_{1},\dots,\alpha_{n}\geq 0 D1,...,DmD_{1},...,D_{m} medibles disjuntos β1,,βm0\beta_{1},\cdots,\beta _m\geq 0 tal que

E=n˙Ei=m˙DjE=\dot{\bigcup^n} E_{i} =\dot{\bigcup^m}D_{j} φ=i=1nαiXEi,ϕ=j=1mβjXDj{\Large\varphi}=\sum_{i=1}^{n} \alpha_{i}\cdot\mathcal{X}_{E_{i}} ,\quad \phi=\sum_{j=1}^{m} \beta_{j}\cdot\mathcal{X}_{D_{j}}

Como E=i˙j˙EiDj\displaystyle E=\dot{\bigcup_{i}}\dot{\bigcup_{j}}E_{i}\cap D_{j} y φ+ϕ(x)=αi+βjxEiDj{\Large\varphi}+\phi(x)=\alpha_{i}+\beta_{j}\quad\forall x \in E_{i}\cap D_{j}

    φ+ϕ=i=1nj=1m(αi+βj)XEiDj\implies {\Large\varphi}+\phi=\sum_{i=1}^{n} \sum_{j=1}^{m} (\alpha _{i}+\beta_{j})\cdot \mathcal{X}_{E_{i}\cap D_{j}} I(φ+ϕ)=i=1nj=1m(αi+βj)μ(EiDj)I({\Large\varphi}+\phi)=\sum_{i=1}^{n} \sum_{j=1}^{m} (\alpha_{i}+\beta_{j})\cdot\mu(E_{i}\cap D_{j}) =i=1nj=1mαiμ(EiDj)+βjμ(EiDj)=\sum_{i=1}^{n} \sum_{j=1}^{m} \alpha_{i}\cdot \mu(E_{i}\cap D_{j})+\beta_{j}\cdot \mu(E_{i}\cap D_{j}) =i=1nj=1mαiμ(EiDj)+i=1nj=1mβjμ(EiDj)=\sum_{i=1}^{n} \sum_{j=1}^{m} \alpha_{i}\cdot \mu(E_{i}\cap D_{j})+\sum_{i=1}^{n} \sum_{j=1}^{m}\beta_{j}\cdot \mu(E_{i}\cap D_{j}) =i=1nαij=1mμ(EiDj)+j=1mβji=1nμ(EiDj)=\sum_{i=1}^{n} \alpha_{i}\cdot \sum_{j=1}^{m} \mu(E_{i}\cap D_{j})+\sum_{j=1}^{m} \beta_{j}\sum_{i=1}^{n} \mu(E_{i}\cap D_{j}) =i=1nαiμ(Ei)+j=1mβjμ(Dj)=\sum_{i=1}^{n} \alpha_{i}\cdot \mu(E_{i})+\sum_{j=1}^{m} \beta_{j}\cdot \mu(D_{j}) =I(φ)+I(ϕ)=I({\Large\varphi})+I(\phi)

Def. :{\color{Cyan} \text{Def. :} }

Teorema\begin{array}{l} \text{Teorema} \end{array}

Sea f:ERf:E\to \mathbb{R} medible.

Ef=Efdμ=Ef(x)dμ(x)\int_{E} f =\int_{E} f \, d\mu =\int_{E}f(x) \,\, d\mu(x) =sup{I(φ):0φf,φ simple medible}=\underset{ }{ \sup }\{ I({\Large\varphi}):0\leq {\Large\varphi}\leq f,{\Large\varphi} \text{ simple medible} \}

Prop. :{\color{Orange} \text{Prop. :} }

Si f:ER simple medible con f0Ef=I(f)\begin{array}{l} \text{Si $f:E\to \mathbb{R}$ simple medible con $f\geq 0$}\\ \displaystyle \int_{E} f=I(f) \end{array}

Dem:{\color{Orange} \text{Dem:} }

Ver que si 0φf0\leq {\Large\varphi}\leq f simple medible     I(φ)I(f)\implies I({\Large\varphi})\leq I(f)

Queda como ejercicio.

--46:35, Al final si dió la demo

Sean φ,f:ER{\Large\varphi},f:E\to \mathbb{R} simples medibles.

f=i=1nαiXEiφ=j=1mβjXDjf=\sum_{i=1}^{n} \alpha_{i}\cdot\mathcal{X}_{E_{i}} \quad \quad {\Large\varphi}=\sum_{j=1}^{m} \beta _{j}\cdot\mathcal{X}_{D_{j}} f=i=1nαiXEi˙jDj=i=1nj=1mαiXEiDjf=\sum_{i=1}^{n} \alpha_{i}\cdot \mathcal{X}_{E_{i}\cap\displaystyle \dot{\cup}_{j}D_{j}} =\sum_{i=1}^{n} \sum_{j=1}^{m} \alpha_{i}\cdot\mathcal{X}_{E_{i}\cap D_{j}}

De la misma manera

φ=j=1mi=1nβjXEiDj{\Large\varphi}=\sum_{j=1}^{m} \sum_{i=1}^{n} \beta_{j}\cdot\mathcal{X}_{E_{i}\cap D_{j}}

Si xEiDjx \in E_{i}\cap D_{j} f(x)=αif(x)=\alpha_{i} y φ(x)=βj    αiβj{\Large\varphi}(x)=\beta_{j}\implies\alpha_{i}\geq\beta_{j}

Esto ultimo porque suponemos que fφf\geq {\Large\varphi}

I(φ)=i=1nj=1mBjμ(EiDj)i=1nj=1mαiμ(EiDj)=I(f)I({\Large\varphi})=\sum_{i=1}^{n} \sum_{j=1}^{m} B_{j}\cdot \mu(E_{i}\cap D_{j})\leq \sum_{i=1}^{n} \sum_{j=1}^{m} \alpha_{i}\cdot \mu(E_{i}\cap D_{j})=I(f)

Prop. :{\color{Orange} \text{Prop. :} }

f:ER. Si E es nulo, Efdμ=0 \begin{array}{l} \text{$f:E \to \mathbb{R}$. Si $E$ es nulo, $\displaystyle \int_{E} f \, d\mu=0$ } \end{array}

Dem:{\color{Orange} \text{Dem:} }

Si φ:ER{\Large\varphi}:E\to \mathbb{R} simple tal que φf{\Large\varphi}\leq f

φ=i=1nαiXEiE=˙i=1nEi{\Large\varphi}=\sum_{i=1}^{n} \alpha_{i}\cdot\mathcal{X}_{E_{i}}\quad \quad E=\dot{\bigcup}_{i=1}^n E_{i} I(φ)=i=1nαiμ(Ei)=0=0I({\Large\varphi})=\sum_{i=1}^{n} \alpha_{i}\cdot \underbrace{ \mu(E_{i}) }_{ =0 }=0

Prop. :{\color{Orange} \text{Prop. :} }

Sean f,g:ER medibles con 0fg Efdμ=Egdμ\begin{array}{l} \text{Sean $f,g:E\to \mathbb{R}$ medibles con $0\leq f\leq g$ }\\ \displaystyle \int_{E}f \, d\mu =\int_{E} g \, d\mu \end{array}

Dem:{\color{Orange} \text{Dem:} } Si 0φf0\leq {\Large\varphi}\leq f es simple medible     φg\implies {\Large\varphi}\leq g --59:30

Prop. :{\color{Orange} \text{Prop. :} }

proposicion\begin{array}{l} \text{proposicion} \end{array}

Sea f:ERf:E\to \mathbb{R} medible con f0f\geq 0 y AEA\subseteq E medible.

    Afdμ=EfXAdμ\implies \int_{A} f \, d\mu =\int_{E} f\cdot \mathcal{X}_{A} \, d\mu

Luego

AfdμEfdμ\int_{A} f \, d\mu \leq \int_{E} f \, d\mu

pues fXAff\cdot\mathcal{X}_{A}\leq f

Obs:Obs: Vimos que puede ocurrir que

fnf pero fnff_{n} \longrightarrow f\text{ pero } \int f_{n}\cancel{ \longrightarrow } \int f

Ejemplos:

fn(x)={n2x0x12nn2(1nx)12nx1n0x>1nf_{n}(x)=\begin{cases} n^{2}x & 0\leq x\leq \frac{1}{2n} \\ n^{2}\left( \frac{1}{n}-x \right) & \frac{1}{2n}\leq x \leq \frac{1}{n} \\ 0 & x> \frac{1}{n} \end{cases}

Teorema de convergencia monótona

Sean (fn)nN( f_{n} )_{n \in \mathbb{N}} sucesión de funciones medibles positivas y sea ff medible tal que fnff_{n}\to f
Si fnfn+1nNf_{n}\leq f_{n+1} \quad\forall n\in \mathbb{N} (monótonas crecientes, fnff_{n}\nearrow f) entonces

limnEfndμ=Elimnfndμ=Efdμ\underset{ n\to \infty }{ \lim } \int_{E} f_{n} \, d\mu =\int_{E} \underset{ n\to \infty }{ \lim } f_{n} \, d\mu =\int_{E}f \, d\mu

Dem:Dem:

Se deja como ejercicio.

Teorema :{\color{violet} \text{Teorema :} }

Teorema\begin{array}{l} \text{Teorema} \end{array}

Sean f,g:ERf,g:E\to \mathbb{R} medibles y positivas y sea λ>0\lambda>0. Entonces

Ef+λgdμ=Efdμ+λEgdμ\int_{E} f+\lambda \cdot g \, d\mu =\int_{E} f \, d\mu +\lambda\cdot \int_{E} g \, d\mu

Dem:{\color{violet} \text{Dem:} }

Ef+λgdμ=I(f+λg)=I(f)+λI(g)=Efdμ+λEgdμ\int_{E} f+\lambda g \, d\mu =I(f+\lambda g)=I(f)+\lambda \cdot I(g)=\int_{E} f \, d\mu +\lambda\int_{E} g \, d\mu

Por algo anterior existen (φn)nN( {\Large\varphi}_{n} )_{n \in \mathbb{N}} medibles simples positivas con φnf{\Large\varphi}_{n}\nearrow f Existen (ϕn)nN( \phi_{n} )_{n \in \mathbb{N}} medibles simples positivas tal que ϕng\phi_{n}\nearrow g Luego

φn+λϕnf+λg{\Large\varphi}_{n}+\lambda \cdot \phi_{n}\nearrow f + \lambda \cdot g Ef+λgdμ=Elimnφn+λϕndμ=teor conv monlimnEφn+λϕndμ\int_{E} f+\lambda \cdot g \, d\mu =\int_{E} \underset{ n\to \infty }{ \lim } {\Large\varphi}_{n}+\lambda \cdot \phi_{n} \, d\mu \underbrace{ = }_{ \text{teor conv mon} } \underset{ n\to \infty }{ \lim } \int_{E} {\Large\varphi}_{n} + \lambda \cdot \phi_{n} \, d\mu =φn+λϕn son simpleslimnEφndμ+λEϕndμ=limnEφndμ+λlimnEϕndμ\underset{ {\Large\varphi}_{n}+\lambda \phi_{n }\text{ son simples} }{ = }\underset{ n\to \infty }{ \lim } \int_{E} {\Large\varphi}_{n} \, d\mu +\lambda \int_{E} \phi_{n} \, d\mu =\underset{ n\to \infty }{ \lim } \int_{E} {\Large\varphi}_{n} \, d\mu + \lambda\underset{ n\to \infty }{ \lim } \int_{E} \phi_{n} \, d\mu =teor conv monElimnφndμ+λElimnϕndμ=Efdμ+λEgdμ\underset{ \text{teor conv mon} }{ = } \int_{E} \underset{ n\to \infty }{ \lim } {\Large\varphi}_{n} \, d\mu +\lambda \cdot \int_{E} \underset{ n\to \infty }{ \lim } \phi_{n} \, d\mu =\int_{E} f \, d\mu +\lambda \cdot \int_{E}g \, d\mu

Corolario:{\color{Red}\text{Corolario}:}

Corolario\begin{array}{l} \text{Corolario} \end{array}

Sea f:ERf:E\to \mathbb{R} medible positiva Sean E1,E2EE_{1},E_{2}\subseteq E medibles con E1E2=E_{1}\cap E_{2}=\emptyset

E1˙E2fdμ=E1fdμ+E2fdμ\int_{E_{1}\dot{\bigcup}E_{2}} f \, d\mu =\int_{E_{1}} f \, d\mu +\int_{E_{2}} f \, d\mu

Dem:{\color{Red} \text{Dem}:}

E1˙E2f=EfXE1˙E2=Ef(XE1+XE2)\int_{E_{1}\dot{\cup}E_{2}}f=\int_{E}f \cdot\mathcal{X}_{E_{1}\dot{\cup}E_{2}} =\int_{E}f\cdot (\mathcal{X}_{E_{1}} +\mathcal{X}_{E_{2}} ) =EfXE1+fXE2=EfXE1+EfXE2=E1f+E2f=\int_{E}f\cdot\mathcal{X}_{E_{1}} +f \cdot \mathcal{X}_{E_{2}} =\int_{E}f \cdot \mathcal{X}_{E_{1}} + \int_{E}f \cdot \mathcal{X}_{E_{2}}=\int_{E_{1}}f + \int_{E_{2}}f

Corolario:{\color{Red}\text{Corolario}:}

Corolario\begin{array}{l} \text{Corolario} \end{array}

Sean f,g:ERf,g:E\longrightarrow \mathbb{R} medibles positivas. Si f=gf=g en casi todo punto

Ef=Eg\int_{E} f = \int_{E}g

Dem:{\color{Red} \text{Dem}:} --01:36:00

Ef=E{f=g}f+E{fg}f=E{f=g}g+0Eg\int_{E}f=\int_{E\cap \{ f=g \}} f+ \int_{E\cap \{ f\neq g \}}f=\int_{E\cap \{ f=g \}}g+0 \leq \int_{E}g     EfEg\implies \int_{E}f\leq \int_{E}g

Análogamente empiezo con gg y obtenga la otra desigualdad.

Corolario:{\color{Red}\text{Corolario}:}

Corolario\begin{array}{l} \text{Corolario} \end{array} RXQ=0\int_{\mathbb{R}} \mathcal{X}_{\mathbb{Q}} = 0

Dem:{\color{Red} \text{Dem}:} Como μ(Q)=0    XQ0\mu(\mathbb{Q})= 0\implies\mathcal{X}_{\mathbb{Q}}\equiv0 en casi todo punto. Además E0=0\displaystyle \int_{E}0=0

Corolario:{\color{Red}\text{Corolario}:}

Corolario\begin{array}{l} \text{Corolario} \end{array}

Sea f:ERf:E\longrightarrow \mathbb{R} medible y positiva. Ef=0\displaystyle \int_{E}f=0 si y solo si f=0f=0 en casi todo punto.

Dem:{\color{Red} \text{Dem}:}     )\implies) --01:44:12 Sea En={f>1n}E_{n}=\left\{ f> \frac{1}{n} \right\} medible.

Z={f=0}Z=\{ f=0 \} 0=Ef=Z˙(nEn)f=Zf+nEnf=0+Enf0=\int_{E}f=\int_{Z\dot{\cup}\left( \bigcup_{n}E_{n} \right)} f=\int_{Z}f+\int_{\bigcup_{n}E_{n}}f=0+\int_{\bigcup E_{n}}f Enf>En1n=E1nXEn=1nμ(En)\geq \int_{E_{n}}f> \int_{E_{n}} \frac{1}{n}=\int_{E} \frac{1}{n}\cdot\mathcal{X}_{E_{n}} = \frac{1}{n} \cdot \mu(E_{n})     01nμ(En)0    μ(En)=0\implies_{0}\geq \frac{1}{n}\cdot \mu(E_{n})\geq 0\implies \mu(E_{n})= 0     μ({f0})=μ(nNEn)limnμ(En)=0\implies \mu(\{ f\neq 0 \})=\mu\left( \bigcup_{n\in \mathbb{N}}E_{n} \right)\leq \underset{ n\to \infty }{ \lim } \mu(E_{n})= 0

Obs:Obs: Si f,g0f,g\geq 0 Me gustaría que

fg=fg\int f-g=\int f - \int g

Def. :{\color{Cyan} \text{Def. :} }

Teorema\begin{array}{l} \text{Teorema} \end{array}

Sea f:ERf:E\to \mathbb{R}

f+={f(x)f(x)00f(x)<0,f={f(x)f(x)<00f(x)0f^{+} =\begin{cases} f(x) & f(x)\geq 0 \\ 0 & f(x)< 0 \end{cases},\quad f^{-} =\begin{cases} -f(x) & f(x)< 0 \\ 0 & f(x)\geq 0 \end{cases}

f+0,f0f^{+}\geq 0,f^{-}\geq 0 Además

f=f+ff=f^{+} -f^{-} f+=fX{f0}f=fX{f0}f^{+} =f \cdot \mathcal{X}_{\{ f\geq 0 \}} \quad \quad f^{-} =-f \cdot\mathcal{X}_{\{ f\leq 0 \}}

Def. :{\color{Cyan} \text{Def. :} }

Teorema\begin{array}{l} \text{Teorema} \end{array}

f:ERf:E\to \mathbb{R} medible.

Ef=Ef+Ef\int_{E}f=\int_{E}f^{+} - \int_{E}f^{-}

Ejercicio: Todo lo que hicimos para funciones positivas (f0f\geq 0 ) vale para ff en general

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