Prove there is no map $T$ from $L_0[0,1]$ to $mathbb R$ satisfies that $T(fn) to 0$ iff $fn to 0$ a.e. on...












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$begingroup$


Prove there is no map $T$ from $L_{0}[0,1]$ to $mathbb R$ satisfies that $T(fn)to 0$ if and only if fn $to$ $0$

a.e. on $[0,1]$.



L0 means Lebesgue measurable.



Hint: consider the condition that $fn to 0$ in measure or integral while not $fn to 0 a.e. on [0,1]$



Thank you for any helpful idea.










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closed as off-topic by Davide Giraudo, José Carlos Santos, onurcanbektas, jameselmore, Rebellos Dec 13 '18 at 18:12


This question appears to be off-topic. The users who voted to close gave this specific reason:


  • "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Davide Giraudo, José Carlos Santos, onurcanbektas, jameselmore, Rebellos

If this question can be reworded to fit the rules in the help center, please edit the question.





















    1












    $begingroup$


    Prove there is no map $T$ from $L_{0}[0,1]$ to $mathbb R$ satisfies that $T(fn)to 0$ if and only if fn $to$ $0$

    a.e. on $[0,1]$.



    L0 means Lebesgue measurable.



    Hint: consider the condition that $fn to 0$ in measure or integral while not $fn to 0 a.e. on [0,1]$



    Thank you for any helpful idea.










    share|cite|improve this question











    $endgroup$



    closed as off-topic by Davide Giraudo, José Carlos Santos, onurcanbektas, jameselmore, Rebellos Dec 13 '18 at 18:12


    This question appears to be off-topic. The users who voted to close gave this specific reason:


    • "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Davide Giraudo, José Carlos Santos, onurcanbektas, jameselmore, Rebellos

    If this question can be reworded to fit the rules in the help center, please edit the question.



















      1












      1








      1


      2



      $begingroup$


      Prove there is no map $T$ from $L_{0}[0,1]$ to $mathbb R$ satisfies that $T(fn)to 0$ if and only if fn $to$ $0$

      a.e. on $[0,1]$.



      L0 means Lebesgue measurable.



      Hint: consider the condition that $fn to 0$ in measure or integral while not $fn to 0 a.e. on [0,1]$



      Thank you for any helpful idea.










      share|cite|improve this question











      $endgroup$




      Prove there is no map $T$ from $L_{0}[0,1]$ to $mathbb R$ satisfies that $T(fn)to 0$ if and only if fn $to$ $0$

      a.e. on $[0,1]$.



      L0 means Lebesgue measurable.



      Hint: consider the condition that $fn to 0$ in measure or integral while not $fn to 0 a.e. on [0,1]$



      Thank you for any helpful idea.







      real-analysis lebesgue-measure






      share|cite|improve this question















      share|cite|improve this question













      share|cite|improve this question




      share|cite|improve this question








      edited Dec 13 '18 at 14:13







      user10754650

















      asked Dec 13 '18 at 12:57









      user10754650user10754650

      162




      162




      closed as off-topic by Davide Giraudo, José Carlos Santos, onurcanbektas, jameselmore, Rebellos Dec 13 '18 at 18:12


      This question appears to be off-topic. The users who voted to close gave this specific reason:


      • "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Davide Giraudo, José Carlos Santos, onurcanbektas, jameselmore, Rebellos

      If this question can be reworded to fit the rules in the help center, please edit the question.







      closed as off-topic by Davide Giraudo, José Carlos Santos, onurcanbektas, jameselmore, Rebellos Dec 13 '18 at 18:12


      This question appears to be off-topic. The users who voted to close gave this specific reason:


      • "This question is missing context or other details: Please provide additional context, which ideally explains why the question is relevant to you and our community. Some forms of context include: background and motivation, relevant definitions, source, possible strategies, your current progress, why the question is interesting or important, etc." – Davide Giraudo, José Carlos Santos, onurcanbektas, jameselmore, Rebellos

      If this question can be reworded to fit the rules in the help center, please edit the question.






















          2 Answers
          2






          active

          oldest

          votes


















          0












          $begingroup$

          $L_0[0,1]$ is the same as $U[0,1]$ probability distribution. If there is a map $T$ such that $T(f_n)rightarrow 0 iff f_nrightarrow 0$ a.s. then consider a sequence of random variables $X_n$ and a random variable $X$ on $[0,1]$ such that $X_nrightarrow X$ in probability $L_0[0,1]$, but not $X_nrightarrow X$ almost surely. Then for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $X_{n_{k_l}}rightarrow X$ alomst surely. This implies for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $T(X_{n_{k_l}}-X)rightarrow 0$. So, we get that $T(X_n-X)rightarrow 0Rightarrow X_nrightarrow X$ almost surely, which is a contradiction.






          share|cite|improve this answer









          $endgroup$













          • $begingroup$
            Your first statement is a bit confusing; I think what you mean to say is that $f_n to f$ in $L^0$ is the same as $f_n to f$ in measure.
            $endgroup$
            – Ian
            Dec 13 '18 at 13:55










          • $begingroup$
            $U[0,1]$ is a uniform probability distribution over $[0,1].$
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:38










          • $begingroup$
            And I clearly mentioned when I said in probability convergence and when I said almost sure convergence.
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:39










          • $begingroup$
            I just meant the first sentence in isolation, I still don't know what exactly you are trying to say there. Perhaps that $L^0[0,1]$ can be interpreted as all measurable functions of a $U[0,1]$ random variable?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:08










          • $begingroup$
            How could you conclude T(Xn-X)->0 from T(Xnkl -X)->0 ?
            $endgroup$
            – user10754650
            Dec 18 '18 at 6:09



















          0












          $begingroup$

          Suppose $T$ exists and take $fin text{Ker}(T)setminus {0}$. As $f$ is non zero we have $|f|geq ccdot 1_A$ for some set $A$ of positive measure and some positive $c$. Then is easy to show that $ncdot fnot rightarrow 0$ even though $T(ncdot f)rightarrow T(0)$.






          share|cite|improve this answer









          $endgroup$













          • $begingroup$
            Where did you get that $T$ would have nontrivial kernel?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:09






          • 1




            $begingroup$
            Because of a dimension argument. If $T$ is injective you are including $L_0[0,1]$ as a vector subspace of $mathbb{R}$ of dimension 1.
            $endgroup$
            – Yesterday was dramatic
            Dec 13 '18 at 17:24


















          2 Answers
          2






          active

          oldest

          votes








          2 Answers
          2






          active

          oldest

          votes









          active

          oldest

          votes






          active

          oldest

          votes









          0












          $begingroup$

          $L_0[0,1]$ is the same as $U[0,1]$ probability distribution. If there is a map $T$ such that $T(f_n)rightarrow 0 iff f_nrightarrow 0$ a.s. then consider a sequence of random variables $X_n$ and a random variable $X$ on $[0,1]$ such that $X_nrightarrow X$ in probability $L_0[0,1]$, but not $X_nrightarrow X$ almost surely. Then for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $X_{n_{k_l}}rightarrow X$ alomst surely. This implies for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $T(X_{n_{k_l}}-X)rightarrow 0$. So, we get that $T(X_n-X)rightarrow 0Rightarrow X_nrightarrow X$ almost surely, which is a contradiction.






          share|cite|improve this answer









          $endgroup$













          • $begingroup$
            Your first statement is a bit confusing; I think what you mean to say is that $f_n to f$ in $L^0$ is the same as $f_n to f$ in measure.
            $endgroup$
            – Ian
            Dec 13 '18 at 13:55










          • $begingroup$
            $U[0,1]$ is a uniform probability distribution over $[0,1].$
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:38










          • $begingroup$
            And I clearly mentioned when I said in probability convergence and when I said almost sure convergence.
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:39










          • $begingroup$
            I just meant the first sentence in isolation, I still don't know what exactly you are trying to say there. Perhaps that $L^0[0,1]$ can be interpreted as all measurable functions of a $U[0,1]$ random variable?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:08










          • $begingroup$
            How could you conclude T(Xn-X)->0 from T(Xnkl -X)->0 ?
            $endgroup$
            – user10754650
            Dec 18 '18 at 6:09
















          0












          $begingroup$

          $L_0[0,1]$ is the same as $U[0,1]$ probability distribution. If there is a map $T$ such that $T(f_n)rightarrow 0 iff f_nrightarrow 0$ a.s. then consider a sequence of random variables $X_n$ and a random variable $X$ on $[0,1]$ such that $X_nrightarrow X$ in probability $L_0[0,1]$, but not $X_nrightarrow X$ almost surely. Then for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $X_{n_{k_l}}rightarrow X$ alomst surely. This implies for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $T(X_{n_{k_l}}-X)rightarrow 0$. So, we get that $T(X_n-X)rightarrow 0Rightarrow X_nrightarrow X$ almost surely, which is a contradiction.






          share|cite|improve this answer









          $endgroup$













          • $begingroup$
            Your first statement is a bit confusing; I think what you mean to say is that $f_n to f$ in $L^0$ is the same as $f_n to f$ in measure.
            $endgroup$
            – Ian
            Dec 13 '18 at 13:55










          • $begingroup$
            $U[0,1]$ is a uniform probability distribution over $[0,1].$
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:38










          • $begingroup$
            And I clearly mentioned when I said in probability convergence and when I said almost sure convergence.
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:39










          • $begingroup$
            I just meant the first sentence in isolation, I still don't know what exactly you are trying to say there. Perhaps that $L^0[0,1]$ can be interpreted as all measurable functions of a $U[0,1]$ random variable?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:08










          • $begingroup$
            How could you conclude T(Xn-X)->0 from T(Xnkl -X)->0 ?
            $endgroup$
            – user10754650
            Dec 18 '18 at 6:09














          0












          0








          0





          $begingroup$

          $L_0[0,1]$ is the same as $U[0,1]$ probability distribution. If there is a map $T$ such that $T(f_n)rightarrow 0 iff f_nrightarrow 0$ a.s. then consider a sequence of random variables $X_n$ and a random variable $X$ on $[0,1]$ such that $X_nrightarrow X$ in probability $L_0[0,1]$, but not $X_nrightarrow X$ almost surely. Then for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $X_{n_{k_l}}rightarrow X$ alomst surely. This implies for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $T(X_{n_{k_l}}-X)rightarrow 0$. So, we get that $T(X_n-X)rightarrow 0Rightarrow X_nrightarrow X$ almost surely, which is a contradiction.






          share|cite|improve this answer









          $endgroup$



          $L_0[0,1]$ is the same as $U[0,1]$ probability distribution. If there is a map $T$ such that $T(f_n)rightarrow 0 iff f_nrightarrow 0$ a.s. then consider a sequence of random variables $X_n$ and a random variable $X$ on $[0,1]$ such that $X_nrightarrow X$ in probability $L_0[0,1]$, but not $X_nrightarrow X$ almost surely. Then for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $X_{n_{k_l}}rightarrow X$ alomst surely. This implies for any sub-sequence $n_k$ there is a further sub-sequence $n_{k_l}$ such that $T(X_{n_{k_l}}-X)rightarrow 0$. So, we get that $T(X_n-X)rightarrow 0Rightarrow X_nrightarrow X$ almost surely, which is a contradiction.







          share|cite|improve this answer












          share|cite|improve this answer



          share|cite|improve this answer










          answered Dec 13 '18 at 13:46









          John_WickJohn_Wick

          1,621111




          1,621111












          • $begingroup$
            Your first statement is a bit confusing; I think what you mean to say is that $f_n to f$ in $L^0$ is the same as $f_n to f$ in measure.
            $endgroup$
            – Ian
            Dec 13 '18 at 13:55










          • $begingroup$
            $U[0,1]$ is a uniform probability distribution over $[0,1].$
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:38










          • $begingroup$
            And I clearly mentioned when I said in probability convergence and when I said almost sure convergence.
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:39










          • $begingroup$
            I just meant the first sentence in isolation, I still don't know what exactly you are trying to say there. Perhaps that $L^0[0,1]$ can be interpreted as all measurable functions of a $U[0,1]$ random variable?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:08










          • $begingroup$
            How could you conclude T(Xn-X)->0 from T(Xnkl -X)->0 ?
            $endgroup$
            – user10754650
            Dec 18 '18 at 6:09


















          • $begingroup$
            Your first statement is a bit confusing; I think what you mean to say is that $f_n to f$ in $L^0$ is the same as $f_n to f$ in measure.
            $endgroup$
            – Ian
            Dec 13 '18 at 13:55










          • $begingroup$
            $U[0,1]$ is a uniform probability distribution over $[0,1].$
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:38










          • $begingroup$
            And I clearly mentioned when I said in probability convergence and when I said almost sure convergence.
            $endgroup$
            – John_Wick
            Dec 13 '18 at 14:39










          • $begingroup$
            I just meant the first sentence in isolation, I still don't know what exactly you are trying to say there. Perhaps that $L^0[0,1]$ can be interpreted as all measurable functions of a $U[0,1]$ random variable?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:08










          • $begingroup$
            How could you conclude T(Xn-X)->0 from T(Xnkl -X)->0 ?
            $endgroup$
            – user10754650
            Dec 18 '18 at 6:09
















          $begingroup$
          Your first statement is a bit confusing; I think what you mean to say is that $f_n to f$ in $L^0$ is the same as $f_n to f$ in measure.
          $endgroup$
          – Ian
          Dec 13 '18 at 13:55




          $begingroup$
          Your first statement is a bit confusing; I think what you mean to say is that $f_n to f$ in $L^0$ is the same as $f_n to f$ in measure.
          $endgroup$
          – Ian
          Dec 13 '18 at 13:55












          $begingroup$
          $U[0,1]$ is a uniform probability distribution over $[0,1].$
          $endgroup$
          – John_Wick
          Dec 13 '18 at 14:38




          $begingroup$
          $U[0,1]$ is a uniform probability distribution over $[0,1].$
          $endgroup$
          – John_Wick
          Dec 13 '18 at 14:38












          $begingroup$
          And I clearly mentioned when I said in probability convergence and when I said almost sure convergence.
          $endgroup$
          – John_Wick
          Dec 13 '18 at 14:39




          $begingroup$
          And I clearly mentioned when I said in probability convergence and when I said almost sure convergence.
          $endgroup$
          – John_Wick
          Dec 13 '18 at 14:39












          $begingroup$
          I just meant the first sentence in isolation, I still don't know what exactly you are trying to say there. Perhaps that $L^0[0,1]$ can be interpreted as all measurable functions of a $U[0,1]$ random variable?
          $endgroup$
          – Ian
          Dec 13 '18 at 17:08




          $begingroup$
          I just meant the first sentence in isolation, I still don't know what exactly you are trying to say there. Perhaps that $L^0[0,1]$ can be interpreted as all measurable functions of a $U[0,1]$ random variable?
          $endgroup$
          – Ian
          Dec 13 '18 at 17:08












          $begingroup$
          How could you conclude T(Xn-X)->0 from T(Xnkl -X)->0 ?
          $endgroup$
          – user10754650
          Dec 18 '18 at 6:09




          $begingroup$
          How could you conclude T(Xn-X)->0 from T(Xnkl -X)->0 ?
          $endgroup$
          – user10754650
          Dec 18 '18 at 6:09











          0












          $begingroup$

          Suppose $T$ exists and take $fin text{Ker}(T)setminus {0}$. As $f$ is non zero we have $|f|geq ccdot 1_A$ for some set $A$ of positive measure and some positive $c$. Then is easy to show that $ncdot fnot rightarrow 0$ even though $T(ncdot f)rightarrow T(0)$.






          share|cite|improve this answer









          $endgroup$













          • $begingroup$
            Where did you get that $T$ would have nontrivial kernel?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:09






          • 1




            $begingroup$
            Because of a dimension argument. If $T$ is injective you are including $L_0[0,1]$ as a vector subspace of $mathbb{R}$ of dimension 1.
            $endgroup$
            – Yesterday was dramatic
            Dec 13 '18 at 17:24
















          0












          $begingroup$

          Suppose $T$ exists and take $fin text{Ker}(T)setminus {0}$. As $f$ is non zero we have $|f|geq ccdot 1_A$ for some set $A$ of positive measure and some positive $c$. Then is easy to show that $ncdot fnot rightarrow 0$ even though $T(ncdot f)rightarrow T(0)$.






          share|cite|improve this answer









          $endgroup$













          • $begingroup$
            Where did you get that $T$ would have nontrivial kernel?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:09






          • 1




            $begingroup$
            Because of a dimension argument. If $T$ is injective you are including $L_0[0,1]$ as a vector subspace of $mathbb{R}$ of dimension 1.
            $endgroup$
            – Yesterday was dramatic
            Dec 13 '18 at 17:24














          0












          0








          0





          $begingroup$

          Suppose $T$ exists and take $fin text{Ker}(T)setminus {0}$. As $f$ is non zero we have $|f|geq ccdot 1_A$ for some set $A$ of positive measure and some positive $c$. Then is easy to show that $ncdot fnot rightarrow 0$ even though $T(ncdot f)rightarrow T(0)$.






          share|cite|improve this answer









          $endgroup$



          Suppose $T$ exists and take $fin text{Ker}(T)setminus {0}$. As $f$ is non zero we have $|f|geq ccdot 1_A$ for some set $A$ of positive measure and some positive $c$. Then is easy to show that $ncdot fnot rightarrow 0$ even though $T(ncdot f)rightarrow T(0)$.







          share|cite|improve this answer












          share|cite|improve this answer



          share|cite|improve this answer










          answered Dec 13 '18 at 14:58









          Yesterday was dramaticYesterday was dramatic

          960718




          960718












          • $begingroup$
            Where did you get that $T$ would have nontrivial kernel?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:09






          • 1




            $begingroup$
            Because of a dimension argument. If $T$ is injective you are including $L_0[0,1]$ as a vector subspace of $mathbb{R}$ of dimension 1.
            $endgroup$
            – Yesterday was dramatic
            Dec 13 '18 at 17:24


















          • $begingroup$
            Where did you get that $T$ would have nontrivial kernel?
            $endgroup$
            – Ian
            Dec 13 '18 at 17:09






          • 1




            $begingroup$
            Because of a dimension argument. If $T$ is injective you are including $L_0[0,1]$ as a vector subspace of $mathbb{R}$ of dimension 1.
            $endgroup$
            – Yesterday was dramatic
            Dec 13 '18 at 17:24
















          $begingroup$
          Where did you get that $T$ would have nontrivial kernel?
          $endgroup$
          – Ian
          Dec 13 '18 at 17:09




          $begingroup$
          Where did you get that $T$ would have nontrivial kernel?
          $endgroup$
          – Ian
          Dec 13 '18 at 17:09




          1




          1




          $begingroup$
          Because of a dimension argument. If $T$ is injective you are including $L_0[0,1]$ as a vector subspace of $mathbb{R}$ of dimension 1.
          $endgroup$
          – Yesterday was dramatic
          Dec 13 '18 at 17:24




          $begingroup$
          Because of a dimension argument. If $T$ is injective you are including $L_0[0,1]$ as a vector subspace of $mathbb{R}$ of dimension 1.
          $endgroup$
          – Yesterday was dramatic
          Dec 13 '18 at 17:24



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