$Z$ ~ $N(0, 1)$. Find $operatornameVar(Z)$

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$Z$ ~ $N(0, 1)$. Find $operatornameVar(Z)$



We know:



$E(Z) = 0$



$operatornameVar(Z) = E(Z^2) - E(Z)^2 = E(Z^2) - 0^2 = E(Z^2)$



Thus, we need:



$E(Z^2) = int_-infty^infty z^2 frac1sqrt2pie^-1/2(z^2)dz$



Using int by parts, $u = z, du = dz$, then $dv = z frac1sqrt2pie^-1/2z^2dz$, $v = -frac1sqrt2pie^-1/2z^2$



Then we have



$$left[-fraczsqrt2pie^-1/2z^2 right]_-infty^infty + frac1sqrt2piint_-infty^inftye^-1/2z^2dz$$



I'm aware that $left[-fraczsqrt2pie^-1/2z^2 right]_-infty^infty = (0-0) = 0$



No clue how to proceed.







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  • 2




    What does the $1$ in $N(0,1)$ mean to you?
    – Arthur
    Aug 6 at 21:28










  • By definition $N(u, sigma^2)$, so $sigma^2 = 1$
    – Bas bas
    Aug 6 at 21:29







  • 1




    So you got it, right? You know that $sigma^2$ is another notation for Var($Z$)?
    – Arnaud Mortier
    Aug 6 at 21:50











  • Yeah, I understand now thank you.
    – Bas bas
    Aug 6 at 22:04






  • 1




    Yes, but the point of the exercise is to show that the formula for PDF of $N(0,1)$ does have variance $1$.
    – Robert Israel
    Aug 6 at 23:40














up vote
1
down vote

favorite












$Z$ ~ $N(0, 1)$. Find $operatornameVar(Z)$



We know:



$E(Z) = 0$



$operatornameVar(Z) = E(Z^2) - E(Z)^2 = E(Z^2) - 0^2 = E(Z^2)$



Thus, we need:



$E(Z^2) = int_-infty^infty z^2 frac1sqrt2pie^-1/2(z^2)dz$



Using int by parts, $u = z, du = dz$, then $dv = z frac1sqrt2pie^-1/2z^2dz$, $v = -frac1sqrt2pie^-1/2z^2$



Then we have



$$left[-fraczsqrt2pie^-1/2z^2 right]_-infty^infty + frac1sqrt2piint_-infty^inftye^-1/2z^2dz$$



I'm aware that $left[-fraczsqrt2pie^-1/2z^2 right]_-infty^infty = (0-0) = 0$



No clue how to proceed.







share|cite|improve this question

















  • 2




    What does the $1$ in $N(0,1)$ mean to you?
    – Arthur
    Aug 6 at 21:28










  • By definition $N(u, sigma^2)$, so $sigma^2 = 1$
    – Bas bas
    Aug 6 at 21:29







  • 1




    So you got it, right? You know that $sigma^2$ is another notation for Var($Z$)?
    – Arnaud Mortier
    Aug 6 at 21:50











  • Yeah, I understand now thank you.
    – Bas bas
    Aug 6 at 22:04






  • 1




    Yes, but the point of the exercise is to show that the formula for PDF of $N(0,1)$ does have variance $1$.
    – Robert Israel
    Aug 6 at 23:40












up vote
1
down vote

favorite









up vote
1
down vote

favorite











$Z$ ~ $N(0, 1)$. Find $operatornameVar(Z)$



We know:



$E(Z) = 0$



$operatornameVar(Z) = E(Z^2) - E(Z)^2 = E(Z^2) - 0^2 = E(Z^2)$



Thus, we need:



$E(Z^2) = int_-infty^infty z^2 frac1sqrt2pie^-1/2(z^2)dz$



Using int by parts, $u = z, du = dz$, then $dv = z frac1sqrt2pie^-1/2z^2dz$, $v = -frac1sqrt2pie^-1/2z^2$



Then we have



$$left[-fraczsqrt2pie^-1/2z^2 right]_-infty^infty + frac1sqrt2piint_-infty^inftye^-1/2z^2dz$$



I'm aware that $left[-fraczsqrt2pie^-1/2z^2 right]_-infty^infty = (0-0) = 0$



No clue how to proceed.







share|cite|improve this question













$Z$ ~ $N(0, 1)$. Find $operatornameVar(Z)$



We know:



$E(Z) = 0$



$operatornameVar(Z) = E(Z^2) - E(Z)^2 = E(Z^2) - 0^2 = E(Z^2)$



Thus, we need:



$E(Z^2) = int_-infty^infty z^2 frac1sqrt2pie^-1/2(z^2)dz$



Using int by parts, $u = z, du = dz$, then $dv = z frac1sqrt2pie^-1/2z^2dz$, $v = -frac1sqrt2pie^-1/2z^2$



Then we have



$$left[-fraczsqrt2pie^-1/2z^2 right]_-infty^infty + frac1sqrt2piint_-infty^inftye^-1/2z^2dz$$



I'm aware that $left[-fraczsqrt2pie^-1/2z^2 right]_-infty^infty = (0-0) = 0$



No clue how to proceed.









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share|cite|improve this question




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edited Aug 6 at 21:52









Bernard

110k635103




110k635103









asked Aug 6 at 21:22









Bas bas

39611




39611







  • 2




    What does the $1$ in $N(0,1)$ mean to you?
    – Arthur
    Aug 6 at 21:28










  • By definition $N(u, sigma^2)$, so $sigma^2 = 1$
    – Bas bas
    Aug 6 at 21:29







  • 1




    So you got it, right? You know that $sigma^2$ is another notation for Var($Z$)?
    – Arnaud Mortier
    Aug 6 at 21:50











  • Yeah, I understand now thank you.
    – Bas bas
    Aug 6 at 22:04






  • 1




    Yes, but the point of the exercise is to show that the formula for PDF of $N(0,1)$ does have variance $1$.
    – Robert Israel
    Aug 6 at 23:40












  • 2




    What does the $1$ in $N(0,1)$ mean to you?
    – Arthur
    Aug 6 at 21:28










  • By definition $N(u, sigma^2)$, so $sigma^2 = 1$
    – Bas bas
    Aug 6 at 21:29







  • 1




    So you got it, right? You know that $sigma^2$ is another notation for Var($Z$)?
    – Arnaud Mortier
    Aug 6 at 21:50











  • Yeah, I understand now thank you.
    – Bas bas
    Aug 6 at 22:04






  • 1




    Yes, but the point of the exercise is to show that the formula for PDF of $N(0,1)$ does have variance $1$.
    – Robert Israel
    Aug 6 at 23:40







2




2




What does the $1$ in $N(0,1)$ mean to you?
– Arthur
Aug 6 at 21:28




What does the $1$ in $N(0,1)$ mean to you?
– Arthur
Aug 6 at 21:28












By definition $N(u, sigma^2)$, so $sigma^2 = 1$
– Bas bas
Aug 6 at 21:29





By definition $N(u, sigma^2)$, so $sigma^2 = 1$
– Bas bas
Aug 6 at 21:29





1




1




So you got it, right? You know that $sigma^2$ is another notation for Var($Z$)?
– Arnaud Mortier
Aug 6 at 21:50





So you got it, right? You know that $sigma^2$ is another notation for Var($Z$)?
– Arnaud Mortier
Aug 6 at 21:50













Yeah, I understand now thank you.
– Bas bas
Aug 6 at 22:04




Yeah, I understand now thank you.
– Bas bas
Aug 6 at 22:04




1




1




Yes, but the point of the exercise is to show that the formula for PDF of $N(0,1)$ does have variance $1$.
– Robert Israel
Aug 6 at 23:40




Yes, but the point of the exercise is to show that the formula for PDF of $N(0,1)$ does have variance $1$.
– Robert Israel
Aug 6 at 23:40










3 Answers
3






active

oldest

votes

















up vote
1
down vote



accepted










The standard method for evaluating $int_-infty^inftye^-frac12z^2dz$ isn't an obvious one, but one worth remembering. It involves squaring it and turning it into a double integral.



First note that



$$int_-infty^inftye^-frac12z^2dz=2int_0^inftye^-frac12z^2dz$$



as $e^-frac12z^2$ is an even function.



Let $I:=int_0^inftye^-frac12z^2dz$. Also note that "$z$" is just a dummy variable, so $I=int_0^inftye^-frac12x^2dx=int_0^inftye^-frac12y^2dy$.



$$
beginalign
I^2 &= int_0^inftye^-frac12x^2dx int_0^inftye^-frac12y^2dy
\ &= int_0^inftyint_0^inftye^-frac12x^2e^-frac12y^2dxdy
\ &= int_0^inftyint_0^inftye^-frac12(x^2+y^2)dxdy
\ &= int_0^fracpi2int_0^inftye^-frac12r^2rdrdtheta
\ &= fracpi2int_0^inftyre^-frac12r^2dr
\ &= fracpi2 left[ -e^-frac12r^2 right]_0^infty
\ &= fracpi2
endalign
$$



... and hence



$$ I = fracsqrt2pi2 $$



which, together with your working, gives:



$$
beginalign
mathrmVar(Z) &= E(Z^2)
\ &= frac1sqrt2piint_-infty^inftye^-frac12z^2dz
\ &= frac2sqrt2pi I
\ &= 1
endalign
$$



as required!






share|cite|improve this answer




























    up vote
    1
    down vote













    Using Fubini's theorem you can compute $(int e^-x^2)^2$=$pi$ and in the same way that $int e^-fracx^2alpha=sqrtalphapi$, which gives you the result you were looking for.






    share|cite|improve this answer




























      up vote
      -1
      down vote













      The answer is by definition of the law 1.



      Moreover, you are trying to find the variance of a normal law knowing only the mean. Do you think it is even possible ? You could have any positive value for the variance.






      share|cite|improve this answer





















      • It seems you think that no meaningful Question has been posed, or at least that any value could be assigned. It might be a narrow reading of the Question (and perhaps an Answer could outline what additional information is needed for a solution), but merely pointing out a shortcoming would be better executed as a Comment on the the Question than posted as an Answer.
        – hardmath
        Aug 6 at 21:57










      Your Answer




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      3 Answers
      3






      active

      oldest

      votes








      3 Answers
      3






      active

      oldest

      votes









      active

      oldest

      votes






      active

      oldest

      votes








      up vote
      1
      down vote



      accepted










      The standard method for evaluating $int_-infty^inftye^-frac12z^2dz$ isn't an obvious one, but one worth remembering. It involves squaring it and turning it into a double integral.



      First note that



      $$int_-infty^inftye^-frac12z^2dz=2int_0^inftye^-frac12z^2dz$$



      as $e^-frac12z^2$ is an even function.



      Let $I:=int_0^inftye^-frac12z^2dz$. Also note that "$z$" is just a dummy variable, so $I=int_0^inftye^-frac12x^2dx=int_0^inftye^-frac12y^2dy$.



      $$
      beginalign
      I^2 &= int_0^inftye^-frac12x^2dx int_0^inftye^-frac12y^2dy
      \ &= int_0^inftyint_0^inftye^-frac12x^2e^-frac12y^2dxdy
      \ &= int_0^inftyint_0^inftye^-frac12(x^2+y^2)dxdy
      \ &= int_0^fracpi2int_0^inftye^-frac12r^2rdrdtheta
      \ &= fracpi2int_0^inftyre^-frac12r^2dr
      \ &= fracpi2 left[ -e^-frac12r^2 right]_0^infty
      \ &= fracpi2
      endalign
      $$



      ... and hence



      $$ I = fracsqrt2pi2 $$



      which, together with your working, gives:



      $$
      beginalign
      mathrmVar(Z) &= E(Z^2)
      \ &= frac1sqrt2piint_-infty^inftye^-frac12z^2dz
      \ &= frac2sqrt2pi I
      \ &= 1
      endalign
      $$



      as required!






      share|cite|improve this answer

























        up vote
        1
        down vote



        accepted










        The standard method for evaluating $int_-infty^inftye^-frac12z^2dz$ isn't an obvious one, but one worth remembering. It involves squaring it and turning it into a double integral.



        First note that



        $$int_-infty^inftye^-frac12z^2dz=2int_0^inftye^-frac12z^2dz$$



        as $e^-frac12z^2$ is an even function.



        Let $I:=int_0^inftye^-frac12z^2dz$. Also note that "$z$" is just a dummy variable, so $I=int_0^inftye^-frac12x^2dx=int_0^inftye^-frac12y^2dy$.



        $$
        beginalign
        I^2 &= int_0^inftye^-frac12x^2dx int_0^inftye^-frac12y^2dy
        \ &= int_0^inftyint_0^inftye^-frac12x^2e^-frac12y^2dxdy
        \ &= int_0^inftyint_0^inftye^-frac12(x^2+y^2)dxdy
        \ &= int_0^fracpi2int_0^inftye^-frac12r^2rdrdtheta
        \ &= fracpi2int_0^inftyre^-frac12r^2dr
        \ &= fracpi2 left[ -e^-frac12r^2 right]_0^infty
        \ &= fracpi2
        endalign
        $$



        ... and hence



        $$ I = fracsqrt2pi2 $$



        which, together with your working, gives:



        $$
        beginalign
        mathrmVar(Z) &= E(Z^2)
        \ &= frac1sqrt2piint_-infty^inftye^-frac12z^2dz
        \ &= frac2sqrt2pi I
        \ &= 1
        endalign
        $$



        as required!






        share|cite|improve this answer























          up vote
          1
          down vote



          accepted







          up vote
          1
          down vote



          accepted






          The standard method for evaluating $int_-infty^inftye^-frac12z^2dz$ isn't an obvious one, but one worth remembering. It involves squaring it and turning it into a double integral.



          First note that



          $$int_-infty^inftye^-frac12z^2dz=2int_0^inftye^-frac12z^2dz$$



          as $e^-frac12z^2$ is an even function.



          Let $I:=int_0^inftye^-frac12z^2dz$. Also note that "$z$" is just a dummy variable, so $I=int_0^inftye^-frac12x^2dx=int_0^inftye^-frac12y^2dy$.



          $$
          beginalign
          I^2 &= int_0^inftye^-frac12x^2dx int_0^inftye^-frac12y^2dy
          \ &= int_0^inftyint_0^inftye^-frac12x^2e^-frac12y^2dxdy
          \ &= int_0^inftyint_0^inftye^-frac12(x^2+y^2)dxdy
          \ &= int_0^fracpi2int_0^inftye^-frac12r^2rdrdtheta
          \ &= fracpi2int_0^inftyre^-frac12r^2dr
          \ &= fracpi2 left[ -e^-frac12r^2 right]_0^infty
          \ &= fracpi2
          endalign
          $$



          ... and hence



          $$ I = fracsqrt2pi2 $$



          which, together with your working, gives:



          $$
          beginalign
          mathrmVar(Z) &= E(Z^2)
          \ &= frac1sqrt2piint_-infty^inftye^-frac12z^2dz
          \ &= frac2sqrt2pi I
          \ &= 1
          endalign
          $$



          as required!






          share|cite|improve this answer













          The standard method for evaluating $int_-infty^inftye^-frac12z^2dz$ isn't an obvious one, but one worth remembering. It involves squaring it and turning it into a double integral.



          First note that



          $$int_-infty^inftye^-frac12z^2dz=2int_0^inftye^-frac12z^2dz$$



          as $e^-frac12z^2$ is an even function.



          Let $I:=int_0^inftye^-frac12z^2dz$. Also note that "$z$" is just a dummy variable, so $I=int_0^inftye^-frac12x^2dx=int_0^inftye^-frac12y^2dy$.



          $$
          beginalign
          I^2 &= int_0^inftye^-frac12x^2dx int_0^inftye^-frac12y^2dy
          \ &= int_0^inftyint_0^inftye^-frac12x^2e^-frac12y^2dxdy
          \ &= int_0^inftyint_0^inftye^-frac12(x^2+y^2)dxdy
          \ &= int_0^fracpi2int_0^inftye^-frac12r^2rdrdtheta
          \ &= fracpi2int_0^inftyre^-frac12r^2dr
          \ &= fracpi2 left[ -e^-frac12r^2 right]_0^infty
          \ &= fracpi2
          endalign
          $$



          ... and hence



          $$ I = fracsqrt2pi2 $$



          which, together with your working, gives:



          $$
          beginalign
          mathrmVar(Z) &= E(Z^2)
          \ &= frac1sqrt2piint_-infty^inftye^-frac12z^2dz
          \ &= frac2sqrt2pi I
          \ &= 1
          endalign
          $$



          as required!







          share|cite|improve this answer













          share|cite|improve this answer



          share|cite|improve this answer











          answered Aug 6 at 22:08









          Malkin

          1,395523




          1,395523




















              up vote
              1
              down vote













              Using Fubini's theorem you can compute $(int e^-x^2)^2$=$pi$ and in the same way that $int e^-fracx^2alpha=sqrtalphapi$, which gives you the result you were looking for.






              share|cite|improve this answer

























                up vote
                1
                down vote













                Using Fubini's theorem you can compute $(int e^-x^2)^2$=$pi$ and in the same way that $int e^-fracx^2alpha=sqrtalphapi$, which gives you the result you were looking for.






                share|cite|improve this answer























                  up vote
                  1
                  down vote










                  up vote
                  1
                  down vote









                  Using Fubini's theorem you can compute $(int e^-x^2)^2$=$pi$ and in the same way that $int e^-fracx^2alpha=sqrtalphapi$, which gives you the result you were looking for.






                  share|cite|improve this answer













                  Using Fubini's theorem you can compute $(int e^-x^2)^2$=$pi$ and in the same way that $int e^-fracx^2alpha=sqrtalphapi$, which gives you the result you were looking for.







                  share|cite|improve this answer













                  share|cite|improve this answer



                  share|cite|improve this answer











                  answered Aug 6 at 21:44









                  Leo Hö

                  195




                  195




















                      up vote
                      -1
                      down vote













                      The answer is by definition of the law 1.



                      Moreover, you are trying to find the variance of a normal law knowing only the mean. Do you think it is even possible ? You could have any positive value for the variance.






                      share|cite|improve this answer





















                      • It seems you think that no meaningful Question has been posed, or at least that any value could be assigned. It might be a narrow reading of the Question (and perhaps an Answer could outline what additional information is needed for a solution), but merely pointing out a shortcoming would be better executed as a Comment on the the Question than posted as an Answer.
                        – hardmath
                        Aug 6 at 21:57














                      up vote
                      -1
                      down vote













                      The answer is by definition of the law 1.



                      Moreover, you are trying to find the variance of a normal law knowing only the mean. Do you think it is even possible ? You could have any positive value for the variance.






                      share|cite|improve this answer





















                      • It seems you think that no meaningful Question has been posed, or at least that any value could be assigned. It might be a narrow reading of the Question (and perhaps an Answer could outline what additional information is needed for a solution), but merely pointing out a shortcoming would be better executed as a Comment on the the Question than posted as an Answer.
                        – hardmath
                        Aug 6 at 21:57












                      up vote
                      -1
                      down vote










                      up vote
                      -1
                      down vote









                      The answer is by definition of the law 1.



                      Moreover, you are trying to find the variance of a normal law knowing only the mean. Do you think it is even possible ? You could have any positive value for the variance.






                      share|cite|improve this answer













                      The answer is by definition of the law 1.



                      Moreover, you are trying to find the variance of a normal law knowing only the mean. Do you think it is even possible ? You could have any positive value for the variance.







                      share|cite|improve this answer













                      share|cite|improve this answer



                      share|cite|improve this answer











                      answered Aug 6 at 21:32









                      Pjonin

                      3206




                      3206











                      • It seems you think that no meaningful Question has been posed, or at least that any value could be assigned. It might be a narrow reading of the Question (and perhaps an Answer could outline what additional information is needed for a solution), but merely pointing out a shortcoming would be better executed as a Comment on the the Question than posted as an Answer.
                        – hardmath
                        Aug 6 at 21:57
















                      • It seems you think that no meaningful Question has been posed, or at least that any value could be assigned. It might be a narrow reading of the Question (and perhaps an Answer could outline what additional information is needed for a solution), but merely pointing out a shortcoming would be better executed as a Comment on the the Question than posted as an Answer.
                        – hardmath
                        Aug 6 at 21:57















                      It seems you think that no meaningful Question has been posed, or at least that any value could be assigned. It might be a narrow reading of the Question (and perhaps an Answer could outline what additional information is needed for a solution), but merely pointing out a shortcoming would be better executed as a Comment on the the Question than posted as an Answer.
                      – hardmath
                      Aug 6 at 21:57




                      It seems you think that no meaningful Question has been posed, or at least that any value could be assigned. It might be a narrow reading of the Question (and perhaps an Answer could outline what additional information is needed for a solution), but merely pointing out a shortcoming would be better executed as a Comment on the the Question than posted as an Answer.
                      – hardmath
                      Aug 6 at 21:57












                       

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