Double Infinite sum of $1/n^2$












3














I am trying to use an identity we showed on our homework:



$$ sum_{-infty}^{infty} frac{1}{(n+a)^2} = frac{pi^2}{sin^2(pi a)} $$



to show that $$ sum_{1}^{infty} frac{1}{n^2} = frac{pi^2}{6}.$$



I have broken the first double infinite sum into the sum from $-infty$ to $1$ plus the the $0^{th}$ term, plus the sum from $1$ to $+infty$ and then I want to take the limit of $a$ going to $0$.



This results in taking the limit of the following:



$$lim_{ato 0} frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} .$$



Which I know should result in $frac{pi^3}{3}$ from Wolfram Alpha, as desired, but I am struggling with showing it analytically.
My idea was to try and find the Maclaurien Expansion of $sin^2(pi a)$, but then taking that series to the exponent of negative 1 since it is in the denominator is causing issues.
Is there a trick I am not seeing or a possible better way to use the above property to show the other infinite sum?



This question is also for a complex analysis class, so perhaps there is a way to use complex Laurent or power series?










share|cite|improve this question
























  • I am sure that this suggestion would work, but our assignment is that we have to use the first double infinite sum identity to show the second.
    – Tyna
    Nov 20 at 3:46










  • It could help that $$Gamma(z)Gamma(1-z)=frac{pi}{sinpi z}$$
    – clathratus
    Nov 20 at 6:49
















3














I am trying to use an identity we showed on our homework:



$$ sum_{-infty}^{infty} frac{1}{(n+a)^2} = frac{pi^2}{sin^2(pi a)} $$



to show that $$ sum_{1}^{infty} frac{1}{n^2} = frac{pi^2}{6}.$$



I have broken the first double infinite sum into the sum from $-infty$ to $1$ plus the the $0^{th}$ term, plus the sum from $1$ to $+infty$ and then I want to take the limit of $a$ going to $0$.



This results in taking the limit of the following:



$$lim_{ato 0} frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} .$$



Which I know should result in $frac{pi^3}{3}$ from Wolfram Alpha, as desired, but I am struggling with showing it analytically.
My idea was to try and find the Maclaurien Expansion of $sin^2(pi a)$, but then taking that series to the exponent of negative 1 since it is in the denominator is causing issues.
Is there a trick I am not seeing or a possible better way to use the above property to show the other infinite sum?



This question is also for a complex analysis class, so perhaps there is a way to use complex Laurent or power series?










share|cite|improve this question
























  • I am sure that this suggestion would work, but our assignment is that we have to use the first double infinite sum identity to show the second.
    – Tyna
    Nov 20 at 3:46










  • It could help that $$Gamma(z)Gamma(1-z)=frac{pi}{sinpi z}$$
    – clathratus
    Nov 20 at 6:49














3












3








3


1





I am trying to use an identity we showed on our homework:



$$ sum_{-infty}^{infty} frac{1}{(n+a)^2} = frac{pi^2}{sin^2(pi a)} $$



to show that $$ sum_{1}^{infty} frac{1}{n^2} = frac{pi^2}{6}.$$



I have broken the first double infinite sum into the sum from $-infty$ to $1$ plus the the $0^{th}$ term, plus the sum from $1$ to $+infty$ and then I want to take the limit of $a$ going to $0$.



This results in taking the limit of the following:



$$lim_{ato 0} frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} .$$



Which I know should result in $frac{pi^3}{3}$ from Wolfram Alpha, as desired, but I am struggling with showing it analytically.
My idea was to try and find the Maclaurien Expansion of $sin^2(pi a)$, but then taking that series to the exponent of negative 1 since it is in the denominator is causing issues.
Is there a trick I am not seeing or a possible better way to use the above property to show the other infinite sum?



This question is also for a complex analysis class, so perhaps there is a way to use complex Laurent or power series?










share|cite|improve this question















I am trying to use an identity we showed on our homework:



$$ sum_{-infty}^{infty} frac{1}{(n+a)^2} = frac{pi^2}{sin^2(pi a)} $$



to show that $$ sum_{1}^{infty} frac{1}{n^2} = frac{pi^2}{6}.$$



I have broken the first double infinite sum into the sum from $-infty$ to $1$ plus the the $0^{th}$ term, plus the sum from $1$ to $+infty$ and then I want to take the limit of $a$ going to $0$.



This results in taking the limit of the following:



$$lim_{ato 0} frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} .$$



Which I know should result in $frac{pi^3}{3}$ from Wolfram Alpha, as desired, but I am struggling with showing it analytically.
My idea was to try and find the Maclaurien Expansion of $sin^2(pi a)$, but then taking that series to the exponent of negative 1 since it is in the denominator is causing issues.
Is there a trick I am not seeing or a possible better way to use the above property to show the other infinite sum?



This question is also for a complex analysis class, so perhaps there is a way to use complex Laurent or power series?







sequences-and-series limits power-series






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edited Nov 20 at 3:44









Tianlalu

3,12321038




3,12321038










asked Nov 20 at 3:39









Tyna

876




876












  • I am sure that this suggestion would work, but our assignment is that we have to use the first double infinite sum identity to show the second.
    – Tyna
    Nov 20 at 3:46










  • It could help that $$Gamma(z)Gamma(1-z)=frac{pi}{sinpi z}$$
    – clathratus
    Nov 20 at 6:49


















  • I am sure that this suggestion would work, but our assignment is that we have to use the first double infinite sum identity to show the second.
    – Tyna
    Nov 20 at 3:46










  • It could help that $$Gamma(z)Gamma(1-z)=frac{pi}{sinpi z}$$
    – clathratus
    Nov 20 at 6:49
















I am sure that this suggestion would work, but our assignment is that we have to use the first double infinite sum identity to show the second.
– Tyna
Nov 20 at 3:46




I am sure that this suggestion would work, but our assignment is that we have to use the first double infinite sum identity to show the second.
– Tyna
Nov 20 at 3:46












It could help that $$Gamma(z)Gamma(1-z)=frac{pi}{sinpi z}$$
– clathratus
Nov 20 at 6:49




It could help that $$Gamma(z)Gamma(1-z)=frac{pi}{sinpi z}$$
– clathratus
Nov 20 at 6:49










3 Answers
3






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oldest

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3














Follow your thought,
$$
lim_{ato 0}frac {pi^2}{sin^2(pi a)}-frac 1{a^2} = lim_{ato 0}frac {a^2pi^2 - sin^2(pi a)}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api - sin(pi a))(pi a + sin (pi a))}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api)^3/6 times 2pi a}{a^4pi^2 }= frac {pi^2} 3.
$$

However you should prove that
$$
lim_{ato 0}sum_{-infty}^{+infty} frac 1{(n+a)^2 } = sum_{-infty}^{+infty} lim_{ato 0}frac 1{(n+a)^2 } = sum_{-infty}^{+infty} frac 1{n^2}.
$$






share|cite|improve this answer





















  • Thank you!! i didn't see the splitting the numerator up into the $(a^2 -b^2) = (a-b)(a+b)$ form!
    – Tyna
    Nov 20 at 4:50



















2














Put $a=frac12$,



$$sum_{n=-infty}^infty frac1{(n+frac12)^2}=sum_{n=-infty}^infty frac4{(2n+1)^2}=pi^2impliessum_{n=-infty}^infty frac1{(2n+1)^2}=frac{pi^2}{4}.$$
Notice
$$sum_{n=-infty}^infty frac1{(2n+1)^2}=left(sum_{n=-infty}^{-1}+sum_{n=0}^inftyright)frac1{(2n+1)^2}=
2sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}{4}$$

implies
$$sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}8.$$



Let $S=sumlimits_{n=1}^inftyfrac 1{n^2}$, separate $S$ into odd and even terms,
begin{align*}
underbrace{sum_{n=1}^infty frac1{n^2}}_{=S}&=sum_{n=0}^infty frac1{(2n+1)^2}+underbrace{sum_{n=1}^infty frac1{(2n)^2}}_{=frac14 S}\
S&=frac{pi^2}8+frac 14 S\
S&=frac{pi^2}{6}.
end{align*}






share|cite|improve this answer































    0














    Your idea of using Taylor expansions is good.



    Let us compose the series around $a=0$
    $$sin(pi a)=pi a-frac{pi ^3 a^3}{6}+frac{pi ^5 a^5}{120}+Oleft(a^7right)$$
    $$sin^2(pi a)=pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right)$$
    $$frac{pi^2}{sin^2(pi a)}=frac{pi^2}{pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right) }=frac{1}{a^2}+frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$
    $$frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} =frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$ which shows both the limit and also how it is approached.



    Try with $a=frac 16$ which is "large". The exact value would be $4 pi ^2-36approx 3.47842$ while the expansion would give $frac{pi ^2}{3}+frac{pi ^4}{540}approx 3.47026$.






    share|cite|improve this answer





















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      3 Answers
      3






      active

      oldest

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      3 Answers
      3






      active

      oldest

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      active

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      active

      oldest

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      3














      Follow your thought,
      $$
      lim_{ato 0}frac {pi^2}{sin^2(pi a)}-frac 1{a^2} = lim_{ato 0}frac {a^2pi^2 - sin^2(pi a)}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api - sin(pi a))(pi a + sin (pi a))}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api)^3/6 times 2pi a}{a^4pi^2 }= frac {pi^2} 3.
      $$

      However you should prove that
      $$
      lim_{ato 0}sum_{-infty}^{+infty} frac 1{(n+a)^2 } = sum_{-infty}^{+infty} lim_{ato 0}frac 1{(n+a)^2 } = sum_{-infty}^{+infty} frac 1{n^2}.
      $$






      share|cite|improve this answer





















      • Thank you!! i didn't see the splitting the numerator up into the $(a^2 -b^2) = (a-b)(a+b)$ form!
        – Tyna
        Nov 20 at 4:50
















      3














      Follow your thought,
      $$
      lim_{ato 0}frac {pi^2}{sin^2(pi a)}-frac 1{a^2} = lim_{ato 0}frac {a^2pi^2 - sin^2(pi a)}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api - sin(pi a))(pi a + sin (pi a))}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api)^3/6 times 2pi a}{a^4pi^2 }= frac {pi^2} 3.
      $$

      However you should prove that
      $$
      lim_{ato 0}sum_{-infty}^{+infty} frac 1{(n+a)^2 } = sum_{-infty}^{+infty} lim_{ato 0}frac 1{(n+a)^2 } = sum_{-infty}^{+infty} frac 1{n^2}.
      $$






      share|cite|improve this answer





















      • Thank you!! i didn't see the splitting the numerator up into the $(a^2 -b^2) = (a-b)(a+b)$ form!
        – Tyna
        Nov 20 at 4:50














      3












      3








      3






      Follow your thought,
      $$
      lim_{ato 0}frac {pi^2}{sin^2(pi a)}-frac 1{a^2} = lim_{ato 0}frac {a^2pi^2 - sin^2(pi a)}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api - sin(pi a))(pi a + sin (pi a))}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api)^3/6 times 2pi a}{a^4pi^2 }= frac {pi^2} 3.
      $$

      However you should prove that
      $$
      lim_{ato 0}sum_{-infty}^{+infty} frac 1{(n+a)^2 } = sum_{-infty}^{+infty} lim_{ato 0}frac 1{(n+a)^2 } = sum_{-infty}^{+infty} frac 1{n^2}.
      $$






      share|cite|improve this answer












      Follow your thought,
      $$
      lim_{ato 0}frac {pi^2}{sin^2(pi a)}-frac 1{a^2} = lim_{ato 0}frac {a^2pi^2 - sin^2(pi a)}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api - sin(pi a))(pi a + sin (pi a))}{a^2 sin^2(pi a)} = lim_{ato 0}frac {(api)^3/6 times 2pi a}{a^4pi^2 }= frac {pi^2} 3.
      $$

      However you should prove that
      $$
      lim_{ato 0}sum_{-infty}^{+infty} frac 1{(n+a)^2 } = sum_{-infty}^{+infty} lim_{ato 0}frac 1{(n+a)^2 } = sum_{-infty}^{+infty} frac 1{n^2}.
      $$







      share|cite|improve this answer












      share|cite|improve this answer



      share|cite|improve this answer










      answered Nov 20 at 4:04









      xbh

      5,6551522




      5,6551522












      • Thank you!! i didn't see the splitting the numerator up into the $(a^2 -b^2) = (a-b)(a+b)$ form!
        – Tyna
        Nov 20 at 4:50


















      • Thank you!! i didn't see the splitting the numerator up into the $(a^2 -b^2) = (a-b)(a+b)$ form!
        – Tyna
        Nov 20 at 4:50
















      Thank you!! i didn't see the splitting the numerator up into the $(a^2 -b^2) = (a-b)(a+b)$ form!
      – Tyna
      Nov 20 at 4:50




      Thank you!! i didn't see the splitting the numerator up into the $(a^2 -b^2) = (a-b)(a+b)$ form!
      – Tyna
      Nov 20 at 4:50











      2














      Put $a=frac12$,



      $$sum_{n=-infty}^infty frac1{(n+frac12)^2}=sum_{n=-infty}^infty frac4{(2n+1)^2}=pi^2impliessum_{n=-infty}^infty frac1{(2n+1)^2}=frac{pi^2}{4}.$$
      Notice
      $$sum_{n=-infty}^infty frac1{(2n+1)^2}=left(sum_{n=-infty}^{-1}+sum_{n=0}^inftyright)frac1{(2n+1)^2}=
      2sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}{4}$$

      implies
      $$sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}8.$$



      Let $S=sumlimits_{n=1}^inftyfrac 1{n^2}$, separate $S$ into odd and even terms,
      begin{align*}
      underbrace{sum_{n=1}^infty frac1{n^2}}_{=S}&=sum_{n=0}^infty frac1{(2n+1)^2}+underbrace{sum_{n=1}^infty frac1{(2n)^2}}_{=frac14 S}\
      S&=frac{pi^2}8+frac 14 S\
      S&=frac{pi^2}{6}.
      end{align*}






      share|cite|improve this answer




























        2














        Put $a=frac12$,



        $$sum_{n=-infty}^infty frac1{(n+frac12)^2}=sum_{n=-infty}^infty frac4{(2n+1)^2}=pi^2impliessum_{n=-infty}^infty frac1{(2n+1)^2}=frac{pi^2}{4}.$$
        Notice
        $$sum_{n=-infty}^infty frac1{(2n+1)^2}=left(sum_{n=-infty}^{-1}+sum_{n=0}^inftyright)frac1{(2n+1)^2}=
        2sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}{4}$$

        implies
        $$sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}8.$$



        Let $S=sumlimits_{n=1}^inftyfrac 1{n^2}$, separate $S$ into odd and even terms,
        begin{align*}
        underbrace{sum_{n=1}^infty frac1{n^2}}_{=S}&=sum_{n=0}^infty frac1{(2n+1)^2}+underbrace{sum_{n=1}^infty frac1{(2n)^2}}_{=frac14 S}\
        S&=frac{pi^2}8+frac 14 S\
        S&=frac{pi^2}{6}.
        end{align*}






        share|cite|improve this answer


























          2












          2








          2






          Put $a=frac12$,



          $$sum_{n=-infty}^infty frac1{(n+frac12)^2}=sum_{n=-infty}^infty frac4{(2n+1)^2}=pi^2impliessum_{n=-infty}^infty frac1{(2n+1)^2}=frac{pi^2}{4}.$$
          Notice
          $$sum_{n=-infty}^infty frac1{(2n+1)^2}=left(sum_{n=-infty}^{-1}+sum_{n=0}^inftyright)frac1{(2n+1)^2}=
          2sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}{4}$$

          implies
          $$sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}8.$$



          Let $S=sumlimits_{n=1}^inftyfrac 1{n^2}$, separate $S$ into odd and even terms,
          begin{align*}
          underbrace{sum_{n=1}^infty frac1{n^2}}_{=S}&=sum_{n=0}^infty frac1{(2n+1)^2}+underbrace{sum_{n=1}^infty frac1{(2n)^2}}_{=frac14 S}\
          S&=frac{pi^2}8+frac 14 S\
          S&=frac{pi^2}{6}.
          end{align*}






          share|cite|improve this answer














          Put $a=frac12$,



          $$sum_{n=-infty}^infty frac1{(n+frac12)^2}=sum_{n=-infty}^infty frac4{(2n+1)^2}=pi^2impliessum_{n=-infty}^infty frac1{(2n+1)^2}=frac{pi^2}{4}.$$
          Notice
          $$sum_{n=-infty}^infty frac1{(2n+1)^2}=left(sum_{n=-infty}^{-1}+sum_{n=0}^inftyright)frac1{(2n+1)^2}=
          2sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}{4}$$

          implies
          $$sum_{n=0}^infty frac1{(2n+1)^2}=frac{pi^2}8.$$



          Let $S=sumlimits_{n=1}^inftyfrac 1{n^2}$, separate $S$ into odd and even terms,
          begin{align*}
          underbrace{sum_{n=1}^infty frac1{n^2}}_{=S}&=sum_{n=0}^infty frac1{(2n+1)^2}+underbrace{sum_{n=1}^infty frac1{(2n)^2}}_{=frac14 S}\
          S&=frac{pi^2}8+frac 14 S\
          S&=frac{pi^2}{6}.
          end{align*}







          share|cite|improve this answer














          share|cite|improve this answer



          share|cite|improve this answer








          edited Nov 20 at 4:03

























          answered Nov 20 at 3:56









          Tianlalu

          3,12321038




          3,12321038























              0














              Your idea of using Taylor expansions is good.



              Let us compose the series around $a=0$
              $$sin(pi a)=pi a-frac{pi ^3 a^3}{6}+frac{pi ^5 a^5}{120}+Oleft(a^7right)$$
              $$sin^2(pi a)=pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right)$$
              $$frac{pi^2}{sin^2(pi a)}=frac{pi^2}{pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right) }=frac{1}{a^2}+frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$
              $$frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} =frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$ which shows both the limit and also how it is approached.



              Try with $a=frac 16$ which is "large". The exact value would be $4 pi ^2-36approx 3.47842$ while the expansion would give $frac{pi ^2}{3}+frac{pi ^4}{540}approx 3.47026$.






              share|cite|improve this answer


























                0














                Your idea of using Taylor expansions is good.



                Let us compose the series around $a=0$
                $$sin(pi a)=pi a-frac{pi ^3 a^3}{6}+frac{pi ^5 a^5}{120}+Oleft(a^7right)$$
                $$sin^2(pi a)=pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right)$$
                $$frac{pi^2}{sin^2(pi a)}=frac{pi^2}{pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right) }=frac{1}{a^2}+frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$
                $$frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} =frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$ which shows both the limit and also how it is approached.



                Try with $a=frac 16$ which is "large". The exact value would be $4 pi ^2-36approx 3.47842$ while the expansion would give $frac{pi ^2}{3}+frac{pi ^4}{540}approx 3.47026$.






                share|cite|improve this answer
























                  0












                  0








                  0






                  Your idea of using Taylor expansions is good.



                  Let us compose the series around $a=0$
                  $$sin(pi a)=pi a-frac{pi ^3 a^3}{6}+frac{pi ^5 a^5}{120}+Oleft(a^7right)$$
                  $$sin^2(pi a)=pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right)$$
                  $$frac{pi^2}{sin^2(pi a)}=frac{pi^2}{pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right) }=frac{1}{a^2}+frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$
                  $$frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} =frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$ which shows both the limit and also how it is approached.



                  Try with $a=frac 16$ which is "large". The exact value would be $4 pi ^2-36approx 3.47842$ while the expansion would give $frac{pi ^2}{3}+frac{pi ^4}{540}approx 3.47026$.






                  share|cite|improve this answer












                  Your idea of using Taylor expansions is good.



                  Let us compose the series around $a=0$
                  $$sin(pi a)=pi a-frac{pi ^3 a^3}{6}+frac{pi ^5 a^5}{120}+Oleft(a^7right)$$
                  $$sin^2(pi a)=pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right)$$
                  $$frac{pi^2}{sin^2(pi a)}=frac{pi^2}{pi ^2 a^2-frac{pi ^4 a^4}{3}+frac{2 pi ^6 a^6}{45}+Oleft(a^8right) }=frac{1}{a^2}+frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$
                  $$frac{pi^2}{sin^2(pi a)} - frac{1}{a^2} =frac{pi ^2}{3}+frac{pi ^4 a^2}{15}+Oleft(a^4right)$$ which shows both the limit and also how it is approached.



                  Try with $a=frac 16$ which is "large". The exact value would be $4 pi ^2-36approx 3.47842$ while the expansion would give $frac{pi ^2}{3}+frac{pi ^4}{540}approx 3.47026$.







                  share|cite|improve this answer












                  share|cite|improve this answer



                  share|cite|improve this answer










                  answered Nov 20 at 6:56









                  Claude Leibovici

                  119k1157132




                  119k1157132






























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