Alternating sum of reciprocals of odd squares











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I have been struggling with this problem for a while.



May I ask what is the exact value of this series, if it’s even possible.



$$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$



A proof of some sort would highly be appreciated. Thank you.



Edit:



I found this by trying to evaluate the integral:



$$int_{0}^{infty} frac{ln^2(x)}{1+x^2}dx$$



What I did was I made the above integral into $u = 1/x$:



$$2int_{0}^{1} frac{ln^2(x)}{1+x^2}dx$$



Then I expanded it into a geometric series and took antiderivatives, leading me to the series above.










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  • How did you find this problem? What attempts have you made so far?
    – abiessu
    Nov 13 at 14:06








  • 1




    Do you know $$sum_{n=1}^inftyfrac1{n^2}=frac{pi^2}6;;?$$
    – DonAntonio
    Nov 13 at 14:07










  • Yes I do know the sum of squares and alternating squares reciprocals.
    – Black Blast
    Nov 13 at 14:16










  • See Catalan's constant.
    – projectilemotion
    Nov 13 at 14:23










  • Catalans constant. Thank you
    – Black Blast
    Nov 13 at 14:29















up vote
1
down vote

favorite












I have been struggling with this problem for a while.



May I ask what is the exact value of this series, if it’s even possible.



$$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$



A proof of some sort would highly be appreciated. Thank you.



Edit:



I found this by trying to evaluate the integral:



$$int_{0}^{infty} frac{ln^2(x)}{1+x^2}dx$$



What I did was I made the above integral into $u = 1/x$:



$$2int_{0}^{1} frac{ln^2(x)}{1+x^2}dx$$



Then I expanded it into a geometric series and took antiderivatives, leading me to the series above.










share|cite|improve this question
























  • How did you find this problem? What attempts have you made so far?
    – abiessu
    Nov 13 at 14:06








  • 1




    Do you know $$sum_{n=1}^inftyfrac1{n^2}=frac{pi^2}6;;?$$
    – DonAntonio
    Nov 13 at 14:07










  • Yes I do know the sum of squares and alternating squares reciprocals.
    – Black Blast
    Nov 13 at 14:16










  • See Catalan's constant.
    – projectilemotion
    Nov 13 at 14:23










  • Catalans constant. Thank you
    – Black Blast
    Nov 13 at 14:29













up vote
1
down vote

favorite









up vote
1
down vote

favorite











I have been struggling with this problem for a while.



May I ask what is the exact value of this series, if it’s even possible.



$$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$



A proof of some sort would highly be appreciated. Thank you.



Edit:



I found this by trying to evaluate the integral:



$$int_{0}^{infty} frac{ln^2(x)}{1+x^2}dx$$



What I did was I made the above integral into $u = 1/x$:



$$2int_{0}^{1} frac{ln^2(x)}{1+x^2}dx$$



Then I expanded it into a geometric series and took antiderivatives, leading me to the series above.










share|cite|improve this question















I have been struggling with this problem for a while.



May I ask what is the exact value of this series, if it’s even possible.



$$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$



A proof of some sort would highly be appreciated. Thank you.



Edit:



I found this by trying to evaluate the integral:



$$int_{0}^{infty} frac{ln^2(x)}{1+x^2}dx$$



What I did was I made the above integral into $u = 1/x$:



$$2int_{0}^{1} frac{ln^2(x)}{1+x^2}dx$$



Then I expanded it into a geometric series and took antiderivatives, leading me to the series above.







calculus






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share|cite|improve this question













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edited Nov 13 at 15:20









projectilemotion

11.2k61941




11.2k61941










asked Nov 13 at 14:03









Black Blast

62




62












  • How did you find this problem? What attempts have you made so far?
    – abiessu
    Nov 13 at 14:06








  • 1




    Do you know $$sum_{n=1}^inftyfrac1{n^2}=frac{pi^2}6;;?$$
    – DonAntonio
    Nov 13 at 14:07










  • Yes I do know the sum of squares and alternating squares reciprocals.
    – Black Blast
    Nov 13 at 14:16










  • See Catalan's constant.
    – projectilemotion
    Nov 13 at 14:23










  • Catalans constant. Thank you
    – Black Blast
    Nov 13 at 14:29


















  • How did you find this problem? What attempts have you made so far?
    – abiessu
    Nov 13 at 14:06








  • 1




    Do you know $$sum_{n=1}^inftyfrac1{n^2}=frac{pi^2}6;;?$$
    – DonAntonio
    Nov 13 at 14:07










  • Yes I do know the sum of squares and alternating squares reciprocals.
    – Black Blast
    Nov 13 at 14:16










  • See Catalan's constant.
    – projectilemotion
    Nov 13 at 14:23










  • Catalans constant. Thank you
    – Black Blast
    Nov 13 at 14:29
















How did you find this problem? What attempts have you made so far?
– abiessu
Nov 13 at 14:06






How did you find this problem? What attempts have you made so far?
– abiessu
Nov 13 at 14:06






1




1




Do you know $$sum_{n=1}^inftyfrac1{n^2}=frac{pi^2}6;;?$$
– DonAntonio
Nov 13 at 14:07




Do you know $$sum_{n=1}^inftyfrac1{n^2}=frac{pi^2}6;;?$$
– DonAntonio
Nov 13 at 14:07












Yes I do know the sum of squares and alternating squares reciprocals.
– Black Blast
Nov 13 at 14:16




Yes I do know the sum of squares and alternating squares reciprocals.
– Black Blast
Nov 13 at 14:16












See Catalan's constant.
– projectilemotion
Nov 13 at 14:23




See Catalan's constant.
– projectilemotion
Nov 13 at 14:23












Catalans constant. Thank you
– Black Blast
Nov 13 at 14:29




Catalans constant. Thank you
– Black Blast
Nov 13 at 14:29










1 Answer
1






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2
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Your original question was regarding the value of the following sum:
$$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$
The value of this sum is (by definition) given by Catalan's constant $Gapprox 0.915965594$. As of today, it is not known whether $G$ is irrational, nor transcendental.





However, I see that you have updated your question regarding where this sum came from, and it seems like you have not obtained the correct sum corresponding to the value of the integral. You should have:
$$begin{align}I=int_0^{infty} frac{ln^2(x)}{1+x^2}~dx&=2int_0^{1} frac{ln^2(x)}{1+x^2}~dx\&=2sum_{n=0}^{infty}(-1)^nint_0^1 ln^2(x)x^{2n}~dx end{align}$$
The change in order of summation and integration can be justified by Fubini's theorem. Using integration by parts twice, we have that:
$$int_0^1 ln^2(x)x^{2n}~dx=-int_0^1 frac{x^{2n+1}}{2n+1}cdot frac{2log(x)}{x}~dx=int_0^1 frac{x^{2n+1}}{(2n+1)^2}cdot frac{2}{x}~dx=frac{2}{(2n+1)^3}$$
Thus, we obtain:
$$I=4cdot sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^color{red}{3}}=frac{pi^3}{8}$$
This sum can be evaluated using multiple methods, see here.






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    up vote
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    down vote













    Your original question was regarding the value of the following sum:
    $$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$
    The value of this sum is (by definition) given by Catalan's constant $Gapprox 0.915965594$. As of today, it is not known whether $G$ is irrational, nor transcendental.





    However, I see that you have updated your question regarding where this sum came from, and it seems like you have not obtained the correct sum corresponding to the value of the integral. You should have:
    $$begin{align}I=int_0^{infty} frac{ln^2(x)}{1+x^2}~dx&=2int_0^{1} frac{ln^2(x)}{1+x^2}~dx\&=2sum_{n=0}^{infty}(-1)^nint_0^1 ln^2(x)x^{2n}~dx end{align}$$
    The change in order of summation and integration can be justified by Fubini's theorem. Using integration by parts twice, we have that:
    $$int_0^1 ln^2(x)x^{2n}~dx=-int_0^1 frac{x^{2n+1}}{2n+1}cdot frac{2log(x)}{x}~dx=int_0^1 frac{x^{2n+1}}{(2n+1)^2}cdot frac{2}{x}~dx=frac{2}{(2n+1)^3}$$
    Thus, we obtain:
    $$I=4cdot sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^color{red}{3}}=frac{pi^3}{8}$$
    This sum can be evaluated using multiple methods, see here.






    share|cite|improve this answer



























      up vote
      2
      down vote













      Your original question was regarding the value of the following sum:
      $$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$
      The value of this sum is (by definition) given by Catalan's constant $Gapprox 0.915965594$. As of today, it is not known whether $G$ is irrational, nor transcendental.





      However, I see that you have updated your question regarding where this sum came from, and it seems like you have not obtained the correct sum corresponding to the value of the integral. You should have:
      $$begin{align}I=int_0^{infty} frac{ln^2(x)}{1+x^2}~dx&=2int_0^{1} frac{ln^2(x)}{1+x^2}~dx\&=2sum_{n=0}^{infty}(-1)^nint_0^1 ln^2(x)x^{2n}~dx end{align}$$
      The change in order of summation and integration can be justified by Fubini's theorem. Using integration by parts twice, we have that:
      $$int_0^1 ln^2(x)x^{2n}~dx=-int_0^1 frac{x^{2n+1}}{2n+1}cdot frac{2log(x)}{x}~dx=int_0^1 frac{x^{2n+1}}{(2n+1)^2}cdot frac{2}{x}~dx=frac{2}{(2n+1)^3}$$
      Thus, we obtain:
      $$I=4cdot sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^color{red}{3}}=frac{pi^3}{8}$$
      This sum can be evaluated using multiple methods, see here.






      share|cite|improve this answer

























        up vote
        2
        down vote










        up vote
        2
        down vote









        Your original question was regarding the value of the following sum:
        $$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$
        The value of this sum is (by definition) given by Catalan's constant $Gapprox 0.915965594$. As of today, it is not known whether $G$ is irrational, nor transcendental.





        However, I see that you have updated your question regarding where this sum came from, and it seems like you have not obtained the correct sum corresponding to the value of the integral. You should have:
        $$begin{align}I=int_0^{infty} frac{ln^2(x)}{1+x^2}~dx&=2int_0^{1} frac{ln^2(x)}{1+x^2}~dx\&=2sum_{n=0}^{infty}(-1)^nint_0^1 ln^2(x)x^{2n}~dx end{align}$$
        The change in order of summation and integration can be justified by Fubini's theorem. Using integration by parts twice, we have that:
        $$int_0^1 ln^2(x)x^{2n}~dx=-int_0^1 frac{x^{2n+1}}{2n+1}cdot frac{2log(x)}{x}~dx=int_0^1 frac{x^{2n+1}}{(2n+1)^2}cdot frac{2}{x}~dx=frac{2}{(2n+1)^3}$$
        Thus, we obtain:
        $$I=4cdot sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^color{red}{3}}=frac{pi^3}{8}$$
        This sum can be evaluated using multiple methods, see here.






        share|cite|improve this answer














        Your original question was regarding the value of the following sum:
        $$sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^2}$$
        The value of this sum is (by definition) given by Catalan's constant $Gapprox 0.915965594$. As of today, it is not known whether $G$ is irrational, nor transcendental.





        However, I see that you have updated your question regarding where this sum came from, and it seems like you have not obtained the correct sum corresponding to the value of the integral. You should have:
        $$begin{align}I=int_0^{infty} frac{ln^2(x)}{1+x^2}~dx&=2int_0^{1} frac{ln^2(x)}{1+x^2}~dx\&=2sum_{n=0}^{infty}(-1)^nint_0^1 ln^2(x)x^{2n}~dx end{align}$$
        The change in order of summation and integration can be justified by Fubini's theorem. Using integration by parts twice, we have that:
        $$int_0^1 ln^2(x)x^{2n}~dx=-int_0^1 frac{x^{2n+1}}{2n+1}cdot frac{2log(x)}{x}~dx=int_0^1 frac{x^{2n+1}}{(2n+1)^2}cdot frac{2}{x}~dx=frac{2}{(2n+1)^3}$$
        Thus, we obtain:
        $$I=4cdot sum_{n=0}^{infty} frac{(-1)^n}{(2n+1)^color{red}{3}}=frac{pi^3}{8}$$
        This sum can be evaluated using multiple methods, see here.







        share|cite|improve this answer














        share|cite|improve this answer



        share|cite|improve this answer








        edited Nov 13 at 15:45

























        answered Nov 13 at 14:59









        projectilemotion

        11.2k61941




        11.2k61941






























             

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