An Euler type sum: $sum_n=1^inftyfracH_n^(2)ncdot 4^n2n choose n$, where $H_n^(2)=sumlimits_k=1^nfrac1k^2$
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I've been trying to compute the following series for quite a while :
$$sum_n=1^inftyfracH_n^(2)ncdot 4^n2n choose n$$
where $H_n^(2)=sumlimits_k=1^nfrac1k^2$ are the generalized harmonic numbers of order 2.
I've already successfully computed the value of a lot of similar-looking series involving harmonic numbers and central binomial coefficients (by using Abel's transformation, finding the generating function...), and they all had closed forms in terms of the Riemann Zeta function, so I'm confident this one too has a nice closed form ; but it's a tough guy that resists my previous methods.
By numerical test, I suspect that the value is $frac32zeta(3)$.
Any idea for derivation ?
calculus real-analysis sequences-and-series summation
edited Sep 7 at 0:51
Blue
44.4k868142
asked Aug 26 at 23:01
Harmonic Sun
2967
add a comment |Â
up vote
8
down vote
favorite
I've been trying to compute the following series for quite a while :
$$sum_n=1^inftyfracH_n^(2)ncdot 4^n2n choose n$$
where $H_n^(2)=sumlimits_k=1^nfrac1k^2$ are the generalized harmonic numbers of order 2.
I've already successfully computed the value of a lot of similar-looking series involving harmonic numbers and central binomial coefficients (by using Abel's transformation, finding the generating function...), and they all had closed forms in terms of the Riemann Zeta function, so I'm confident this one too has a nice closed form ; but it's a tough guy that resists my previous methods.
By numerical test, I suspect that the value is $frac32zeta(3)$.
Any idea for derivation ?
calculus real-analysis sequences-and-series summation
edited Sep 7 at 0:51
Blue
44.4k868142
asked Aug 26 at 23:01
Harmonic Sun
2967
2
What a fitting name!
– Frank W.
Aug 26 at 23:10
add a comment |Â
up vote
8
down vote
favorite
up vote
8
down vote
favorite
I've been trying to compute the following series for quite a while :
$$sum_n=1^inftyfracH_n^(2)ncdot 4^n2n choose n$$
where $H_n^(2)=sumlimits_k=1^nfrac1k^2$ are the generalized harmonic numbers of order 2.
I've already successfully computed the value of a lot of similar-looking series involving harmonic numbers and central binomial coefficients (by using Abel's transformation, finding the generating function...), and they all had closed forms in terms of the Riemann Zeta function, so I'm confident this one too has a nice closed form ; but it's a tough guy that resists my previous methods.
By numerical test, I suspect that the value is $frac32zeta(3)$.
Any idea for derivation ?
calculus real-analysis sequences-and-series summation
edited Sep 7 at 0:51
Blue
44.4k868142
asked Aug 26 at 23:01
Harmonic Sun
2967
I've been trying to compute the following series for quite a while :
$$sum_n=1^inftyfracH_n^(2)ncdot 4^n2n choose n$$
where $H_n^(2)=sumlimits_k=1^nfrac1k^2$ are the generalized harmonic numbers of order 2.
I've already successfully computed the value of a lot of similar-looking series involving harmonic numbers and central binomial coefficients (by using Abel's transformation, finding the generating function...), and they all had closed forms in terms of the Riemann Zeta function, so I'm confident this one too has a nice closed form ; but it's a tough guy that resists my previous methods.
By numerical test, I suspect that the value is $frac32zeta(3)$.
Any idea for derivation ?
calculus real-analysis sequences-and-series summation
calculus real-analysis sequences-and-series summation
edited Sep 7 at 0:51
Blue
44.4k868142
asked Aug 26 at 23:01
Harmonic Sun
2967
edited Sep 7 at 0:51
Blue
44.4k868142
asked Aug 26 at 23:01
Harmonic Sun
2967
edited Sep 7 at 0:51
Blue
44.4k868142
edited Sep 7 at 0:51
Blue
44.4k868142
edited Sep 7 at 0:51
Blue
44.4k868142
44.4k868142
asked Aug 26 at 23:01
Harmonic Sun
2967
asked Aug 26 at 23:01
Harmonic Sun
2967
asked Aug 26 at 23:01
Harmonic Sun
2967
2967
2
What a fitting name!
– Frank W.
Aug 26 at 23:10
add a comment |Â
2
What a fitting name!
– Frank W.
Aug 26 at 23:10
2
2
What a fitting name!
– Frank W.
Aug 26 at 23:10
What a fitting name!
– Frank W.
Aug 26 at 23:10
add a comment |Â
1 Answer
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Since
$$ zeta(2)-H_n^(2) = int_0^1 x^n frac-log x1-x,dx $$
$$ sum_ngeq 1fracx^nn4^nbinom2nn = 2log(2)-2log(1+sqrt1-x) $$
the computation of your series boils down to the computation of the integral
$$ int_0^1fraclog(x)log(1+sqrt1-x)1-x,dx=int_0^1fraclog(1-x)log(1+sqrtx)x,dx $$
or the computation of the integral
$$ int_0^1fracleft[log(1-x)+log(1+x)right]log(1+x)x,dx $$
where
$$ int_0^1fraclog^2(1+x)x=fraczeta(3)4,qquad int_0^1fraclog(1-x)log(1+x)x,dx =-frac5,zeta(3)8$$
are simple to prove by Maclaurin series and Euler sums. Your conjecture is correct.
answered Aug 27 at 15:12
Jack D'Aurizio♦
275k32268640
Thank you very much !
– Harmonic Sun
Aug 27 at 17:53
add a comment |Â
1 Answer
1
active
oldest
votes
1 Answer
1
active
oldest
votes
active
oldest
votes
active
oldest
votes
up vote
5
down vote
Since
$$ zeta(2)-H_n^(2) = int_0^1 x^n frac-log x1-x,dx $$
$$ sum_ngeq 1fracx^nn4^nbinom2nn = 2log(2)-2log(1+sqrt1-x) $$
the computation of your series boils down to the computation of the integral
$$ int_0^1fraclog(x)log(1+sqrt1-x)1-x,dx=int_0^1fraclog(1-x)log(1+sqrtx)x,dx $$
or the computation of the integral
$$ int_0^1fracleft[log(1-x)+log(1+x)right]log(1+x)x,dx $$
where
$$ int_0^1fraclog^2(1+x)x=fraczeta(3)4,qquad int_0^1fraclog(1-x)log(1+x)x,dx =-frac5,zeta(3)8$$
are simple to prove by Maclaurin series and Euler sums. Your conjecture is correct.
answered Aug 27 at 15:12
Jack D'Aurizio♦
275k32268640
Thank you very much !
– Harmonic Sun
Aug 27 at 17:53
add a comment |Â
up vote
5
down vote
Since
$$ zeta(2)-H_n^(2) = int_0^1 x^n frac-log x1-x,dx $$
$$ sum_ngeq 1fracx^nn4^nbinom2nn = 2log(2)-2log(1+sqrt1-x) $$
the computation of your series boils down to the computation of the integral
$$ int_0^1fraclog(x)log(1+sqrt1-x)1-x,dx=int_0^1fraclog(1-x)log(1+sqrtx)x,dx $$
or the computation of the integral
$$ int_0^1fracleft[log(1-x)+log(1+x)right]log(1+x)x,dx $$
where
$$ int_0^1fraclog^2(1+x)x=fraczeta(3)4,qquad int_0^1fraclog(1-x)log(1+x)x,dx =-frac5,zeta(3)8$$
are simple to prove by Maclaurin series and Euler sums. Your conjecture is correct.
answered Aug 27 at 15:12
Jack D'Aurizio♦
275k32268640
Thank you very much !
– Harmonic Sun
Aug 27 at 17:53
add a comment |Â
up vote
5
down vote
up vote
5
down vote
Since
$$ zeta(2)-H_n^(2) = int_0^1 x^n frac-log x1-x,dx $$
$$ sum_ngeq 1fracx^nn4^nbinom2nn = 2log(2)-2log(1+sqrt1-x) $$
the computation of your series boils down to the computation of the integral
$$ int_0^1fraclog(x)log(1+sqrt1-x)1-x,dx=int_0^1fraclog(1-x)log(1+sqrtx)x,dx $$
or the computation of the integral
$$ int_0^1fracleft[log(1-x)+log(1+x)right]log(1+x)x,dx $$
where
$$ int_0^1fraclog^2(1+x)x=fraczeta(3)4,qquad int_0^1fraclog(1-x)log(1+x)x,dx =-frac5,zeta(3)8$$
are simple to prove by Maclaurin series and Euler sums. Your conjecture is correct.
answered Aug 27 at 15:12
Jack D'Aurizio♦
275k32268640
Since
$$ zeta(2)-H_n^(2) = int_0^1 x^n frac-log x1-x,dx $$
$$ sum_ngeq 1fracx^nn4^nbinom2nn = 2log(2)-2log(1+sqrt1-x) $$
the computation of your series boils down to the computation of the integral
$$ int_0^1fraclog(x)log(1+sqrt1-x)1-x,dx=int_0^1fraclog(1-x)log(1+sqrtx)x,dx $$
or the computation of the integral
$$ int_0^1fracleft[log(1-x)+log(1+x)right]log(1+x)x,dx $$
where
$$ int_0^1fraclog^2(1+x)x=fraczeta(3)4,qquad int_0^1fraclog(1-x)log(1+x)x,dx =-frac5,zeta(3)8$$
are simple to prove by Maclaurin series and Euler sums. Your conjecture is correct.
answered Aug 27 at 15:12
Jack D'Aurizio♦
275k32268640
edited Aug 27 at 15:21
answered Aug 27 at 15:12
Jack D'Aurizio♦
275k32268640
answered Aug 27 at 15:12
Jack D'Aurizio♦
275k32268640
answered Aug 27 at 15:12
Jack D'Aurizio♦
275k32268640
275k32268640
Thank you very much !
– Harmonic Sun
Aug 27 at 17:53
add a comment |Â
Thank you very much !
– Harmonic Sun
Aug 27 at 17:53
Thank you very much !
– Harmonic Sun
Aug 27 at 17:53
Thank you very much !
– Harmonic Sun
Aug 27 at 17:53
add a comment |Â
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2
What a fitting name!
– Frank W.
Aug 26 at 23:10