How to find first 32 digits of $displaystyle prod_{n=1}^{infty} (1-gamma^n)$?
$begingroup$
I need to find first 32 digits of $displaystyle prod_{n=1}^{infty} (1-gamma^n)$ but wolframalpha's brain is too narrow to contain the result, and I don't know any software and programming to find the result. $gamma$ is the Euler's constant. Or does it converge to a known number? Please help! Thanks
Added for Bounty. Does the mentioned infinite product have any closed form in terms of known mathematical constants?
infinite-product q-series
$endgroup$
add a comment |
$begingroup$
I need to find first 32 digits of $displaystyle prod_{n=1}^{infty} (1-gamma^n)$ but wolframalpha's brain is too narrow to contain the result, and I don't know any software and programming to find the result. $gamma$ is the Euler's constant. Or does it converge to a known number? Please help! Thanks
Added for Bounty. Does the mentioned infinite product have any closed form in terms of known mathematical constants?
infinite-product q-series
$endgroup$
$begingroup$
Using Euler's pentagonal number formula gives a very rapidly convergent series. Of course, you need the value of $gamma$ quite accurately.
$endgroup$
– Lord Shark the Unknown
Jan 11 at 5:23
$begingroup$
Pentagonal number theorem.
$endgroup$
– Alex Ravsky
Jan 15 at 6:40
add a comment |
$begingroup$
I need to find first 32 digits of $displaystyle prod_{n=1}^{infty} (1-gamma^n)$ but wolframalpha's brain is too narrow to contain the result, and I don't know any software and programming to find the result. $gamma$ is the Euler's constant. Or does it converge to a known number? Please help! Thanks
Added for Bounty. Does the mentioned infinite product have any closed form in terms of known mathematical constants?
infinite-product q-series
$endgroup$
I need to find first 32 digits of $displaystyle prod_{n=1}^{infty} (1-gamma^n)$ but wolframalpha's brain is too narrow to contain the result, and I don't know any software and programming to find the result. $gamma$ is the Euler's constant. Or does it converge to a known number? Please help! Thanks
Added for Bounty. Does the mentioned infinite product have any closed form in terms of known mathematical constants?
infinite-product q-series
infinite-product q-series
edited Jan 13 at 9:39
72D
asked Jan 11 at 5:07
72D72D
512116
512116
$begingroup$
Using Euler's pentagonal number formula gives a very rapidly convergent series. Of course, you need the value of $gamma$ quite accurately.
$endgroup$
– Lord Shark the Unknown
Jan 11 at 5:23
$begingroup$
Pentagonal number theorem.
$endgroup$
– Alex Ravsky
Jan 15 at 6:40
add a comment |
$begingroup$
Using Euler's pentagonal number formula gives a very rapidly convergent series. Of course, you need the value of $gamma$ quite accurately.
$endgroup$
– Lord Shark the Unknown
Jan 11 at 5:23
$begingroup$
Pentagonal number theorem.
$endgroup$
– Alex Ravsky
Jan 15 at 6:40
$begingroup$
Using Euler's pentagonal number formula gives a very rapidly convergent series. Of course, you need the value of $gamma$ quite accurately.
$endgroup$
– Lord Shark the Unknown
Jan 11 at 5:23
$begingroup$
Using Euler's pentagonal number formula gives a very rapidly convergent series. Of course, you need the value of $gamma$ quite accurately.
$endgroup$
– Lord Shark the Unknown
Jan 11 at 5:23
$begingroup$
Pentagonal number theorem.
$endgroup$
– Alex Ravsky
Jan 15 at 6:40
$begingroup$
Pentagonal number theorem.
$endgroup$
– Alex Ravsky
Jan 15 at 6:40
add a comment |
2 Answers
2
active
oldest
votes
$begingroup$
Using Pochhammer symbols $$displaystyle prod_{n=1}^{infty} (1-gamma^n)=(gamma ;gamma )_{infty }$$ A very fast way to compute it (have a look here) is
$$(gamma ;gamma )_{infty }=sum_{k=-infty}^infty (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$
Consider partial sums
$$S_p=sum_{k=-p}^p (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$ and compute for $50$ decimal places
$$left(
begin{array}{cc}
5 & 0.17340542156115797462125386932229340638693672477775 \
6 & 0.17340542156185623295922558757637084613978106011987 \
7 & 0.17340542156185621287562583984349502239524993758969 \
8 & 0.17340542156185621287573763551045706783782602427578 \
9 & 0.17340542156185621287573763539033111094663184209447 \
10 & 0.17340542156185621287573763539033113582404282775260 \
11 & 0.17340542156185621287573763539033113582404183569900 \
12 & 0.17340542156185621287573763539033113582404183569901 \
13 & 0.17340542156185621287573763539033113582404183569901 \
14 & 0.17340542156185621287573763539033113582404183569900 \
15 & 0.17340542156185621287573763539033113582404183569900
end{array}
right)$$ For $32$ decimal places $S_9$ would be fine.
$endgroup$
add a comment |
$begingroup$
I asked Alpha and got
$0.1734054215618562128757376353903311358240418\
356990083565526180089819971434621977210396477\
9552159698610211689009709...$
with one click on More Digits. I have found that sometimes when a calculation fails, close the tab, open a new one, and try again sometimes works.
$endgroup$
$begingroup$
So I wasn't asking it probably! Would you let me know if there is a 'closed form' for it, I mean the product as a function of other known numbers?
$endgroup$
– 72D
Jan 11 at 5:19
$begingroup$
I would guess not, but don't really know.
$endgroup$
– Ross Millikan
Jan 11 at 5:19
add a comment |
Your Answer
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2 Answers
2
active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
Using Pochhammer symbols $$displaystyle prod_{n=1}^{infty} (1-gamma^n)=(gamma ;gamma )_{infty }$$ A very fast way to compute it (have a look here) is
$$(gamma ;gamma )_{infty }=sum_{k=-infty}^infty (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$
Consider partial sums
$$S_p=sum_{k=-p}^p (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$ and compute for $50$ decimal places
$$left(
begin{array}{cc}
5 & 0.17340542156115797462125386932229340638693672477775 \
6 & 0.17340542156185623295922558757637084613978106011987 \
7 & 0.17340542156185621287562583984349502239524993758969 \
8 & 0.17340542156185621287573763551045706783782602427578 \
9 & 0.17340542156185621287573763539033111094663184209447 \
10 & 0.17340542156185621287573763539033113582404282775260 \
11 & 0.17340542156185621287573763539033113582404183569900 \
12 & 0.17340542156185621287573763539033113582404183569901 \
13 & 0.17340542156185621287573763539033113582404183569901 \
14 & 0.17340542156185621287573763539033113582404183569900 \
15 & 0.17340542156185621287573763539033113582404183569900
end{array}
right)$$ For $32$ decimal places $S_9$ would be fine.
$endgroup$
add a comment |
$begingroup$
Using Pochhammer symbols $$displaystyle prod_{n=1}^{infty} (1-gamma^n)=(gamma ;gamma )_{infty }$$ A very fast way to compute it (have a look here) is
$$(gamma ;gamma )_{infty }=sum_{k=-infty}^infty (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$
Consider partial sums
$$S_p=sum_{k=-p}^p (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$ and compute for $50$ decimal places
$$left(
begin{array}{cc}
5 & 0.17340542156115797462125386932229340638693672477775 \
6 & 0.17340542156185623295922558757637084613978106011987 \
7 & 0.17340542156185621287562583984349502239524993758969 \
8 & 0.17340542156185621287573763551045706783782602427578 \
9 & 0.17340542156185621287573763539033111094663184209447 \
10 & 0.17340542156185621287573763539033113582404282775260 \
11 & 0.17340542156185621287573763539033113582404183569900 \
12 & 0.17340542156185621287573763539033113582404183569901 \
13 & 0.17340542156185621287573763539033113582404183569901 \
14 & 0.17340542156185621287573763539033113582404183569900 \
15 & 0.17340542156185621287573763539033113582404183569900
end{array}
right)$$ For $32$ decimal places $S_9$ would be fine.
$endgroup$
add a comment |
$begingroup$
Using Pochhammer symbols $$displaystyle prod_{n=1}^{infty} (1-gamma^n)=(gamma ;gamma )_{infty }$$ A very fast way to compute it (have a look here) is
$$(gamma ;gamma )_{infty }=sum_{k=-infty}^infty (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$
Consider partial sums
$$S_p=sum_{k=-p}^p (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$ and compute for $50$ decimal places
$$left(
begin{array}{cc}
5 & 0.17340542156115797462125386932229340638693672477775 \
6 & 0.17340542156185623295922558757637084613978106011987 \
7 & 0.17340542156185621287562583984349502239524993758969 \
8 & 0.17340542156185621287573763551045706783782602427578 \
9 & 0.17340542156185621287573763539033111094663184209447 \
10 & 0.17340542156185621287573763539033113582404282775260 \
11 & 0.17340542156185621287573763539033113582404183569900 \
12 & 0.17340542156185621287573763539033113582404183569901 \
13 & 0.17340542156185621287573763539033113582404183569901 \
14 & 0.17340542156185621287573763539033113582404183569900 \
15 & 0.17340542156185621287573763539033113582404183569900
end{array}
right)$$ For $32$ decimal places $S_9$ would be fine.
$endgroup$
Using Pochhammer symbols $$displaystyle prod_{n=1}^{infty} (1-gamma^n)=(gamma ;gamma )_{infty }$$ A very fast way to compute it (have a look here) is
$$(gamma ;gamma )_{infty }=sum_{k=-infty}^infty (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$
Consider partial sums
$$S_p=sum_{k=-p}^p (-1)^k ,gamma ^{frac{3k^2-k}{2} }$$ and compute for $50$ decimal places
$$left(
begin{array}{cc}
5 & 0.17340542156115797462125386932229340638693672477775 \
6 & 0.17340542156185623295922558757637084613978106011987 \
7 & 0.17340542156185621287562583984349502239524993758969 \
8 & 0.17340542156185621287573763551045706783782602427578 \
9 & 0.17340542156185621287573763539033111094663184209447 \
10 & 0.17340542156185621287573763539033113582404282775260 \
11 & 0.17340542156185621287573763539033113582404183569900 \
12 & 0.17340542156185621287573763539033113582404183569901 \
13 & 0.17340542156185621287573763539033113582404183569901 \
14 & 0.17340542156185621287573763539033113582404183569900 \
15 & 0.17340542156185621287573763539033113582404183569900
end{array}
right)$$ For $32$ decimal places $S_9$ would be fine.
answered Jan 11 at 6:10
Claude LeiboviciClaude Leibovici
120k1157132
120k1157132
add a comment |
add a comment |
$begingroup$
I asked Alpha and got
$0.1734054215618562128757376353903311358240418\
356990083565526180089819971434621977210396477\
9552159698610211689009709...$
with one click on More Digits. I have found that sometimes when a calculation fails, close the tab, open a new one, and try again sometimes works.
$endgroup$
$begingroup$
So I wasn't asking it probably! Would you let me know if there is a 'closed form' for it, I mean the product as a function of other known numbers?
$endgroup$
– 72D
Jan 11 at 5:19
$begingroup$
I would guess not, but don't really know.
$endgroup$
– Ross Millikan
Jan 11 at 5:19
add a comment |
$begingroup$
I asked Alpha and got
$0.1734054215618562128757376353903311358240418\
356990083565526180089819971434621977210396477\
9552159698610211689009709...$
with one click on More Digits. I have found that sometimes when a calculation fails, close the tab, open a new one, and try again sometimes works.
$endgroup$
$begingroup$
So I wasn't asking it probably! Would you let me know if there is a 'closed form' for it, I mean the product as a function of other known numbers?
$endgroup$
– 72D
Jan 11 at 5:19
$begingroup$
I would guess not, but don't really know.
$endgroup$
– Ross Millikan
Jan 11 at 5:19
add a comment |
$begingroup$
I asked Alpha and got
$0.1734054215618562128757376353903311358240418\
356990083565526180089819971434621977210396477\
9552159698610211689009709...$
with one click on More Digits. I have found that sometimes when a calculation fails, close the tab, open a new one, and try again sometimes works.
$endgroup$
I asked Alpha and got
$0.1734054215618562128757376353903311358240418\
356990083565526180089819971434621977210396477\
9552159698610211689009709...$
with one click on More Digits. I have found that sometimes when a calculation fails, close the tab, open a new one, and try again sometimes works.
answered Jan 11 at 5:16
Ross MillikanRoss Millikan
294k23198371
294k23198371
$begingroup$
So I wasn't asking it probably! Would you let me know if there is a 'closed form' for it, I mean the product as a function of other known numbers?
$endgroup$
– 72D
Jan 11 at 5:19
$begingroup$
I would guess not, but don't really know.
$endgroup$
– Ross Millikan
Jan 11 at 5:19
add a comment |
$begingroup$
So I wasn't asking it probably! Would you let me know if there is a 'closed form' for it, I mean the product as a function of other known numbers?
$endgroup$
– 72D
Jan 11 at 5:19
$begingroup$
I would guess not, but don't really know.
$endgroup$
– Ross Millikan
Jan 11 at 5:19
$begingroup$
So I wasn't asking it probably! Would you let me know if there is a 'closed form' for it, I mean the product as a function of other known numbers?
$endgroup$
– 72D
Jan 11 at 5:19
$begingroup$
So I wasn't asking it probably! Would you let me know if there is a 'closed form' for it, I mean the product as a function of other known numbers?
$endgroup$
– 72D
Jan 11 at 5:19
$begingroup$
I would guess not, but don't really know.
$endgroup$
– Ross Millikan
Jan 11 at 5:19
$begingroup$
I would guess not, but don't really know.
$endgroup$
– Ross Millikan
Jan 11 at 5:19
add a comment |
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$begingroup$
Using Euler's pentagonal number formula gives a very rapidly convergent series. Of course, you need the value of $gamma$ quite accurately.
$endgroup$
– Lord Shark the Unknown
Jan 11 at 5:23
$begingroup$
Pentagonal number theorem.
$endgroup$
– Alex Ravsky
Jan 15 at 6:40