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Difference between revisions of "Double Mersenne number"
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This holds true for the first 4 terms: | This holds true for the first 4 terms: | ||
− | *MM(2) = <math>2^3-1</math> = 7, known | + | *MM(2) = <math>2^3-1</math> = 7, known prime since antiquity |
− | *MM(3) = <math>2^7-1</math> = 127, known | + | *MM(3) = <math>2^7-1</math> = 127, known prime since antiquity |
*MM(5) = <math>2^{31}-1</math> = 2147483647, proven prime by [[Leonhard Euler]] in 1772 | *MM(5) = <math>2^{31}-1</math> = 2147483647, proven prime by [[Leonhard Euler]] in 1772 | ||
*[[M12|MM(7)]] = <math>2^{127}-1</math> = 170141183460469231731687303715884105727, proven prime by [[Édouard Lucas]] in 1876 | *[[M12|MM(7)]] = <math>2^{127}-1</math> = 170141183460469231731687303715884105727, proven prime by [[Édouard Lucas]] in 1876 | ||
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*MM(19) has a factor, 62914441, found in 1957 | *MM(19) has a factor, 62914441, found in 1957 | ||
*MM(31) has a factor, 295257526626031, found in 1983 | *MM(31) has a factor, 295257526626031, found in 1983 | ||
− | All further numbers are [[MM61|MM(61)]], MM(89), MM(107), MM(127), etc. are unknown. (It is worth noting that, there was a gap of over 80 years between the proving of MM(7) and the finding of factors for MM(17) & MM(19). The factors were found by [[Raphael Robinson]] with a computer.) These all are so very large that there is no hope of running a [[Lucas-Lehmer test]] on them any time in the forseeable future. Efforts are under way attempting to find factors for these numbers. Currently MM(61) and MM(127) are getting the most attention. | + | All further numbers are [[MM61|MM(61)]], MM(89), MM(107), MM(127), etc. are unknown. (It is worth noting that, there was a gap of over 80 years between the proving of MM(7) and the finding of factors for MM(17) & MM(19). The factors were found by [[Raphael M. Robinson]] with a computer.) These all are so very large that there is no hope of running a [[Lucas-Lehmer test]] on them any time in the forseeable future. Efforts are under way attempting to find factors for these numbers. Currently MM(61) and MM(127) are getting the most attention. |
MM(61) or <math>2^{2305843009213693951}-1</math> is 694 127 911 065 419 642 [[digit]]s long. [[Tony Forbes]] lead an effort to find a [[factor]] for this number. The search has included all '''''[[Value k|k]]''''' values up to {{Num|1167025860000000}}, with many beyond that as well (as of Feb 2011). | MM(61) or <math>2^{2305843009213693951}-1</math> is 694 127 911 065 419 642 [[digit]]s long. [[Tony Forbes]] lead an effort to find a [[factor]] for this number. The search has included all '''''[[Value k|k]]''''' values up to {{Num|1167025860000000}}, with many beyond that as well (as of Feb 2011). | ||
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==External links== | ==External links== | ||
*[http://www.doublemersennes.org/history.php Double Mersennes Prime Search] by [[Luigi Morelli]] | *[http://www.doublemersennes.org/history.php Double Mersennes Prime Search] by [[Luigi Morelli]] | ||
− | *Will Edgington's <nowiki>http://www.garlic.com/~wedgingt/MMPstats.txt</nowiki> on Double Mersennes (known factors, factoring effort, and more.) | + | *[https://web.archive.org/web/20141015012140/http://www.garlic.com/~wedgingt/MMPstats.txt Archive of Will Edgington's <nowiki>http://www.garlic.com/~wedgingt/MMPstats.txt</nowiki> on Double Mersennes (known factors, factoring effort, and more.)] |
*Tony Forbes' project <nowiki>http://sites.google.com/site/anthonydforbes/mm61.htm</nowiki> -> unreachable | *Tony Forbes' project <nowiki>http://sites.google.com/site/anthonydforbes/mm61.htm</nowiki> -> unreachable | ||
*[http://mersenneforum.org/forumdisplay.php?f=99 MersenneForum subforum] for Double Mersennes | *[http://mersenneforum.org/forumdisplay.php?f=99 MersenneForum subforum] for Double Mersennes | ||
+ | {{Navbox NumberClasses}} | ||
[[Category:Number]] | [[Category:Number]] |
Latest revision as of 14:50, 19 September 2021
A double Mersenne number is a number where the exponent is also a Mersenne number and usually a Mersenne prime. These are generally denoted as MMp, MMp, or MM(p) and refer to [math]\displaystyle{ 2^{2^p-1}-1 }[/math]. Early on it was thought that if M(p) was prime so too was MM(p).
This holds true for the first 4 terms:
- MM(2) = [math]\displaystyle{ 2^3-1 }[/math] = 7, known prime since antiquity
- MM(3) = [math]\displaystyle{ 2^7-1 }[/math] = 127, known prime since antiquity
- MM(5) = [math]\displaystyle{ 2^{31}-1 }[/math] = 2147483647, proven prime by Leonhard Euler in 1772
- MM(7) = [math]\displaystyle{ 2^{127}-1 }[/math] = 170141183460469231731687303715884105727, proven prime by Édouard Lucas in 1876
However this does not hold true for next 4 terms:
- MM(13) has a factor, 338193759479, found in 1976
- MM(17) has a factor, 231733529, found in 1957
- MM(19) has a factor, 62914441, found in 1957
- MM(31) has a factor, 295257526626031, found in 1983
All further numbers are MM(61), MM(89), MM(107), MM(127), etc. are unknown. (It is worth noting that, there was a gap of over 80 years between the proving of MM(7) and the finding of factors for MM(17) & MM(19). The factors were found by Raphael M. Robinson with a computer.) These all are so very large that there is no hope of running a Lucas-Lehmer test on them any time in the forseeable future. Efforts are under way attempting to find factors for these numbers. Currently MM(61) and MM(127) are getting the most attention.
MM(61) or [math]\displaystyle{ 2^{2305843009213693951}-1 }[/math] is 694 127 911 065 419 642 digits long. Tony Forbes lead an effort to find a factor for this number. The search has included all k values up to 1,167,025,860,000,000, with many beyond that as well (as of Feb 2011).
George Woltman wrote a GPU program mmff that can factor double Mersennes. Luigi Morelli is co-ordinating the effort to factor these numbers.
More about MM(127) below.
Catalan Sequence
A subset of double Mersennes is the Catalan-Mersenne sequence (sometimes called simply the Catalan sequence). The sequence was first noted by Eugéne Catalan in 1876 after Lucas' finding M(127) to be prime.
The sequence can be written several ways, as noted in the table below:
Catalan element # |
Catalan formula |
Mersenne function | Mersenne element # | value |
---|---|---|---|---|
C0 | 2 | 2 | ||
C1 | [math]\displaystyle{ 2^{C_0}{-}1 }[/math] | M(2) | M1 | 3 |
C2 | [math]\displaystyle{ 2^{C_1}{-}1 }[/math] | M(3) or M(M(2)) |
M2 | 7 |
C3 | [math]\displaystyle{ 2^{C_2}{-}1 }[/math] | M(7) or M(M(M(2))) |
M4 | 127 |
C4 | [math]\displaystyle{ 2^{C_3}{-}1 }[/math] | M(127) or M(M(M(M(2)))) |
M12 | 170141183460469231731687303715884105727 |
C5 | [math]\displaystyle{ 2^{C_4}{-}1 }[/math] | M(170141183460469231731687303715884105727) or M(M(M(M(M(2))))) |
M??, status unknown | [math]\displaystyle{ \approx1*10^{(5.12*10^{30})} }[/math] |
This was the sequence that Lucas was testing when he proved M(127) to be prime. While the sequence does hold true for the first few elements, this likely to be a case of the "Strong law of small numbers". There have been efforts to again test this trend, by finding a factor for C5. If a factor is found M(M(127)), then M(M(M(127)) etc. must be composite. Landon Curt Noll has trial factored this number up to a k value of at least 3,000,000,000,000 (i.e. there is no factor smaller than [math]\displaystyle{ 5*10^{51} }[/math]), a bit level over 169.4. The current version of Prime95 cannot handle numbers this large, nor can mfaktc.
External links
- Double Mersennes Prime Search by Luigi Morelli
- Archive of Will Edgington's http://www.garlic.com/~wedgingt/MMPstats.txt on Double Mersennes (known factors, factoring effort, and more.)
- Tony Forbes' project http://sites.google.com/site/anthonydforbes/mm61.htm -> unreachable
- MersenneForum subforum for Double Mersennes
General numbers |
Special numbers |
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Prime numbers |
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