“Gilbreath's conjecture”的意思、由来-开放百科全书

Gilbreath observed a pattern while playing with the ordered sequence of prime numbers

Computing the absolute value of the difference between term n+1 and term n in this sequence yields the sequence

If the same calculation is done for the terms in this new sequence, and the sequence that is the outcome of this process, and again ad infinitum for each sequence that is the output of such a calculation, the following five sequences in this list are

What Gilbreath—and François Proth before him—noticed is that the first term in each series of differences appears to be 1.

The conjecture

Stating Gilbreath's observation formally is significantly easier to do after devising a notation for the sequences in the previous section. Toward this end, let

denote the ordered sequence of prime numbers

, and define each term in the sequence

where

is positive. Also, for each integer

greater than 1, let the terms in

be given by

Gilbreath's conjecture states that every term in the sequence

for positive

is 1.

Verification and attempted proofs

Generalizations

In 1980, Martin Gardner published a conjecture by Hallard Croft that stated that the property of Gilbreath's conjecture (having a 1 in the first term of each difference sequence) should hold more generally for every sequence that begins with 2, subsequently contains only odd numbers, and has a sufficiently low bound on the gaps between consecutive elements in the sequence.^[3] This conjecture has also been repeated by later authors.^[4]^[5] However, it is false: for every initial subsequence of 2 and odd numbers, and every non-constant growth rate, there is a continuation of the subsequence by odd numbers whose gaps obey the growth rate but whose difference sequences fail to begin with 1 infinitely often.^[6] {{harvtxt|Odlyzko|1993}} is more careful, writing of certain heuristic reasons for believing Gilbreath's conjecture that "the arguments above apply to many other sequences in which the first element is a 1, the others even, and where the gaps between consecutive elements are not too large and are sufficiently random."^[2] However, he does not give a formal definition of what "sufficiently random" means.

See also

References

1. ^¹{{Citation |first=Chris |last=Caldwell |url=http://primes.utm.edu/glossary/page.php?sort=GilbreathsConjecture |title=The Prime Glossary: Gilbreath's conjecture |work=The Prime Pages |accessdate= }}.
2. ^¹{{Citation |first=A. M. |last=Odlyzko | authorlink=Andrew Odlyzko |url=http://www.dtc.umn.edu/~odlyzko/doc/arch/gilbreath.conj.ps |title=Iterated absolute values of differences of consecutive primes |journal=Mathematics of Computation |volume=61 |year=1993 |pages=373–380 |doi= 10.2307/2152962 | zbl=0781.11037 |ref=harv}}.
3. ^{{cite journal|department=Mathematical Games|first=Martin|last=Gardner|authorlink=Martin Gardner|date=December 1980|url=http://www.softouch.on.ca/kb/data/Scan-121213-0011.pdf|title=Patterns in primes are a clue to the strong law of small numbers|volume=243|issue=6|pages=18–28}}
4. ^{{cite book|last=Guy|first=Richard K. | authorlink=Richard K. Guy| title=Unsolved Problems in Number Theory | edition=3rd | publisher=Springer-Verlag | year=2004 | isbn=0-387-20860-7 | zbl=1058.11001 | series=Problem Books in Mathematics | page=42 }}
5. ^{{cite book|title=The Universal Book of Mathematics: From Abracadabra to Zeno's Paradoxes|first=David|last=Darling|authorlink=David J. Darling|publisher=John Wiley & Sons|year=2004|isbn=9780471667001|pages=133–134|url=https://books.google.com/books?id=HrOxRdtYYaMC&pg=PA133|contribution=Gilbreath's conjecture}}
6. ^{{cite web|first=David |last=Eppstein |authorlink=David Eppstein |url=https://11011110.github.io/blog/2011/02/20/anti-gilbreath-sequences.html |work=11011110 |title=Anti-Gilbreath sequences |date=February 20, 2011 }}

Motivating arithmetic

The conjecture

Verification and attempted proofs

Generalizations

See also

References