Formula for primes

In number theory, a formula for primes is a formula generating the prime numbers, exactly and without exception. No such formula which is efficiently computable is known. A number of constraints are known, showing what such a "formula" can and cannot be.

Prime formulas and polynomial functions

It is known that no non-constant polynomial function P(n) with integer coefficients exists that evaluates to a prime number for all integers n. The proof is as follows: Suppose such a polynomial existed. Then P(1) would evaluate to a prime p, so $P(1) \equiv 0 \pmod p$ . But for any k, $P(1+kp) \equiv 0 \pmod p$ also, so $P(1+kp)$ cannot also be prime (as it would be divisible by p) unless it were p itself, but the only way $P(1+kp) = P(1)$ for all k is if the polynomial function is constant.

The same reasoning shows an even stronger result: no non-constant polynomial function P(n) exists that evaluates to a prime number for almost all integers n.

Euler first noticed (in 1772) that the quadratic polynomial

P(n) = n² + n + 41

is prime for all natural numbers less than 40. The primes for n = 0, 1, 2, ... are 41, 43, 47, 53, 61, 71... The differences between the terms are 2, 4, 6, 8, 10... For n = 40, it produces a square number, 1681, which is equal to 41×41, the smallest composite number for this formula. If 41 divides n, it divides P(n) too. Furthermore, since P(n) can be written as n(n + 1) + 41, if 41 divides n + 1 instead, it also divides P(n). The phenomenon is related to the Ulam spiral, which is also implicitly quadratic, and the class number; this polynomial is related to the Heegner number $163=4\cdot 41-1$ , and there are analogous polynomials for $p=2, 3, 5, 11, \text{ and } 17$ (the lucky numbers of Euler), corresponding to other Heegner numbers.

Given a positive integer S, there may be infinitely many c such that the expression n² + n + c is always coprime to S. c may be negative, in which case there is a delay before primes are produced.

It is known, based on Dirichlet's theorem on arithmetic progressions, that linear polynomial functions $L(n) = an + b$ produce infinitely many primes as long as a and b are relatively prime (though no such function will assume prime values for all values of n). Moreover, the Green–Tao theorem says that for any k there exists a pair of a and b with the property that $L(n) = an+b$ is prime for any n from 0 to k − 1. However, the best known result of such type is for k = 26 (by Benoãt Perichon of France):

43142746595714191 + 5283234035979900n is prime for all n from 0 to 25 (Perichon 2010).

It is not even known whether there exists a univariate polynomial of degree at least 2 that assumes an infinite number of values that are prime; see Bunyakovsky conjecture.

Formula based on a system of Diophantine equations

Because the set of primes is a computably enumerable set, by Matiyasevich's theorem, it can be obtained from a system of Diophantine equations. Jones et al. (1976) found an explicit set of 14 Diophantine equations in 26 variables, such that a given number k + 2 is prime if and only if that system has a solution in natural numbers:

\alpha _{0}=wz+h+j-q=0

\alpha _{1}=(gk+2g+k+1)(h+j)+h-z=0

\alpha _{2}=16(k+1)^{3}(k+2)(n+1)^{2}+1-f^{2}=0

\alpha _{3}=2n+p+q+z-e=0

\alpha _{4}=e^{3}(e+2)(a+1)^{2}+1-o^{2}=0

\alpha _{5}=(a^{2}-1)y^{2}+1-x^{2}=0

\alpha _{6}=16r^{2}y^{4}(a^{2}-1)+1-u^{2}=0

\alpha _{7}=n+l+v-y=0

\alpha _{8}=(a^{2}-1)l^{2}+1-m^{2}=0

\alpha _{9}=ai+k+1-l-i=0

\alpha _{{10}}=((a+u^{2}(u^{2}-a))^{2}-1)(n+4dy)^{2}+1-(x+cu)^{2}=0

\alpha _{{11}}=p+l(a-n-1)+b(2an+2a-n^{2}-2n-2)-m=0

\alpha _{{12}}=q+y(a-p-1)+s(2ap+2a-p^{2}-2p-2)-x=0

\alpha _{{13}}=z+pl(a-p)+t(2ap-p^{2}-1)-pm=0

The 14 equations α₀, …, α₁₃ can be used to produce a prime-generating polynomial inequality in 26 variables:

(k+2)(1-\alpha_0^2-\alpha_1^2-\cdots-\alpha_{13}^2) > 0

i.e.:

(k+2) (1 -

[wz + h + j - q]^2 -

[(gk + 2g + k + 1)(h + j) + h - z]^2 -

[16(k + 1)^3(k + 2)(n + 1)^2 + 1 - f^2]^2 -

[2n + p + q + z - e]^2 -

[e^3(e + 2)(a + 1)^2 + 1 - o^2]^2 -

[(a^2 - 1)y^2 + 1 - x^2]^2 -

[16r^2y^4(a^2 - 1) + 1 - u^2]^2 -

[n + l + v - y]^2 -

[(a^2 - 1)l^2 + 1 - m^2]^2 -

[ai + k + 1 - l - i]^2 -

[((a + u^2(u^2 - a))^2 - 1)(n + 4dy)^2 + 1 - (x + cu)^2]^2 -

[p + l(a - n - 1) + b(2an + 2a - n^2 - 2n - 2) - m]^2 -

[q + y(a - p - 1) + s(2ap + 2a - p^2 - 2p - 2) - x]^2 -

[z + pl(a - p) + t(2ap - p^2 - 1) - pm]^2)

> 0

is a polynomial inequality in 26 variables, and the set of prime numbers is identical to the set of positive values taken on by the left-hand side as the variables a, b, …, z range over the nonnegative integers.

A general theorem of Matiyasevich says that if a set is defined by a system of Diophantine equations, it can also be defined by a system of Diophantine equations in only 9 variables (Matiyasevich 1999). Hence, there is a prime-generating polynomial as above with only 10 variables. However, its degree is large (in the order of 10⁴⁵). On the other hand, there also exists such a set of equations of degree only 4, but in 58 variables. See (Jones 1982).

Mills' formula

The first such formula known was established by W. H. Mills (1947), who proved that there exists a real number A such that

\lfloor A^{3^{n}}\;\rfloor

is a prime number for all positive integers n. If the Riemann hypothesis is true, then the smallest such A has a value of around 1.3063... and is known as Mills' constant. This formula has no practical value, because very little is known about the constant (not even whether it is rational), and there is no known way of calculating the constant without finding primes in the first place.

Recurrence relations

Another prime generator is defined by the recurrence relation

a_n = a_{n-1} + \operatorname{gcd}(n,a_{n-1}), \quad a_1 = 7,

where gcd(x, y) denotes the greatest common divisor of x and y. The sequence of differences a_{n + 1} − a_n starts with 1, 1, 1, 5, 3, 1, 1, 1, 1, 11, 3, 1, 1, ... (sequence A132199 in the OEIS). Rowland (2008) proved that this sequence contains only ones and prime numbers.

Because the set of primes is a recursive set of natural numbers, it is therefore recursively enumerable ^[1] which is the same as computably enumerable. Therefore there exist such computable functions which list not only a subset the prime numbers, but all of them. (See also the section on Matsiveyich's theorem which derives a different conclusion from the same hypothesis).

References

↑ Encyclopeida of mathematics "Recursive set theory"

Jones, James P.; Sato, Daihachiro; Wada, Hideo; Wiens, Douglas (1976), "Diophantine representation of the set of prime numbers", American Mathematical Monthly, Mathematical Association of America, 83 (6): 449–464, doi:10.2307/2318339, JSTOR 2318339 .
Jones, James P. (1982), "Universal diophantine equation", Journal of Symbolic Logic, 47 (3): 549–571, doi:10.2307/2273588 .
Matiyasevich, Yuri V. (1999), "Formulas for Prime Numbers", in Tabachnikov, Serge, Kvant Selecta: Algebra and Analysis, II, American Mathematical Society, pp. 13–24, ISBN 978-0-8218-1915-9 .
Mills, W. H. (1947), "A prime-representing function" (PDF), Bulletin of the American Mathematical Society, 53 (6): 604, arXiv:1408.1888, doi:10.1090/S0002-9904-1947-08849-2 .
Perichon, Benoãt (2010), A World Record AP26 (Arithmetic Progression of 26 primes) (PDF) , The AP26 is listed in "Jens Kruse Andersen's Primes in Arithmetic Progression Records page", retrieved 2014-06-25.
Regimbal, Stephen (1975), "An explicit Formula for the k-th prime number", Mathematics Magazine, Mathematical Association of America, 48 (4): 230–232, doi:10.2307/2690354, JSTOR 2690354 .
Rowland, Eric S. (2008), "A Natural Prime-Generating Recurrence", Journal of Integer Sequences, 11: 08.2.8, arXiv:0710.3217, Bibcode:2008JIntS..11...28R .

External links

Weisstein, Eric W. "Prime Formulas". MathWorld.

Weisstein, Eric W. "Prime-Generating Polynomial". MathWorld.

Weisstein, Eric W. "Mill's Constant". MathWorld.

A Venugopalan. Formula for primes, twinprimes, number of primes and number of twinprimes. Proceedings of the Indian Academy of Sciences—Mathematical Sciences, Vol. 92, No 1, September 1983, pp. 49–52. Page 49, 50, 51, 52, errata.

Prime number classes

By formula	Fermat (2^2ⁿ + 1) Mersenne (2^p − 1) Double Mersenne (2^{2^p−1} − 1) Wagstaff (2^p + 1)/3 Proth (k·2ⁿ + 1) Factorial (n! ± 1) Primorial (p_n# ± 1) Euclid (p_n# + 1) Pythagorean (4n + 1) Pierpont (2^u·3^v + 1) Quartan (x⁴ + y⁴) Solinas (2^a ± 2^b ± 1) Cullen (n·2ⁿ + 1) Woodall (n·2ⁿ − 1) Cuban (x³ − y³)/(x − y) Carol (2ⁿ − 1)² − 2 Kynea (2ⁿ + 1)² − 2 Leyland (x^y + y^x) Thabit (3·2ⁿ − 1) Mills (floor(A^3ⁿ))

By integer sequence	Fibonacci Lucas Pell Newman–Shanks–Williams Perrin Partitions Bell Motzkin

By property	Wieferich (pair) Wall–Sun–Sun Wolstenholme Wilson Lucky Fortunate Ramanujan Pillai Regular Strong Stern Supersingular (elliptic curve) Supersingular (moonshine theory) Good Super Higgs Highly cototient

Base-dependent	Happy Dihedral Palindromic Emirp Repunit (10ⁿ − 1)/9 Permutable Circular Truncatable Strobogrammatic Minimal Weakly Full reptend Unique Primeval Self Smarandache–Wellin

Patterns	Twin (p, p + 2) Bi-twin chain (n − 1, n + 1, 2n − 1, 2n + 1, …) Triplet (p, p + 2 or p + 4, p + 6) Quadruplet (p, p + 2, p + 6, p + 8) k−Tuple Cousin (p, p + 4) Sexy (p, p + 6) Chen Sophie Germain (p, 2p + 1) Cunningham chain (p, 2p ± 1, …) Safe (p, (p − 1)/2) Arithmetic progression (p + a·n, n = 0, 1, …) Balanced (consecutive p − n, p, p + n)

By size	Titanic (1,000+ digits) Gigantic (10,000+) Mega (1,000,000+) Largest known

Complex numbers	Eisenstein prime Gaussian prime

Composite numbers	Pseudoprime Almost prime Semiprime Interprime

Related topics	Probable prime Industrial-grade prime Illegal prime Formula for primes Prime gap

First 50 primes	2 3 5 7 11 13 17 19 23 29 31 37 41 43 47 53 59 61 67 71 73 79 83 89 97 101 103 107 109 113 127 131 137 139 149 151 157 163 167 173 179 181 191 193 197 199 211 223 227 229

List of prime numbers

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