Agoh–Giuga conjecture
Template:Short description In number theory the Agoh–Giuga conjecture on the Bernoulli numbers Bk postulates that p is a prime number if and only if
- <math>pB_{p-1} \equiv -1 \pmod p.</math>
It is named after Takashi Agoh and Giuseppe Giuga.
Equivalent formulationEdit
The conjecture as stated above is due to Takashi Agoh (1990); an equivalent formulation is due to Giuseppe Giuga, from 1950, to the effect that p is prime if and only if
- <math>1^{p-1}+2^{p-1}+ \cdots +(p-1)^{p-1} \equiv -1 \pmod p</math>
which may also be written as
- <math>\sum_{i=1}^{p-1} i^{p-1} \equiv -1 \pmod p.</math>
It is trivial to show that p being prime is sufficient for the second equivalence to hold, since if p is prime, Fermat's little theorem states that
- <math>a^{p-1} \equiv 1 \pmod p</math>
for <math>a = 1,2,\dots,p-1</math>, and the equivalence follows, since <math>p-1 \equiv -1 \pmod p.</math>
StatusEdit
The statement is still a conjecture since it has not yet been proven that if a number n is not prime (that is, n is composite), then the formula does not hold. It has been shown that a composite number n satisfies the formula if and only if it is both a Carmichael number and a Giuga number, and that if such a number exists, it has at least 13,800 digits (Borwein, Borwein, Borwein, Girgensohn 1996). Laerte Sorini, in a work of 2001 showed that a possible counterexample should be a number n greater than 1036067 which represents the limit suggested by Bedocchi for the demonstration technique specified by Giuga to his own conjecture.
Relation to Wilson's theoremEdit
The Agoh–Giuga conjecture bears a similarity to Wilson's theorem, which has been proven to be true. Wilson's theorem states that a number p is prime if and only if
- <math>(p-1)! \equiv -1 \pmod p,</math>
which may also be written as
- <math>\prod_{i=1}^{p-1} i \equiv -1 \pmod p.</math>
For an odd prime p we have
- <math>\prod_{i=1}^{p-1} i^{p-1} \equiv (-1)^{p-1} \equiv 1 \pmod p,</math>
and for p=2 we have
- <math>\prod_{i=1}^{p-1} i^{p-1} \equiv (-1)^{p-1} \equiv 1 \pmod p.</math>
So, the truth of the Agoh–Giuga conjecture combined with Wilson's theorem would give: a number p is prime if and only if
- <math>\sum_{i=1}^{p-1} i^{p-1} \equiv -1 \pmod p</math>
and
- <math>\prod_{i=1}^{p-1} i^{p-1} \equiv 1 \pmod p.</math>