Agrawal's conjecture

In number theory, Agrawal's conjecture, due to Manindra Agrawal in 2002,^[1] forms the basis for the cyclotomic AKS test. Agrawal's conjecture states formally:

Let $n$ and $r$ be two coprime positive integers. If

(X-1)^{n}\equiv X^{n}-1{\pmod {n,\,X^{r}-1}}\,

then either $n$ is prime or $n^{2}\equiv 1{\pmod {r}}$

Ramifications[edit]

If Agrawal's conjecture were true, it would decrease the runtime complexity of the AKS primality test from ${\tilde {O}}{\mathord {\left(\log ^{6}n\right)}}$ to ${\tilde {O}}{\mathord {\left(\log ^{3}n\right)}}$ .

Truth or falsehood[edit]

The conjecture was formulated by Rajat Bhattacharjee and Prashant Pandey in their 2001 thesis.^[2] It has been computationally verified for $r<100$ and $n<10^{10}$ ,^[3] and for $r=5,n<10^{11}$ .^[4]

However, a heuristic argument by Carl Pomerance and Hendrik W. Lenstra suggests there are infinitely many counterexamples.^[5] In particular, the heuristic shows that such counterexamples have asymptotic density greater than ${\tfrac {1}{n^{\varepsilon }}}$ for any $\varepsilon >0$ .

Assuming Agrawal's conjecture is false by the above argument, Roman B. Popovych conjectures a modified version may still be true:

Let $n$ and $r$ be two coprime positive integers. If

(X-1)^{n}\equiv X^{n}-1{\pmod {n,\,X^{r}-1}}

and

(X+2)^{n}\equiv X^{n}+2{\pmod {n,\,X^{r}-1}}

then either $n$ is prime or $n^{2}\equiv 1{\pmod {r}}$ .^[6]

Distributed computing[edit]

Both Agrawal's conjecture and Popovych's conjecture were tested by distributed computing project Primaboinca which ran from 2010 to 2020, based on BOINC. The project found no counterexample, searching in $10^{10}<n<10^{17}$ .

Notes[edit]

^ Agrawal, Manindra; Kayal, Neeraj; Saxena, Nitin (2004). "PRIMES is in P" (PDF). Annals of Mathematics. 160 (2): 781–793. doi:10.4007/annals.2004.160.781. JSTOR 3597229.
^ Rajat Bhattacharjee, Prashant Pandey (April 2001). "Primality Testing". Technical Report. IIT Kanpur.
^ Neeraj Kayal, Nitin Saxena (2002). "Towards a deterministic polynomial-time Primality Test". Technical Report. IIT Kanpur. CiteSeerX 10.1.1.16.9281.
^ Saxena, Nitin (Dec 2014). "Primality & Prime Number Generation" (PDF). UPMC Paris. Archived from the original (PDF) on 25 April 2018. Retrieved 24 April 2018.
^ Lenstra, H. W.; Pomerance, Carl (2003). "Remarks on Agrawal's conjecture" (PDF). American Institute of Mathematics. Retrieved 16 October 2013.
^ Popovych, Roman (30 December 2008), A note on Agrawal conjecture (PDF), retrieved 21 April 2018

External links[edit]

Primaboinca project

[AKS-1] Agrawal, Manindra; Kayal, Neeraj; Saxena, Nitin (2004). "PRIMES is in P" (PDF). Annals of Mathematics. 160 (2): 781–793. doi:10.4007/annals.2004.160.781. JSTOR 3597229.

[2] Rajat Bhattacharjee, Prashant Pandey (April 2001). "Primality Testing". Technical Report. IIT Kanpur.

[3] Neeraj Kayal, Nitin Saxena (2002). "Towards a deterministic polynomial-time Primality Test". Technical Report. IIT Kanpur. CiteSeerX 10.1.1.16.9281.

[4] Saxena, Nitin (Dec 2014). "Primality & Prime Number Generation" (PDF). UPMC Paris. Archived from the original (PDF) on 25 April 2018. Retrieved 24 April 2018.

[LP03b-5] Lenstra, H. W.; Pomerance, Carl (2003). "Remarks on Agrawal's conjecture" (PDF). American Institute of Mathematics. Retrieved 16 October 2013.

[6] Popovych, Roman (30 December 2008), A note on Agrawal conjecture (PDF), retrieved 21 April 2018

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