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Carmichael function

 
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In number theory, the Carmichael function of a positive integer n, denoted λ(n), is defined as the smallest positive integer m such that

a^m \equiv 1 \pmod{n}

for every integer a that is coprime to n.

In other words, in more algebraic terms, it defines the exponent of the multiplicative group of residues modulo n.

The first 26 values of λ(n) for n = 1, 2, 3, ... are 1, 1, 2, 2, 4, 2, 6, 2, 6, 4, 10, 2, 12, 6, 4, 4, 16, 6, 18, 4, 6, 10, 22, 2, 20, 12, ... (sequence A002322 in OEIS)

Contents

Carmichael's theorem

This function can also be defined recursively, as follows.

For prime p and positive integer k such that p \ge 3 or k \le 2:

\lambda(p^k) = p^{k-1}(p-1).\, (This is equal to Euler's totient function, \varphi(p^k)\, )

For integer k \ge 3,

\lambda(2^k) = 2^{k-2}\, .

For distinct primes p_1,p_2,\ldots,p_t and positive integers k_1,k_2,\ldots,k_t:

\lambda(p_1^{k_1} p_2^{k_2} \cdots p_t^{k_t}) = \mathrm{lcm}( \lambda(p_1^{k_1}), \lambda(p_2^{k_2}), \ldots, \lambda(p_t^{k_t}) )

where lcm denotes the least common multiple.

Carmichael's theorem states that if a is coprime to n, then

a^{\lambda(n)} \equiv 1 \pmod{n},

where λ is the Carmichael function defined recursively. In other words, it asserts the correctness of the recursion. This can be proven by considering any Primitive root modulo n and the Chinese remainder theorem.

Hierarchy of results

The classical Euler's theorem implies that λ(n) divides φ(n), the Euler's totient function. In fact Carmichael's theorem is related to Euler's theorem, because the exponent of a finite abelian group must divide the order of the group, by elementary group theory. The two functions differ already in small cases: λ(15) = 4 while φ(15) = 8.

Fermat's little theorem is the special case of Euler's theorem in which n is a prime number p. Carmichael's theorem for a prime p adds nothing to Fermat's theorem, because the group in question is a cyclic group for which the order and exponent are both p − 1.

Properties of the Carmichael function

Average and typical value

For any x > 16, and a constant B ≈ 0.34537:

\frac{1}{x} \sum_{n \leq x} \lambda (n) = \frac{x}{\ln x} e^{B(\ln\ln x) (1+o(1)) / (\ln\ln\ln x) }.[1]

For all numbers N and all except o(N) positive integers n ≤ N:

\lambda(n) = n / (\ln n)^{\ln\ln\ln n + A + o(1)}\,

where A is a constant, A ≈ 0.226969.[2]

Lower bounds

For any sufficiently large number N and for any \Delta \geq (\ln\ln N)^3, there are at most

Ne^{-0.69(\Delta\ln\Delta)^{1/3}}

positive integers n \leq N such that \lambda(n) \leq ne^{-\Delta}.[3]

For any sequence n_1<n_2<n_3<\cdots of positive integers, any constant 0 < c < 1 / ln2, and any sufficiently large i:

\lambda(n_i) > (\ln n_i)^{c\ln\ln\ln n_i}.[4]

Small values

For a constant c and any sufficiently large positive A, there exists an integer n > A such that λ(n) < (lnA)clnlnlnA. Moreover, n is of the form

n = q
(q − 1) | m and q is prime

for some square-free integer m < (lnA)clnlnlnA.[5]

See also

Notes

  1. ^ Theorem 3 in Erdös (1991)
  2. ^ Theorem 2 in Erdös (1991)
  3. ^ Theorem 5 in Friedlander (2001)
  4. ^ Theorem 1 in Erdös 1991
  5. ^ Theorem 1 in Erdös 1991

References

  • John Friedlander, Carl Pomerance, Igor E. Shparlinski (2001) Period of the power generator and small values of the Carmichael function, Mathematics of Computation, vol. 70 no. 236, pp. 1591-1605.

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