Modulus (algebraic number theory)

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In mathematics, in the field of algebraic number theory, a modulus (plural moduli) (or cycle,^[1] or extended ideal^[2]) is a formal product of places of a global field (i.e. an algebraic number field or a global function field). It is used to encode ramification data for abelian extensions of a global field.

Let K be a global field with ring of integers R. A modulus is a formal product^[3][4]

${\displaystyle 𝐦=\prod _{𝐩}{𝐩}^{\nu (𝐩)},\nu (𝐩)\ge 0}$

where p runs over all places of K, finite or infinite, the exponents ν(p) are zero except for finitely many p. If K is a number field, ν(p) = 0 or 1 for real places and ν(p) = 0 for complex places. If K is a function field, ν(p) = 0 for all infinite places.

In the function field case, a modulus is the same thing as an effective divisor,^[5] and in the number field case, a modulus can be considered as special form of Arakelov divisor.^[6]

The notion of congruence can be extended to the setting of moduli. If a and b are elements of K^×, the definition of a ≡^∗b (mod p^ν) depends on what type of prime p is:^[7][8]

• if it is finite, then

${\displaystyle a{\equiv }^{\ast }b(\mathrm{m}\mathrm{o}\mathrm{d}{𝐩}^{\nu })\iff {\mathrm{o}\mathrm{r}\mathrm{d}}_{𝐩}(\frac{a}{b}-1)\ge \nu }$

where ord_p is the normalized valuation associated to p;

• if it is a real place (of a number field) and ν = 1, then

${\displaystyle a{\equiv }^{\ast }b(\mathrm{m}\mathrm{o}\mathrm{d}𝐩)\iff \frac{a}{b}>0}$

under the real embedding associated to p.

• if it is any other infinite place, there is no condition.

Then, given a modulus m, a ≡^∗b (mod m) if a ≡^∗b (mod p^ν(p)) for all p such that ν(p) > 0.

Template:Main The ray modulo m is^[9][10][11]

${\displaystyle K_{𝐦,1}=\{a\in K^{\times }:a{\equiv }^{\ast }1(\mathrm{m}\mathrm{o}\mathrm{d}𝐦)\}.}$

A modulus m can be split into two parts, m_f and m_∞, the product over the finite and infinite places, respectively. Let I^m to be one of the following:

• if K is a number field, the subgroup of the group of fractional ideals generated by ideals coprime to m_f;^[12]
• if K is a function field of an algebraic curve over k, the group of divisors, rational over k, with support away from m.^[13]

In both case, there is a group homomorphism i : K_m,1 → I^m obtained by sending a to the principal ideal (resp. divisor) (a).

The ray class group modulo m is the quotient C_m = I^m / i(K_m,1).^[14][15] A coset of i(K_m,1) is called a ray class modulo m.

Erich Hecke's original definition of Hecke characters may be interpreted in terms of characters of the ray class group with respect to some modulus m.^[16]

When K is a number field, the following properties hold.^[17]

• When m = 1, the ray class group is just the ideal class group.
• The ray class group is finite. Its order is the ray class number.
• The ray class number is divisible by the class number of K.

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