Dirichlet theorem on the group of units of a number field #
This file is devoted to the proof of Dirichlet unit theorem that states that the group of
units (π K)Λ£
of units of the ring of integers π K
of a number field K
modulo its torsion
subgroup is a free β€
-module of rank card (InfinitePlace K) - 1
.
Main definitions #
NumberField.Units.rank
: the unit rank of the number fieldK
.NumberField.Units.fundSystem
: a fundamental system of units ofK
.NumberField.Units.basisModTorsion
: aβ€
-basis of(π K)Λ£ β§Έ (torsion K)
as an additiveβ€
-module.
Main results #
NumberField.Units.rank_modTorsion
: theβ€
-rank of(π K)Λ£ β§Έ (torsion K)
is equal tocard (InfinitePlace K) - 1
.NumberField.Units.exist_unique_eq_mul_prod
: Dirichlet Unit Theorem. Any unit ofπ K
can be written uniquely as the product of a root of unity and powers of the units of the fundamental systemfundSystem
.
Tags #
number field, units, Dirichlet unit theorem
Dirichlet Unit Theorem #
We define a group morphism from (π K)Λ£
to {w : InfinitePlace K // w β wβ} β β
where wβ
is a
distinguished (arbitrary) infinite place, prove that its kernel is the torsion subgroup (see
logEmbedding_eq_zero_iff
) and that its image, called unitLattice
, is a full β€
-lattice. It
follows that unitLattice
is a free β€
-module (see instModuleFree_unitLattice
) of rank
card (InfinitePlaces K) - 1
(see unitLattice_rank
). To prove that the unitLattice
is a full
β€
-lattice, we need to prove that it is discrete (see unitLattice_inter_ball_finite
) and that it
spans the full space over β
(see unitLattice_span_eq_top
); this is the main part of the proof,
see the section span_top
below for more details.
The distinguished infinite place.
Equations
- NumberField.Units.dirichletUnitTheorem.wβ = β―.some
Instances For
The logarithmic embedding of the units (seen as an Additive
group).
Equations
- One or more equations did not get rendered due to their size.
Instances For
The lattice formed by the image of the logarithmic embedding.
Equations
- NumberField.Units.unitLattice K = Submodule.map (NumberField.Units.logEmbedding K).toIntLinearMap β€
Instances For
Section span_top
#
In this section, we prove that the span over β
of the unitLattice
is equal to the full space.
For this, we construct for each infinite place wβ β wβ
a unit u_wβ
of K
such that, for all
infinite places w
such that w β wβ
, we have Real.log w (u_wβ) < 0
(and thus Real.log wβ (u_wβ) > 0
). It follows then from a determinant computation
(using Matrix.det_ne_zero_of_sum_col_lt_diag
) that the image by logEmbedding
of these units is
a β
-linearly independent family. The unit u_wβ
is obtained by constructing a sequence seq n
of nonzero algebraic integers that is strictly decreasing at infinite places distinct from wβ
and
of norm β€ B
. Since there are finitely many ideals of norm β€ B
, there exists two term in the
sequence defining the same ideal and their quotient is the desired unit u_wβ
(see exists_unit
).
This result shows that there always exists a next term in the sequence.
An infinite sequence of nonzero algebraic integers of K
satisfying the following properties:
β’ seq n
is nonzero;
β’ for w : InfinitePlace K
, w β wβ β w (seq n+1) < w (seq n)
;
β’ β£norm (seq n)β£ β€ B
.
Equations
- NumberField.Units.dirichletUnitTheorem.seq K wβ hB 0 = β¨1, β―β©
- NumberField.Units.dirichletUnitTheorem.seq K wβ hB n.succ = β¨β―.choose, β―β©
Instances For
The terms of the sequence are nonzero.
The sequence is strictly decreasing at infinite places distinct from wβ
.
The terms of the sequence have norm bounded by B
.
Construct a unit associated to the place wβ
. The family, for wβ β wβ
, formed by the
image by the logEmbedding
of these units is β
-linearly independent, see
unitLattice_span_eq_top
.
The unit rank of the number field K
, it is equal to card (InfinitePlace K) - 1
.
Equations
Instances For
Equations
- β― = β―
Equations
- β― = β―
The map obtained by quotienting by the kernel of logEmbedding
.
Equations
- One or more equations did not get rendered due to their size.
Instances For
The linear equivalence between (π K)Λ£ β§Έ (torsion K)
as an additive β€
-module and
unitLattice
.
Equations
- NumberField.Units.logEmbeddingEquiv K = LinearEquiv.ofBijective ((NumberField.Units.logEmbeddingQuot K).codRestrict (NumberField.Units.unitLattice K) β―).toIntLinearMap β―
Instances For
Equations
- β― = β―
Equations
- β― = β―
Equations
- β― = β―
Equations
- β― = β―
A basis of the quotient (π K)Λ£ β§Έ (torsion K)
seen as an additive β€-module.
Equations
Instances For
The basis of the unitLattice
obtained by mapping basisModTorsion
via logEmbedding
.
Equations
Instances For
A fundamental system of units of K
. The units of fundSystem
are arbitrary lifts of the
units in basisModTorsion
.
Equations
- NumberField.Units.fundSystem K i = Quotient.out' (Additive.toMul ((NumberField.Units.basisModTorsion K) i))
Instances For
The exponents that appear in the unique decomposition of a unit as the product of
a root of unity and powers of the units of the fundamental system fundSystem
(see
exist_unique_eq_mul_prod
) are given by the representation of the unit on basisModTorsion
.
Dirichlet Unit Theorem. Any unit x
of π K
can be written uniquely as the product of
a root of unity and powers of the units of the fundamental system fundSystem
.