- Source: Adele ring
In mathematics, the adele ring of a global field (also adelic ring, ring of adeles or ring of adèles) is a central object of class field theory, a branch of algebraic number theory. It is the restricted product of all the completions of the global field and is an example of a self-dual topological ring.
An adele derives from a particular kind of idele. "Idele" derives from the French "idèle" and was coined by the French mathematician Claude Chevalley. The word stands for 'ideal element' (abbreviated: id.el.). Adele (French: "adèle") stands for 'additive idele' (that is, additive ideal element).
The ring of adeles allows one to describe the Artin reciprocity law, which is a generalisation of quadratic reciprocity, and other reciprocity laws over finite fields. In addition, it is a classical theorem from Weil that
G
{\displaystyle G}
-bundles on an algebraic curve over a finite field can be described in terms of adeles for a reductive group
G
{\displaystyle G}
. Adeles are also connected with the adelic algebraic groups and adelic curves.
The study of geometry of numbers over the ring of adeles of a number field is called adelic geometry.
Definition
Let
K
{\displaystyle K}
be a global field (a finite extension of
Q
{\displaystyle \mathbf {Q} }
or the function field of a curve
X
/
F
q
{\displaystyle X/\mathbf {F_{\mathit {q}}} }
over a finite field). The adele ring of
K
{\displaystyle K}
is the subring
A
K
=
∏
(
K
ν
,
O
ν
)
⊆
∏
K
ν
{\displaystyle \mathbf {A} _{K}\ =\ \prod (K_{\nu },{\mathcal {O}}_{\nu })\ \subseteq \ \prod K_{\nu }}
consisting of the tuples
(
a
ν
)
{\displaystyle (a_{\nu })}
where
a
ν
{\displaystyle a_{\nu }}
lies in the subring
O
ν
⊂
K
ν
{\displaystyle {\mathcal {O}}_{\nu }\subset K_{\nu }}
for all but finitely many places
ν
{\displaystyle \nu }
. Here the index
ν
{\displaystyle \nu }
ranges over all valuations of the global field
K
{\displaystyle K}
,
K
ν
{\displaystyle K_{\nu }}
is the completion at that valuation and
O
ν
{\displaystyle {\mathcal {O}}_{\nu }}
the corresponding valuation ring.
= Motivation
=The ring of adeles solves the technical problem of "doing analysis on the rational numbers
Q
{\displaystyle \mathbf {Q} }
." The classical solution was to pass to the standard metric completion
R
{\displaystyle \mathbf {R} }
and use analytic techniques there. But, as was learned later on, there are many more absolute values other than the Euclidean distance, one for each prime number
p
∈
Z
{\displaystyle p\in \mathbf {Z} }
, as was classified by Ostrowski. The Euclidean absolute value, denoted
|
⋅
|
∞
{\displaystyle |\cdot |_{\infty }}
, is only one among many others,
|
⋅
|
p
{\displaystyle |\cdot |_{p}}
, but the ring of adeles makes it possible to comprehend and use all of the valuations at once. This has the advantage of enabling analytic techniques while also retaining information about the primes, since their structure is embedded by the restricted infinite product.
The purpose of the adele ring is to look at all completions of
K
{\displaystyle K}
at once. The adele ring is defined with the restricted product, rather than the Cartesian product. There are two reasons for this:
For each element of
K
{\displaystyle K}
the valuations are zero for almost all places, i.e., for all places except a finite number. So, the global field can be embedded in the restricted product.
The restricted product is a locally compact space, while the Cartesian product is not. Therefore, there cannot be any application of harmonic analysis to the Cartesian product. This is because local compactness ensures the existence (and uniqueness) of Haar measure, a crucial tool in analysis on groups in general.
Why the restricted product?
The restricted infinite product is a required technical condition for giving the number field
Q
{\displaystyle \mathbf {Q} }
a lattice structure inside of
A
Q
{\displaystyle \mathbf {A} _{\mathbf {Q} }}
, making it possible to build a theory of Fourier analysis (cf. Harmonic analysis) in the adelic setting. This is analogous to the situation in algebraic number theory where the ring of integers of an algebraic number field embeds
O
K
↪
K
{\displaystyle {\mathcal {O}}_{K}\hookrightarrow K}
as a lattice. With the power of a new theory of Fourier analysis, Tate was able to prove a special class of L-functions and the Dedekind zeta functions were meromorphic on the complex plane. Another natural reason for why this technical condition holds can be seen by constructing the ring of adeles as a tensor product of rings. If defining the ring of integral adeles
A
Z
{\displaystyle \mathbf {A} _{\mathbf {Z} }}
as the ring
A
Z
=
R
×
Z
^
=
R
×
∏
p
Z
p
,
{\displaystyle \mathbf {A} _{\mathbf {Z} }=\mathbf {R} \times {\hat {\mathbf {Z} }}=\mathbf {R} \times \prod _{p}\mathbf {Z} _{p},}
then the ring of adeles can be equivalently defined as
A
Q
=
Q
⊗
Z
A
Z
=
Q
⊗
Z
(
R
×
∏
p
Z
p
)
.
{\displaystyle {\begin{aligned}\mathbf {A} _{\mathbf {Q} }&=\mathbf {Q} \otimes _{\mathbf {Z} }\mathbf {A} _{\mathbf {Z} }\\&=\mathbf {Q} \otimes _{\mathbf {Z} }\left(\mathbf {R} \times \prod _{p}\mathbf {Z} _{p}\right).\end{aligned}}}
The restricted product structure becomes transparent after looking at explicit elements in this ring. The image of an element
b
/
c
⊗
(
r
,
(
a
p
)
)
∈
A
Q
{\displaystyle b/c\otimes (r,(a_{p}))\in \mathbf {A} _{\mathbf {Q} }}
inside of the unrestricted product
R
×
∏
p
Q
p
{\textstyle \mathbf {R} \times \prod _{p}\mathbf {Q} _{p}}
is the element
(
b
r
c
,
(
b
a
p
c
)
)
.
{\displaystyle \left({\frac {br}{c}},\left({\frac {ba_{p}}{c}}\right)\right).}
The factor
b
a
p
/
c
{\displaystyle ba_{p}/c}
lies in
Z
p
{\displaystyle \mathbf {Z} _{p}}
whenever
p
{\displaystyle p}
is not a prime factor of
c
{\displaystyle c}
, which is the case for all but finitely many primes
p
{\displaystyle p}
.
= Origin of the name
=The term "idele" (French: idèle) is an invention of the French mathematician Claude Chevalley (1909–1984) and stands for "ideal element" (abbreviated: id.el.). The term "adele" (French: adèle) stands for additive idele. Thus, an adele is an additive ideal element.
Examples
= Ring of adeles for the rational numbers
=The rationals
K
=
Q
{\displaystyle K={\mathbf {Q}}}
have a valuation for every prime number
p
{\displaystyle p}
, with
(
K
ν
,
O
ν
)
=
(
Q
p
,
Z
p
)
{\displaystyle (K_{\nu },{\mathcal {O}}_{\nu })=(\mathbf {Q} _{p},\mathbf {Z} _{p})}
, and one infinite valuation ∞ with
Q
∞
=
R
{\displaystyle \mathbf {Q} _{\infty }=\mathbf {R} }
. Thus an element of
A
Q
=
R
×
∏
p
(
Q
p
,
Z
p
)
{\displaystyle \mathbf {A} _{\mathbf {Q} }\ =\ \mathbf {R} \times \prod _{p}(\mathbf {Q} _{p},\mathbf {Z} _{p})}
is a real number along with a p-adic rational for each
p
{\displaystyle p}
of which all but finitely many are p-adic integers.
= Ring of adeles for the function field of the projective line
=Secondly, take the function field
K
=
F
q
(
P
1
)
=
F
q
(
t
)
{\displaystyle K=\mathbf {F} _{q}(\mathbf {P} ^{1})=\mathbf {F} _{q}(t)}
of the projective line over a finite field. Its valuations correspond to points
x
{\displaystyle x}
of
X
=
P
1
{\displaystyle X=\mathbf {P} ^{1}}
, i.e. maps over
Spec
F
q
{\displaystyle {\text{Spec}}\mathbf {F} _{q}}
x
:
Spec
F
q
n
⟶
P
1
.
{\displaystyle x\ :\ {\text{Spec}}\mathbf {F} _{q^{n}}\ \longrightarrow \ \mathbf {P} ^{1}.}
For instance, there are
q
+
1
{\displaystyle q+1}
points of the form
Spec
F
q
⟶
P
1
{\displaystyle {\text{Spec}}\mathbf {F} _{q}\ \longrightarrow \ \mathbf {P} ^{1}}
. In this case
O
ν
=
O
^
X
,
x
{\displaystyle {\mathcal {O}}_{\nu }={\widehat {\mathcal {O}}}_{X,x}}
is the completed stalk of the structure sheaf at
x
{\displaystyle x}
(i.e. functions on a formal neighbourhood of
x
{\displaystyle x}
) and
K
ν
=
K
X
,
x
{\displaystyle K_{\nu }=K_{X,x}}
is its fraction field. Thus
A
F
q
(
P
1
)
=
∏
x
∈
X
(
K
X
,
x
,
O
^
X
,
x
)
.
{\displaystyle \mathbf {A} _{\mathbf {F} _{q}(\mathbf {P} ^{1})}\ =\ \prod _{x\in X}({\mathcal {K}}_{X,x},{\widehat {\mathcal {O}}}_{X,x}).}
The same holds for any smooth proper curve
X
/
F
q
{\displaystyle X/\mathbf {F_{\mathit {q}}} }
over a finite field, the restricted product being over all points of
x
∈
X
{\displaystyle x\in X}
.
Related notions
The group of units in the adele ring is called the idele group
I
K
=
A
K
×
{\displaystyle I_{K}=\mathbf {A} _{K}^{\times }}
.
The quotient of the ideles by the subgroup
K
×
⊆
I
K
{\displaystyle K^{\times }\subseteq I_{K}}
is called the idele class group
C
K
=
I
K
/
K
×
.
{\displaystyle C_{K}\ =\ I_{K}/K^{\times }.}
The integral adeles are the subring
O
K
=
∏
O
ν
⊆
A
K
.
{\displaystyle \mathbf {O} _{K}\ =\ \prod O_{\nu }\ \subseteq \ \mathbf {A} _{K}.}
Applications
= Stating Artin reciprocity
=The Artin reciprocity law says that for a global field
K
{\displaystyle K}
,
C
K
^
=
A
K
×
/
K
×
^
≃
Gal
(
K
ab
/
K
)
{\displaystyle {\widehat {C_{K}}}={\widehat {\mathbf {A} _{K}^{\times }/K^{\times }}}\ \simeq \ {\text{Gal}}(K^{\text{ab}}/K)}
where
K
a
b
{\displaystyle K^{ab}}
is the maximal abelian algebraic extension of
K
{\displaystyle K}
and
(
…
)
^
{\displaystyle {\widehat {(\dots )}}}
means the profinite completion of the group.
= Giving adelic formulation of Picard group of a curve
=If
X
/
F
q
{\displaystyle X/\mathbf {F_{\mathit {q}}} }
is a smooth proper curve then its Picard group is
Pic
(
X
)
=
K
×
∖
A
X
×
/
O
X
×
{\displaystyle {\text{Pic}}(X)\ =\ K^{\times }\backslash \mathbf {A} _{X}^{\times }/\mathbf {O} _{X}^{\times }}
and its divisor group is
Div
(
X
)
=
A
X
×
/
O
X
×
{\displaystyle {\text{Div}}(X)=\mathbf {A} _{X}^{\times }/\mathbf {O} _{X}^{\times }}
. Similarly, if
G
{\displaystyle G}
is a semisimple algebraic group (e.g.
S
L
n
{\textstyle SL_{n}}
, it also holds for
G
L
n
{\displaystyle GL_{n}}
) then Weil uniformisation says that
Bun
G
(
X
)
=
G
(
K
)
∖
G
(
A
X
)
/
G
(
O
X
)
.
{\displaystyle {\text{Bun}}_{G}(X)\ =\ G(K)\backslash G(\mathbf {A} _{X})/G(\mathbf {O} _{X}).}
Applying this to
G
=
G
m
{\displaystyle G=\mathbf {G} _{m}}
gives the result on the Picard group.
= Tate's thesis
=There is a topology on
A
K
{\displaystyle \mathbf {A} _{K}}
for which the quotient
A
K
/
K
{\displaystyle \mathbf {A} _{K}/K}
is compact, allowing one to do harmonic analysis on it. John Tate in his thesis "Fourier analysis in number fields and Hecke Zeta functions" proved results about Dirichlet L-functions using Fourier analysis on the adele ring and the idele group. Therefore, the adele ring and the idele group have been applied to study the Riemann zeta function and more general zeta functions and the L-functions.
= Proving Serre duality on a smooth curve
=If
X
{\displaystyle X}
is a smooth proper curve over the complex numbers, one can define the adeles of its function field
C
(
X
)
{\displaystyle \mathbf {C} (X)}
exactly as the finite fields case. John Tate proved that Serre duality on
X
{\displaystyle X}
H
1
(
X
,
L
)
≃
H
0
(
X
,
Ω
X
⊗
L
−
1
)
∗
{\displaystyle H^{1}(X,{\mathcal {L}})\ \simeq \ H^{0}(X,\Omega _{X}\otimes {\mathcal {L}}^{-1})^{*}}
can be deduced by working with this adele ring
A
C
(
X
)
{\displaystyle \mathbf {A} _{\mathbf {C} (X)}}
. Here L is a line bundle on
X
{\displaystyle X}
.
Notation and basic definitions
= Global fields
=Throughout this article,
K
{\displaystyle K}
is a global field, meaning it is either a number field (a finite extension of
Q
{\displaystyle \mathbb {Q} }
) or a global function field (a finite extension of
F
p
r
(
t
)
{\displaystyle \mathbb {F} _{p^{r}}(t)}
for
p
{\displaystyle p}
prime and
r
∈
N
{\displaystyle r\in \mathbb {N} }
). By definition a finite extension of a global field is itself a global field.
= Valuations
=For a valuation
v
{\displaystyle v}
of
K
{\displaystyle K}
it can be written
K
v
{\displaystyle K_{v}}
for the completion of
K
{\displaystyle K}
with respect to
v
.
{\displaystyle v.}
If
v
{\displaystyle v}
is discrete it can be written
O
v
{\displaystyle O_{v}}
for the valuation ring of
K
v
{\displaystyle K_{v}}
and
m
v
{\displaystyle {\mathfrak {m}}_{v}}
for the maximal ideal of
O
v
.
{\displaystyle O_{v}.}
If this is a principal ideal denoting the uniformising element by
π
v
.
{\displaystyle \pi _{v}.}
A non-Archimedean valuation is written as
v
<
∞
{\displaystyle v<\infty }
or
v
∤
∞
{\displaystyle v\nmid \infty }
and an Archimedean valuation as
v
|
∞
.
{\displaystyle v|\infty .}
Then assume all valuations to be non-trivial.
There is a one-to-one identification of valuations and absolute values. Fix a constant
C
>
1
,
{\displaystyle C>1,}
the valuation
v
{\displaystyle v}
is assigned the absolute value
|
⋅
|
v
,
{\displaystyle |\cdot |_{v},}
defined as:
∀
x
∈
K
:
|
x
|
v
:=
{
C
−
v
(
x
)
x
≠
0
0
x
=
0
{\displaystyle \forall x\in K:\quad |x|_{v}:={\begin{cases}C^{-v(x)}&x\neq 0\\0&x=0\end{cases}}}
Conversely, the absolute value
|
⋅
|
{\displaystyle |\cdot |}
is assigned the valuation
v
|
⋅
|
,
{\displaystyle v_{|\cdot |},}
defined as:
∀
x
∈
K
×
:
v
|
⋅
|
(
x
)
:=
−
log
C
(
|
x
|
)
.
{\displaystyle \forall x\in K^{\times }:\quad v_{|\cdot |}(x):=-\log _{C}(|x|).}
A place of
K
{\displaystyle K}
is a representative of an equivalence class of valuations (or absolute values) of
K
.
{\displaystyle K.}
Places corresponding to non-Archimedean valuations are called finite, whereas places corresponding to Archimedean valuations are called infinite. Infinite places of a global field form a finite set, which is denoted by
P
∞
.
{\displaystyle P_{\infty }.}
Define
O
^
:=
∏
v
<
∞
O
v
{\displaystyle \textstyle {\widehat {O}}:=\prod _{v<\infty }O_{v}}
and let
O
^
×
{\displaystyle {\widehat {O}}^{\times }}
be its group of units. Then
O
^
×
=
∏
v
<
∞
O
v
×
.
{\displaystyle \textstyle {\widehat {O}}^{\times }=\prod _{v<\infty }O_{v}^{\times }.}
= Finite extensions
=Let
L
/
K
{\displaystyle L/K}
be a finite extension of the global field
K
.
{\displaystyle K.}
Let
w
{\displaystyle w}
be a place of
L
{\displaystyle L}
and
v
{\displaystyle v}
a place of
K
.
{\displaystyle K.}
If the absolute value
|
⋅
|
w
{\displaystyle |\cdot |_{w}}
restricted to
K
{\displaystyle K}
is in the equivalence class of
v
{\displaystyle v}
, then
w
{\displaystyle w}
lies above
v
,
{\displaystyle v,}
which is denoted by
w
|
v
,
{\displaystyle w|v,}
and defined as:
L
v
:=
∏
w
|
v
L
w
,
O
v
~
:=
∏
w
|
v
O
w
.
{\displaystyle {\begin{aligned}L_{v}&:=\prod _{w|v}L_{w},\\{\widetilde {O_{v}}}&:=\prod _{w|v}O_{w}.\end{aligned}}}
(Note that both products are finite.)
If
w
|
v
{\displaystyle w|v}
,
K
v
{\displaystyle K_{v}}
can be embedded in
L
w
.
{\displaystyle L_{w}.}
Therefore,
K
v
{\displaystyle K_{v}}
is embedded diagonally in
L
v
.
{\displaystyle L_{v}.}
With this embedding
L
v
{\displaystyle L_{v}}
is a commutative algebra over
K
v
{\displaystyle K_{v}}
with degree
∑
w
|
v
[
L
w
:
K
v
]
=
[
L
:
K
]
.
{\displaystyle \sum _{w|v}[L_{w}:K_{v}]=[L:K].}
The adele ring
The set of finite adeles of a global field
K
,
{\displaystyle K,}
denoted
A
K
,
fin
,
{\displaystyle \mathbb {A} _{K,{\text{fin}}},}
is defined as the restricted product of
K
v
{\displaystyle K_{v}}
with respect to the
O
v
:
{\displaystyle O_{v}:}
A
K
,
fin
:=
∏
v
<
∞
′
K
v
=
{
(
x
v
)
v
∈
∏
v
<
∞
K
v
|
x
v
∈
O
v
for almost all
v
}
.
{\displaystyle \mathbb {A} _{K,{\text{fin}}}:={\prod _{v<\infty }}^{'}K_{v}=\left\{\left.(x_{v})_{v}\in \prod _{v<\infty }K_{v}\right|x_{v}\in O_{v}{\text{ for almost all }}v\right\}.}
It is equipped with the restricted product topology, the topology generated by restricted open rectangles, which have the following form:
U
=
∏
v
∈
E
U
v
×
∏
v
∉
E
O
v
⊂
∏
v
<
∞
′
K
v
,
{\displaystyle U=\prod _{v\in E}U_{v}\times \prod _{v\notin E}O_{v}\subset {\prod _{v<\infty }}^{'}K_{v},}
where
E
{\displaystyle E}
is a finite set of (finite) places and
U
v
⊂
K
v
{\displaystyle U_{v}\subset K_{v}}
are open. With component-wise addition and multiplication
A
K
,
fin
{\displaystyle \mathbb {A} _{K,{\text{fin}}}}
is also a ring.
The adele ring of a global field
K
{\displaystyle K}
is defined as the product of
A
K
,
fin
{\displaystyle \mathbb {A} _{K,{\text{fin}}}}
with the product of the completions of
K
{\displaystyle K}
at its infinite places. The number of infinite places is finite and the completions are either
R
{\displaystyle \mathbb {R} }
or
C
.
{\displaystyle \mathbb {C} .}
In short:
A
K
:=
A
K
,
fin
×
∏
v
|
∞
K
v
=
∏
v
<
∞
′
K
v
×
∏
v
|
∞
K
v
.
{\displaystyle \mathbb {A} _{K}:=\mathbb {A} _{K,{\text{fin}}}\times \prod _{v|\infty }K_{v}={\prod _{v<\infty }}^{'}K_{v}\times \prod _{v|\infty }K_{v}.}
With addition and multiplication defined as component-wise the adele ring is a ring. The elements of the adele ring are called adeles of
K
.
{\displaystyle K.}
In the following, it is written as
A
K
=
∏
v
′
K
v
,
{\displaystyle \mathbb {A} _{K}={\prod _{v}}^{'}K_{v},}
although this is generally not a restricted product.
Remark. Global function fields do not have any infinite places and therefore the finite adele ring equals the adele ring.
Lemma. There is a natural embedding of
K
{\displaystyle K}
into
A
K
{\displaystyle \mathbb {A} _{K}}
given by the diagonal map:
a
↦
(
a
,
a
,
…
)
.
{\displaystyle a\mapsto (a,a,\ldots ).}
Proof. If
a
∈
K
,
{\displaystyle a\in K,}
then
a
∈
O
v
×
{\displaystyle a\in O_{v}^{\times }}
for almost all
v
.
{\displaystyle v.}
This shows the map is well-defined. It is also injective because the embedding of
K
{\displaystyle K}
in
K
v
{\displaystyle K_{v}}
is injective for all
v
.
{\displaystyle v.}
Remark. By identifying
K
{\displaystyle K}
with its image under the diagonal map it is regarded as a subring of
A
K
.
{\displaystyle \mathbb {A} _{K}.}
The elements of
K
{\displaystyle K}
are called the principal adeles of
A
K
.
{\displaystyle \mathbb {A} _{K}.}
Definition. Let
S
{\displaystyle S}
be a set of places of
K
.
{\displaystyle K.}
Define the set of the
S
{\displaystyle S}
-adeles of
K
{\displaystyle K}
as
A
K
,
S
:=
∏
v
∈
S
′
K
v
.
{\displaystyle \mathbb {A} _{K,S}:={\prod _{v\in S}}^{'}K_{v}.}
Furthermore, if
A
K
S
:=
∏
v
∉
S
′
K
v
{\displaystyle \mathbb {A} _{K}^{S}:={\prod _{v\notin S}}^{'}K_{v}}
the result is:
A
K
=
A
K
,
S
×
A
K
S
.
{\displaystyle \mathbb {A} _{K}=\mathbb {A} _{K,S}\times \mathbb {A} _{K}^{S}.}
= The adele ring of rationals
=By Ostrowski's theorem the places of
Q
{\displaystyle \mathbb {Q} }
are
{
p
∈
N
:
p
prime
}
∪
{
∞
}
,
{\displaystyle \{p\in \mathbb {N} :p{\text{ prime}}\}\cup \{\infty \},}
it is possible to identify a prime
p
{\displaystyle p}
with the equivalence class of the
p
{\displaystyle p}
-adic absolute value and
∞
{\displaystyle \infty }
with the equivalence class of the absolute value
|
⋅
|
∞
{\displaystyle |\cdot |_{\infty }}
defined as:
∀
x
∈
Q
:
|
x
|
∞
:=
{
x
x
≥
0
−
x
x
<
0
{\displaystyle \forall x\in \mathbb {Q} :\quad |x|_{\infty }:={\begin{cases}x&x\geq 0\\-x&x<0\end{cases}}}
The completion of
Q
{\displaystyle \mathbb {Q} }
with respect to the place
p
{\displaystyle p}
is
Q
p
{\displaystyle \mathbb {Q} _{p}}
with valuation ring
Z
p
.
{\displaystyle \mathbb {Z} _{p}.}
For the place
∞
{\displaystyle \infty }
the completion is
R
.
{\displaystyle \mathbb {R} .}
Thus:
A
Q
,
fin
=
∏
p
<
∞
′
Q
p
A
Q
=
(
∏
p
<
∞
′
Q
p
)
×
R
{\displaystyle {\begin{aligned}\mathbb {A} _{\mathbb {Q} ,{\text{fin}}}&={\prod _{p<\infty }}^{'}\mathbb {Q} _{p}\\\mathbb {A} _{\mathbb {Q} }&=\left({\prod _{p<\infty }}^{'}\mathbb {Q} _{p}\right)\times \mathbb {R} \end{aligned}}}
Or for short
A
Q
=
∏
p
≤
∞
′
Q
p
,
Q
∞
:=
R
.
{\displaystyle \mathbb {A} _{\mathbb {Q} }={\prod _{p\leq \infty }}^{'}\mathbb {Q} _{p},\qquad \mathbb {Q} _{\infty }:=\mathbb {R} .}
the difference between restricted and unrestricted product topology can be illustrated using a sequence in
A
Q
{\displaystyle \mathbb {A} _{\mathbb {Q} }}
:
Lemma. Consider the following sequence in
A
Q
{\displaystyle \mathbb {A} _{\mathbb {Q} }}
:
x
1
=
(
1
2
,
1
,
1
,
…
)
x
2
=
(
1
,
1
3
,
1
,
…
)
x
3
=
(
1
,
1
,
1
5
,
1
,
…
)
x
4
=
(
1
,
1
,
1
,
1
7
,
1
,
…
)
⋮
{\displaystyle {\begin{aligned}x_{1}&=\left({\frac {1}{2}},1,1,\ldots \right)\\x_{2}&=\left(1,{\frac {1}{3}},1,\ldots \right)\\x_{3}&=\left(1,1,{\frac {1}{5}},1,\ldots \right)\\x_{4}&=\left(1,1,1,{\frac {1}{7}},1,\ldots \right)\\&\vdots \end{aligned}}}
In the product topology this converges to
(
1
,
1
,
…
)
{\displaystyle (1,1,\ldots )}
, but it does not converge at all in the restricted product topology.
Proof. In product topology convergence corresponds to the convergence in each coordinate, which is trivial because the sequences become stationary. The sequence doesn't converge in restricted product topology. For each adele
a
=
(
a
p
)
p
∈
A
Q
{\displaystyle a=(a_{p})_{p}\in \mathbb {A} _{\mathbb {Q} }}
and for each restricted open rectangle
U
=
∏
p
∈
E
U
p
×
∏
p
∉
E
Z
p
,
{\displaystyle \textstyle U=\prod _{p\in E}U_{p}\times \prod _{p\notin E}\mathbb {Z} _{p},}
it has:
1
p
−
a
p
∉
Z
p
{\displaystyle {\tfrac {1}{p}}-a_{p}\notin \mathbb {Z} _{p}}
for
a
p
∈
Z
p
{\displaystyle a_{p}\in \mathbb {Z} _{p}}
and therefore
1
p
−
a
p
∉
Z
p
{\displaystyle {\tfrac {1}{p}}-a_{p}\notin \mathbb {Z} _{p}}
for all
p
∉
F
.
{\displaystyle p\notin F.}
As a result
x
n
−
a
∉
U
{\displaystyle x_{n}-a\notin U}
for almost all
n
∈
N
.
{\displaystyle n\in \mathbb {N} .}
In this consideration,
E
{\displaystyle E}
and
F
{\displaystyle F}
are finite subsets of the set of all places.
= Alternative definition for number fields
=Definition (profinite integers). The profinite integers are defined as the profinite completion of the rings
Z
/
n
Z
{\displaystyle \mathbb {Z} /n\mathbb {Z} }
with the partial order
n
≥
m
⇔
m
|
n
,
{\displaystyle n\geq m\Leftrightarrow m|n,}
i.e.,
Z
^
:=
lim
←
n
Z
/
n
Z
,
{\displaystyle {\widehat {\mathbb {Z} }}:=\varprojlim _{n}\mathbb {Z} /n\mathbb {Z} ,}
Lemma.
Z
^
≅
∏
p
Z
p
.
{\displaystyle \textstyle {\widehat {\mathbb {Z} }}\cong \prod _{p}\mathbb {Z} _{p}.}
Proof. This follows from the Chinese Remainder Theorem.
Lemma.
A
Q
,
fin
=
Z
^
⊗
Z
Q
.
{\displaystyle \mathbb {A} _{\mathbb {Q} ,{\text{fin}}}={\widehat {\mathbb {Z} }}\otimes _{\mathbb {Z} }\mathbb {Q} .}
Proof. Use the universal property of the tensor product. Define a
Z
{\displaystyle \mathbb {Z} }
-bilinear function
{
Ψ
:
Z
^
×
Q
→
A
Q
,
fin
(
(
a
p
)
p
,
q
)
↦
(
a
p
q
)
p
{\displaystyle {\begin{cases}\Psi :{\widehat {\mathbb {Z} }}\times \mathbb {Q} \to \mathbb {A} _{\mathbb {Q} ,{\text{fin}}}\\\left((a_{p})_{p},q\right)\mapsto (a_{p}q)_{p}\end{cases}}}
This is well-defined because for a given
q
=
m
n
∈
Q
{\displaystyle q={\tfrac {m}{n}}\in \mathbb {Q} }
with
m
,
n
{\displaystyle m,n}
co-prime there are only finitely many primes dividing
n
.
{\displaystyle n.}
Let
M
{\displaystyle M}
be another
Z
{\displaystyle \mathbb {Z} }
-module with a
Z
{\displaystyle \mathbb {Z} }
-bilinear map
Φ
:
Z
^
×
Q
→
M
.
{\displaystyle \Phi :{\widehat {\mathbb {Z} }}\times \mathbb {Q} \to M.}
It must be the case that
Φ
{\displaystyle \Phi }
factors through
Ψ
{\displaystyle \Psi }
uniquely, i.e., there exists a unique
Z
{\displaystyle \mathbb {Z} }
-linear map
Φ
~
:
A
Q
,
fin
→
M
{\displaystyle {\tilde {\Phi }}:\mathbb {A} _{\mathbb {Q} ,{\text{fin}}}\to M}
such that
Φ
=
Φ
~
∘
Ψ
.
{\displaystyle \Phi ={\tilde {\Phi }}\circ \Psi .}
Φ
~
{\displaystyle {\tilde {\Phi }}}
can be defined as follows: for a given
(
u
p
)
p
{\displaystyle (u_{p})_{p}}
there exist
u
∈
N
{\displaystyle u\in \mathbb {N} }
and
(
v
p
)
p
∈
Z
^
{\displaystyle (v_{p})_{p}\in {\widehat {\mathbb {Z} }}}
such that
u
p
=
1
u
⋅
v
p
{\displaystyle u_{p}={\tfrac {1}{u}}\cdot v_{p}}
for all
p
.
{\displaystyle p.}
Define
Φ
~
(
(
u
p
)
p
)
:=
Φ
(
(
v
p
)
p
,
1
u
)
.
{\displaystyle {\tilde {\Phi }}((u_{p})_{p}):=\Phi ((v_{p})_{p},{\tfrac {1}{u}}).}
One can show
Φ
~
{\displaystyle {\tilde {\Phi }}}
is well-defined,
Z
{\displaystyle \mathbb {Z} }
-linear, satisfies
Φ
=
Φ
~
∘
Ψ
{\displaystyle \Phi ={\tilde {\Phi }}\circ \Psi }
and is unique with these properties.
Corollary. Define
A
Z
:=
Z
^
×
R
.
{\displaystyle \mathbb {A} _{\mathbb {Z} }:={\widehat {\mathbb {Z} }}\times \mathbb {R} .}
This results in an algebraic isomorphism
A
Q
≅
A
Z
⊗
Z
Q
.
{\displaystyle \mathbb {A} _{\mathbb {Q} }\cong \mathbb {A} _{\mathbb {Z} }\otimes _{\mathbb {Z} }\mathbb {Q} .}
Proof.
A
Z
⊗
Z
Q
=
(
Z
^
×
R
)
⊗
Z
Q
≅
(
Z
^
⊗
Z
Q
)
×
(
R
⊗
Z
Q
)
≅
(
Z
^
⊗
Z
Q
)
×
R
=
A
Q
,
fin
×
R
=
A
Q
.
{\displaystyle \mathbb {A} _{\mathbb {Z} }\otimes _{\mathbb {Z} }\mathbb {Q} =\left({\widehat {\mathbb {Z} }}\times \mathbb {R} \right)\otimes _{\mathbb {Z} }\mathbb {Q} \cong \left({\widehat {\mathbb {Z} }}\otimes _{\mathbb {Z} }\mathbb {Q} \right)\times (\mathbb {R} \otimes _{\mathbb {Z} }\mathbb {Q} )\cong \left({\widehat {\mathbb {Z} }}\otimes _{\mathbb {Z} }\mathbb {Q} \right)\times \mathbb {R} =\mathbb {A} _{\mathbb {Q} ,{\text{fin}}}\times \mathbb {R} =\mathbb {A} _{\mathbb {Q} }.}
Lemma. For a number field
K
,
A
K
=
A
Q
⊗
Q
K
.
{\displaystyle K,\mathbb {A} _{K}=\mathbb {A} _{\mathbb {Q} }\otimes _{\mathbb {Q} }K.}
Remark. Using
A
Q
⊗
Q
K
≅
A
Q
⊕
⋯
⊕
A
Q
,
{\displaystyle \mathbb {A} _{\mathbb {Q} }\otimes _{\mathbb {Q} }K\cong \mathbb {A} _{\mathbb {Q} }\oplus \dots \oplus \mathbb {A} _{\mathbb {Q} },}
where there are
[
K
:
Q
]
{\displaystyle [K:\mathbb {Q} ]}
summands, give the right side receives the product topology and transport this topology via the isomorphism onto
A
Q
⊗
Q
K
.
{\displaystyle \mathbb {A} _{\mathbb {Q} }\otimes _{\mathbb {Q} }K.}
= The adele ring of a finite extension
=If
L
/
K
{\displaystyle L/K}
be a finite extension, then
L
{\displaystyle L}
is a global field. Thus
A
L
{\displaystyle \mathbb {A} _{L}}
is defined, and
A
L
=
∏
v
′
L
v
.
{\displaystyle \textstyle \mathbb {A} _{L}={\prod _{v}}^{'}L_{v}.}
A
K
{\displaystyle \mathbb {A} _{K}}
can be identified with a subgroup of
A
L
.
{\displaystyle \mathbb {A} _{L}.}
Map
a
=
(
a
v
)
v
∈
A
K
{\displaystyle a=(a_{v})_{v}\in \mathbb {A} _{K}}
to
a
′
=
(
a
w
′
)
w
∈
A
L
{\displaystyle a'=(a'_{w})_{w}\in \mathbb {A} _{L}}
where
a
w
′
=
a
v
∈
K
v
⊂
L
w
{\displaystyle a'_{w}=a_{v}\in K_{v}\subset L_{w}}
for
w
|
v
.
{\displaystyle w|v.}
Then
a
=
(
a
w
)
w
∈
A
L
{\displaystyle a=(a_{w})_{w}\in \mathbb {A} _{L}}
is in the subgroup
A
K
,
{\displaystyle \mathbb {A} _{K},}
if
a
w
∈
K
v
{\displaystyle a_{w}\in K_{v}}
for
w
|
v
{\displaystyle w|v}
and
a
w
=
a
w
′
{\displaystyle a_{w}=a_{w'}}
for all
w
,
w
′
{\displaystyle w,w'}
lying above the same place
v
{\displaystyle v}
of
K
.
{\displaystyle K.}
Lemma. If
L
/
K
{\displaystyle L/K}
is a finite extension, then
A
L
≅
A
K
⊗
K
L
{\displaystyle \mathbb {A} _{L}\cong \mathbb {A} _{K}\otimes _{K}L}
both algebraically and topologically.
With the help of this isomorphism, the inclusion
A
K
⊂
A
L
{\displaystyle \mathbb {A} _{K}\subset \mathbb {A} _{L}}
is given by
{
A
K
→
A
L
α
↦
α
⊗
K
1
{\displaystyle {\begin{cases}\mathbb {A} _{K}\to \mathbb {A} _{L}\\\alpha \mapsto \alpha \otimes _{K}1\end{cases}}}
Furthermore, the principal adeles in
A
K
{\displaystyle \mathbb {A} _{K}}
can be identified with a subgroup of principal adeles in
A
L
{\displaystyle \mathbb {A} _{L}}
via the map
{
K
→
(
K
⊗
K
L
)
≅
L
α
↦
1
⊗
K
α
{\displaystyle {\begin{cases}K\to (K\otimes _{K}L)\cong L\\\alpha \mapsto 1\otimes _{K}\alpha \end{cases}}}
Proof. Let
ω
1
,
…
,
ω
n
{\displaystyle \omega _{1},\ldots ,\omega _{n}}
be a basis of
L
{\displaystyle L}
over
K
.
{\displaystyle K.}
Then for almost all
v
,
{\displaystyle v,}
O
v
~
≅
O
v
ω
1
⊕
⋯
⊕
O
v
ω
n
.
{\displaystyle {\widetilde {O_{v}}}\cong O_{v}\omega _{1}\oplus \cdots \oplus O_{v}\omega _{n}.}
Furthermore, there are the following isomorphisms:
K
v
ω
1
⊕
⋯
⊕
K
v
ω
n
≅
K
v
⊗
K
L
≅
L
v
=
∏
w
|
v
L
w
{\displaystyle K_{v}\omega _{1}\oplus \cdots \oplus K_{v}\omega _{n}\cong K_{v}\otimes _{K}L\cong L_{v}=\prod \nolimits _{w|v}L_{w}}
For the second use the map:
{
K
v
⊗
K
L
→
L
v
α
v
⊗
a
↦
(
α
v
⋅
(
τ
w
(
a
)
)
)
w
{\displaystyle {\begin{cases}K_{v}\otimes _{K}L\to L_{v}\\\alpha _{v}\otimes a\mapsto (\alpha _{v}\cdot (\tau _{w}(a)))_{w}\end{cases}}}
in which
τ
w
:
L
→
L
w
{\displaystyle \tau _{w}:L\to L_{w}}
is the canonical embedding and
w
|
v
.
{\displaystyle w|v.}
The restricted product is taken on both sides with respect to
O
v
~
:
{\displaystyle {\widetilde {O_{v}}}:}
A
K
⊗
K
L
=
(
∏
v
′
K
v
)
⊗
K
L
≅
∏
v
′
(
K
v
ω
1
⊕
⋯
⊕
K
v
ω
n
)
≅
∏
v
′
(
K
v
⊗
K
L
)
≅
∏
v
′
L
v
=
A
L
{\displaystyle {\begin{aligned}\mathbb {A} _{K}\otimes _{K}L&=\left({\prod _{v}}^{'}K_{v}\right)\otimes _{K}L\\&\cong {\prod _{v}}^{'}(K_{v}\omega _{1}\oplus \cdots \oplus K_{v}\omega _{n})\\&\cong {\prod _{v}}^{'}(K_{v}\otimes _{K}L)\\&\cong {\prod _{v}}^{'}L_{v}\\&=\mathbb {A} _{L}\end{aligned}}}
Corollary. As additive groups
A
L
≅
A
K
⊕
⋯
⊕
A
K
,
{\displaystyle \mathbb {A} _{L}\cong \mathbb {A} _{K}\oplus \cdots \oplus \mathbb {A} _{K},}
where the right side has
[
L
:
K
]
{\displaystyle [L:K]}
summands.
The set of principal adeles in
A
L
{\displaystyle \mathbb {A} _{L}}
is identified with the set
K
⊕
⋯
⊕
K
,
{\displaystyle K\oplus \cdots \oplus K,}
where the left side has
[
L
:
K
]
{\displaystyle [L:K]}
summands and
K
{\displaystyle K}
is considered as a subset of
A
K
.
{\displaystyle \mathbb {A} _{K}.}
= The adele ring of vector-spaces and algebras
=Lemma. Suppose
P
⊃
P
∞
{\displaystyle P\supset P_{\infty }}
is a finite set of places of
K
{\displaystyle K}
and define
A
K
(
P
)
:=
∏
v
∈
P
K
v
×
∏
v
∉
P
O
v
.
{\displaystyle \mathbb {A} _{K}(P):=\prod _{v\in P}K_{v}\times \prod _{v\notin P}O_{v}.}
Equip
A
K
(
P
)
{\displaystyle \mathbb {A} _{K}(P)}
with the product topology and define addition and multiplication component-wise. Then
A
K
(
P
)
{\displaystyle \mathbb {A} _{K}(P)}
is a locally compact topological ring.
Remark. If
P
′
{\displaystyle P'}
is another finite set of places of
K
{\displaystyle K}
containing
P
{\displaystyle P}
then
A
K
(
P
)
{\displaystyle \mathbb {A} _{K}(P)}
is an open subring of
A
K
(
P
′
)
.
{\displaystyle \mathbb {A} _{K}(P').}
Now, an alternative characterisation of the adele ring can be presented. The adele ring is the union of all sets
A
K
(
P
)
{\displaystyle \mathbb {A} _{K}(P)}
:
A
K
=
⋃
P
⊃
P
∞
,
|
P
|
<
∞
A
K
(
P
)
.
{\displaystyle \mathbb {A} _{K}=\bigcup _{P\supset P_{\infty },|P|<\infty }\mathbb {A} _{K}(P).}
Equivalently
A
K
{\displaystyle \mathbb {A} _{K}}
is the set of all
x
=
(
x
v
)
v
{\displaystyle x=(x_{v})_{v}}
so that
|
x
v
|
v
≤
1
{\displaystyle |x_{v}|_{v}\leq 1}
for almost all
v
<
∞
.
{\displaystyle v<\infty .}
The topology of
A
K
{\displaystyle \mathbb {A} _{K}}
is induced by the requirement that all
A
K
(
P
)
{\displaystyle \mathbb {A} _{K}(P)}
be open subrings of
A
K
.
{\displaystyle \mathbb {A} _{K}.}
Thus,
A
K
{\displaystyle \mathbb {A} _{K}}
is a locally compact topological ring.
Fix a place
v
{\displaystyle v}
of
K
.
{\displaystyle K.}
Let
P
{\displaystyle P}
be a finite set of places of
K
,
{\displaystyle K,}
containing
v
{\displaystyle v}
and
P
∞
.
{\displaystyle P_{\infty }.}
Define
A
K
′
(
P
,
v
)
:=
∏
w
∈
P
∖
{
v
}
K
w
×
∏
w
∉
P
O
w
.
{\displaystyle \mathbb {A} _{K}'(P,v):=\prod _{w\in P\setminus \{v\}}K_{w}\times \prod _{w\notin P}O_{w}.}
Then:
A
K
(
P
)
≅
K
v
×
A
K
′
(
P
,
v
)
.
{\displaystyle \mathbb {A} _{K}(P)\cong K_{v}\times \mathbb {A} _{K}'(P,v).}
Furthermore, define
A
K
′
(
v
)
:=
⋃
P
⊃
P
∞
∪
{
v
}
A
K
′
(
P
,
v
)
,
{\displaystyle \mathbb {A} _{K}'(v):=\bigcup _{P\supset P_{\infty }\cup \{v\}}\mathbb {A} _{K}'(P,v),}
where
P
{\displaystyle P}
runs through all finite sets containing
P
∞
∪
{
v
}
.
{\displaystyle P_{\infty }\cup \{v\}.}
Then:
A
K
≅
K
v
×
A
K
′
(
v
)
,
{\displaystyle \mathbb {A} _{K}\cong K_{v}\times \mathbb {A} _{K}'(v),}
via the map
(
a
w
)
w
↦
(
a
v
,
(
a
w
)
w
≠
v
)
.
{\displaystyle (a_{w})_{w}\mapsto (a_{v},(a_{w})_{w\neq v}).}
The entire procedure above holds with a finite subset
P
~
{\displaystyle {\widetilde {P}}}
instead of
{
v
}
.
{\displaystyle \{v\}.}
By construction of
A
K
′
(
v
)
,
{\displaystyle \mathbb {A} _{K}'(v),}
there is a natural embedding:
K
v
↪
A
K
.
{\displaystyle K_{v}\hookrightarrow \mathbb {A} _{K}.}
Furthermore, there exists a natural projection
A
K
↠
K
v
.
{\displaystyle \mathbb {A} _{K}\twoheadrightarrow K_{v}.}
The adele ring of a vector-space
Let
E
{\displaystyle E}
be a finite dimensional vector-space over
K
{\displaystyle K}
and
{
ω
1
,
…
,
ω
n
}
{\displaystyle \{\omega _{1},\ldots ,\omega _{n}\}}
a basis for
E
{\displaystyle E}
over
K
.
{\displaystyle K.}
For each place
v
{\displaystyle v}
of
K
{\displaystyle K}
:
E
v
:=
E
⊗
K
K
v
≅
K
v
ω
1
⊕
⋯
⊕
K
v
ω
n
O
v
~
:=
O
v
ω
1
⊕
⋯
⊕
O
v
ω
n
{\displaystyle {\begin{aligned}E_{v}&:=E\otimes _{K}K_{v}\cong K_{v}\omega _{1}\oplus \cdots \oplus K_{v}\omega _{n}\\{\widetilde {O_{v}}}&:=O_{v}\omega _{1}\oplus \cdots \oplus O_{v}\omega _{n}\end{aligned}}}
The adele ring of
E
{\displaystyle E}
is defined as
A
E
:=
∏
v
′
E
v
.
{\displaystyle \mathbb {A} _{E}:={\prod _{v}}^{'}E_{v}.}
This definition is based on the alternative description of the adele ring as a tensor product equipped with the same topology that was defined when giving an alternate definition of adele ring for number fields. Next,
A
E
{\displaystyle \mathbb {A} _{E}}
is equipped with the restricted product topology. Then
A
E
=
E
⊗
K
A
K
{\displaystyle \mathbb {A} _{E}=E\otimes _{K}\mathbb {A} _{K}}
and
E
{\displaystyle E}
is embedded in
A
E
{\displaystyle \mathbb {A} _{E}}
naturally via the map
e
↦
e
⊗
1.
{\displaystyle e\mapsto e\otimes 1.}
An alternative definition of the topology on
A
E
{\displaystyle \mathbb {A} _{E}}
can be provided. Consider all linear maps:
E
→
K
.
{\displaystyle E\to K.}
Using the natural embeddings
E
→
A
E
{\displaystyle E\to \mathbb {A} _{E}}
and
K
→
A
K
,
{\displaystyle K\to \mathbb {A} _{K},}
extend these linear maps to:
A
E
→
A
K
.
{\displaystyle \mathbb {A} _{E}\to \mathbb {A} _{K}.}
The topology on
A
E
{\displaystyle \mathbb {A} _{E}}
is the coarsest topology for which all these extensions are continuous.
The topology can be defined in a different way. Fixing a basis for
E
{\displaystyle E}
over
K
{\displaystyle K}
results in an isomorphism
E
≅
K
n
.
{\displaystyle E\cong K^{n}.}
Therefore fixing a basis induces an isomorphism
(
A
K
)
n
≅
A
E
.
{\displaystyle (\mathbb {A} _{K})^{n}\cong \mathbb {A} _{E}.}
The left-hand side is supplied with the product topology and transport this topology with the isomorphism onto the right-hand side. The topology doesn't depend on the choice of the basis, because another basis defines a second isomorphism. By composing both isomorphisms, a linear homeomorphism which transfers the two topologies into each other is obtained. More formally
A
E
=
E
⊗
K
A
K
≅
(
K
⊗
K
A
K
)
⊕
⋯
⊕
(
K
⊗
K
A
K
)
≅
A
K
⊕
⋯
⊕
A
K
{\displaystyle {\begin{aligned}\mathbb {A} _{E}&=E\otimes _{K}\mathbb {A} _{K}\\&\cong (K\otimes _{K}\mathbb {A} _{K})\oplus \cdots \oplus (K\otimes _{K}\mathbb {A} _{K})\\&\cong \mathbb {A} _{K}\oplus \cdots \oplus \mathbb {A} _{K}\end{aligned}}}
where the sums have
n
{\displaystyle n}
summands. In case of
E
=
L
,
{\displaystyle E=L,}
the definition above is consistent with the results about the adele ring of a finite extension
L
/
K
.
{\displaystyle L/K.}
The adele ring of an algebra
Let
A
{\displaystyle A}
be a finite-dimensional algebra over
K
.
{\displaystyle K.}
In particular,
A
{\displaystyle A}
is a finite-dimensional vector-space over
K
.
{\displaystyle K.}
As a consequence,
A
A
{\displaystyle \mathbb {A} _{A}}
is defined and
A
A
≅
A
K
⊗
K
A
.
{\displaystyle \mathbb {A} _{A}\cong \mathbb {A} _{K}\otimes _{K}A.}
Since there is multiplication on
A
K
{\displaystyle \mathbb {A} _{K}}
and
A
,
{\displaystyle A,}
a multiplication on
A
A
{\displaystyle \mathbb {A} _{A}}
can be defined via:
∀
α
,
β
∈
A
K
and
∀
a
,
b
∈
A
:
(
α
⊗
K
a
)
⋅
(
β
⊗
K
b
)
:=
(
α
β
)
⊗
K
(
a
b
)
.
{\displaystyle \forall \alpha ,\beta \in \mathbb {A} _{K}{\text{ and }}\forall a,b\in A:\qquad (\alpha \otimes _{K}a)\cdot (\beta \otimes _{K}b):=(\alpha \beta )\otimes _{K}(ab).}
As a consequence,
A
A
{\displaystyle \mathbb {A} _{A}}
is an algebra with a unit over
A
K
.
{\displaystyle \mathbb {A} _{K}.}
Let
B
{\displaystyle {\mathcal {B}}}
be a finite subset of
A
,
{\displaystyle A,}
containing a basis for
A
{\displaystyle A}
over
K
.
{\displaystyle K.}
For any finite place
v
{\displaystyle v}
,
M
v
{\displaystyle M_{v}}
is defined as the
O
v
{\displaystyle O_{v}}
-module generated by
B
{\displaystyle {\mathcal {B}}}
in
A
v
.
{\displaystyle A_{v}.}
For each finite set of places,
P
⊃
P
∞
,
{\displaystyle P\supset P_{\infty },}
define
A
A
(
P
,
α
)
=
∏
v
∈
P
A
v
×
∏
v
∉
P
M
v
.
{\displaystyle \mathbb {A} _{A}(P,\alpha )=\prod _{v\in P}A_{v}\times \prod _{v\notin P}M_{v}.}
One can show there is a finite set
P
0
,
{\displaystyle P_{0},}
so that
A
A
(
P
,
α
)
{\displaystyle \mathbb {A} _{A}(P,\alpha )}
is an open subring of
A
A
,
{\displaystyle \mathbb {A} _{A},}
if
P
⊃
P
0
.
{\displaystyle P\supset P_{0}.}
Furthermore
A
A
{\displaystyle \mathbb {A} _{A}}
is the union of all these subrings and for
A
=
K
,
{\displaystyle A=K,}
the definition above is consistent with the definition of the adele ring.
= Trace and norm on the adele ring
=Let
L
/
K
{\displaystyle L/K}
be a finite extension. Since
A
K
=
A
K
⊗
K
K
{\displaystyle \mathbb {A} _{K}=\mathbb {A} _{K}\otimes _{K}K}
and
A
L
=
A
K
⊗
K
L
{\displaystyle \mathbb {A} _{L}=\mathbb {A} _{K}\otimes _{K}L}
from the Lemma above,
A
K
{\displaystyle \mathbb {A} _{K}}
can be interpreted as a closed subring of
A
L
.
{\displaystyle \mathbb {A} _{L}.}
For this embedding, write
con
L
/
K
{\displaystyle \operatorname {con} _{L/K}}
. Explicitly for all places
w
{\displaystyle w}
of
L
{\displaystyle L}
above
v
{\displaystyle v}
and for any
α
∈
A
K
,
(
con
L
/
K
(
α
)
)
w
=
α
v
∈
K
v
.
{\displaystyle \alpha \in \mathbb {A} _{K},(\operatorname {con} _{L/K}(\alpha ))_{w}=\alpha _{v}\in K_{v}.}
Let
M
/
L
/
K
{\displaystyle M/L/K}
be a tower of global fields. Then:
con
M
/
K
(
α
)
=
con
M
/
L
(
con
L
/
K
(
α
)
)
∀
α
∈
A
K
.
{\displaystyle \operatorname {con} _{M/K}(\alpha )=\operatorname {con} _{M/L}(\operatorname {con} _{L/K}(\alpha ))\qquad \forall \alpha \in \mathbb {A} _{K}.}
Furthermore, restricted to the principal adeles
con
{\displaystyle \operatorname {con} }
is the natural injection
K
→
L
.
{\displaystyle K\to L.}
Let
{
ω
1
,
…
,
ω
n
}
{\displaystyle \{\omega _{1},\ldots ,\omega _{n}\}}
be a basis of the field extension
L
/
K
.
{\displaystyle L/K.}
Then each
α
∈
A
L
{\displaystyle \alpha \in \mathbb {A} _{L}}
can be written as
∑
j
=
1
n
α
j
ω
j
,
{\displaystyle \textstyle \sum _{j=1}^{n}\alpha _{j}\omega _{j},}
where
α
j
∈
A
K
{\displaystyle \alpha _{j}\in \mathbb {A} _{K}}
are unique. The map
α
↦
α
j
{\displaystyle \alpha \mapsto \alpha _{j}}
is continuous. Define
α
i
j
{\displaystyle \alpha _{ij}}
depending on
α
{\displaystyle \alpha }
via the equations:
α
ω
1
=
∑
j
=
1
n
α
1
j
ω
j
⋮
α
ω
n
=
∑
j
=
1
n
α
n
j
ω
j
{\displaystyle {\begin{aligned}\alpha \omega _{1}&=\sum _{j=1}^{n}\alpha _{1j}\omega _{j}\\&\vdots \\\alpha \omega _{n}&=\sum _{j=1}^{n}\alpha _{nj}\omega _{j}\end{aligned}}}
Now, define the trace and norm of
α
{\displaystyle \alpha }
as:
Tr
L
/
K
(
α
)
:=
Tr
(
(
α
i
j
)
i
,
j
)
=
∑
i
=
1
n
α
i
i
N
L
/
K
(
α
)
:=
N
(
(
α
i
j
)
i
,
j
)
=
det
(
(
α
i
j
)
i
,
j
)
{\displaystyle {\begin{aligned}\operatorname {Tr} _{L/K}(\alpha )&:=\operatorname {Tr} ((\alpha _{ij})_{i,j})=\sum _{i=1}^{n}\alpha _{ii}\\N_{L/K}(\alpha )&:=N((\alpha _{ij})_{i,j})=\det((\alpha _{ij})_{i,j})\end{aligned}}}
These are the trace and the determinant of the linear map
{
A
L
→
A
L
x
↦
α
x
{\displaystyle {\begin{cases}\mathbb {A} _{L}\to \mathbb {A} _{L}\\x\mapsto \alpha x\end{cases}}}
They are continuous maps on the adele ring, and they fulfil the usual equations:
Tr
L
/
K
(
α
+
β
)
=
Tr
L
/
K
(
α
)
+
Tr
L
/
K
(
β
)
∀
α
,
β
∈
A
L
Tr
L
/
K
(
con
(
α
)
)
=
n
α
∀
α
∈
A
K
N
L
/
K
(
α
β
)
=
N
L
/
K
(
α
)
N
L
/
K
(
β
)
∀
α
,
β
∈
A
L
N
L
/
K
(
con
(
α
)
)
=
α
n
∀
α
∈
A
K
{\displaystyle {\begin{aligned}\operatorname {Tr} _{L/K}(\alpha +\beta )&=\operatorname {Tr} _{L/K}(\alpha )+\operatorname {Tr} _{L/K}(\beta )&&\forall \alpha ,\beta \in \mathbb {A} _{L}\\\operatorname {Tr} _{L/K}(\operatorname {con} (\alpha ))&=n\alpha &&\forall \alpha \in \mathbb {A} _{K}\\N_{L/K}(\alpha \beta )&=N_{L/K}(\alpha )N_{L/K}(\beta )&&\forall \alpha ,\beta \in \mathbb {A} _{L}\\N_{L/K}(\operatorname {con} (\alpha ))&=\alpha ^{n}&&\forall \alpha \in \mathbb {A} _{K}\end{aligned}}}
Furthermore, for
α
∈
L
,
{\displaystyle \alpha \in L,}
Tr
L
/
K
(
α
)
{\displaystyle \operatorname {Tr} _{L/K}(\alpha )}
and
N
L
/
K
(
α
)
{\displaystyle N_{L/K}(\alpha )}
are identical to the trace and norm of the field extension
L
/
K
.
{\displaystyle L/K.}
For a tower of fields
M
/
L
/
K
,
{\displaystyle M/L/K,}
the result is:
Tr
L
/
K
(
Tr
M
/
L
(
α
)
)
=
Tr
M
/
K
(
α
)
∀
α
∈
A
M
N
L
/
K
(
N
M
/
L
(
α
)
)
=
N
M
/
K
(
α
)
∀
α
∈
A
M
{\displaystyle {\begin{aligned}\operatorname {Tr} _{L/K}(\operatorname {Tr} _{M/L}(\alpha ))&=\operatorname {Tr} _{M/K}(\alpha )&&\forall \alpha \in \mathbb {A} _{M}\\N_{L/K}(N_{M/L}(\alpha ))&=N_{M/K}(\alpha )&&\forall \alpha \in \mathbb {A} _{M}\end{aligned}}}
Moreover, it can be proven that:
Tr
L
/
K
(
α
)
=
(
∑
w
|
v
Tr
L
w
/
K
v
(
α
w
)
)
v
∀
α
∈
A
L
N
L
/
K
(
α
)
=
(
∏
w
|
v
N
L
w
/
K
v
(
α
w
)
)
v
∀
α
∈
A
L
{\displaystyle {\begin{aligned}\operatorname {Tr} _{L/K}(\alpha )&=\left(\sum _{w|v}\operatorname {Tr} _{L_{w}/K_{v}}(\alpha _{w})\right)_{v}&&\forall \alpha \in \mathbb {A} _{L}\\N_{L/K}(\alpha )&=\left(\prod _{w|v}N_{L_{w}/K_{v}}(\alpha _{w})\right)_{v}&&\forall \alpha \in \mathbb {A} _{L}\end{aligned}}}
= Properties of the adele ring
=Theorem. For every set of places
S
,
A
K
,
S
{\displaystyle S,\mathbb {A} _{K,S}}
is a locally compact topological ring.
Remark. The result above also holds for the adele ring of vector-spaces and algebras over
K
.
{\displaystyle K.}
Theorem.
K
{\displaystyle K}
is discrete and cocompact in
A
K
.
{\displaystyle \mathbb {A} _{K}.}
In particular,
K
{\displaystyle K}
is closed in
A
K
.
{\displaystyle \mathbb {A} _{K}.}
Proof. Prove the case
K
=
Q
.
{\displaystyle K=\mathbb {Q} .}
To show
Q
⊂
A
Q
{\displaystyle \mathbb {Q} \subset \mathbb {A} _{\mathbb {Q} }}
is discrete it is sufficient to show the existence of a neighbourhood of
0
{\displaystyle 0}
which contains no other rational number. The general case follows via translation. Define
U
:=
{
(
α
p
)
p
|
∀
p
<
∞
:
|
α
p
|
p
≤
1
and
|
α
∞
|
∞
<
1
}
=
Z
^
×
(
−
1
,
1
)
.
{\displaystyle U:=\left\{(\alpha _{p})_{p}\left|\forall p<\infty :|\alpha _{p}|_{p}\leq 1\quad {\text{and}}\quad |\alpha _{\infty }|_{\infty }<1\right.\right\}={\widehat {\mathbb {Z} }}\times (-1,1).}
U
{\displaystyle U}
is an open neighbourhood of
0
∈
A
Q
.
{\displaystyle 0\in \mathbb {A} _{\mathbb {Q} }.}
It is claimed that
U
∩
Q
=
{
0
}
.
{\displaystyle U\cap \mathbb {Q} =\{0\}.}
Let
β
∈
U
∩
Q
,
{\displaystyle \beta \in U\cap \mathbb {Q} ,}
then
β
∈
Q
{\displaystyle \beta \in \mathbb {Q} }
and
|
β
|
p
≤
1
{\displaystyle |\beta |_{p}\leq 1}
for all
p
{\displaystyle p}
and therefore
β
∈
Z
.
{\displaystyle \beta \in \mathbb {Z} .}
Additionally,
β
∈
(
−
1
,
1
)
{\displaystyle \beta \in (-1,1)}
and therefore
β
=
0.
{\displaystyle \beta =0.}
Next, to show compactness, define:
W
:=
{
(
α
p
)
p
|
∀
p
<
∞
:
|
α
p
|
p
≤
1
and
|
α
∞
|
∞
≤
1
2
}
=
Z
^
×
[
−
1
2
,
1
2
]
.
{\displaystyle W:=\left\{(\alpha _{p})_{p}\left|\forall p<\infty :|\alpha _{p}|_{p}\leq 1\quad {\text{and}}\quad |\alpha _{\infty }|_{\infty }\leq {\frac {1}{2}}\right.\right\}={\widehat {\mathbb {Z} }}\times \left[-{\frac {1}{2}},{\frac {1}{2}}\right].}
Each element in
A
Q
/
Q
{\displaystyle \mathbb {A} _{\mathbb {Q} }/\mathbb {Q} }
has a representative in
W
,
{\displaystyle W,}
that is for each
α
∈
A
Q
,
{\displaystyle \alpha \in \mathbb {A} _{\mathbb {Q} },}
there exists
β
∈
Q
{\displaystyle \beta \in \mathbb {Q} }
such that
α
−
β
∈
W
.
{\displaystyle \alpha -\beta \in W.}
Let
α
=
(
α
p
)
p
∈
A
Q
,
{\displaystyle \alpha =(\alpha _{p})_{p}\in \mathbb {A} _{\mathbb {Q} },}
be arbitrary and
p
{\displaystyle p}
be a prime for which
|
α
p
|
>
1.
{\displaystyle |\alpha _{p}|>1.}
Then there exists
r
p
=
z
p
/
p
x
p
{\displaystyle r_{p}=z_{p}/p^{x_{p}}}
with
z
p
∈
Z
,
x
p
∈
N
{\displaystyle z_{p}\in \mathbb {Z} ,x_{p}\in \mathbb {N} }
and
|
α
p
−
r
p
|
≤
1.
{\displaystyle |\alpha _{p}-r_{p}|\leq 1.}
Replace
α
{\displaystyle \alpha }
with
α
−
r
p
{\displaystyle \alpha -r_{p}}
and let
q
≠
p
{\displaystyle q\neq p}
be another prime. Then:
|
α
q
−
r
p
|
q
≤
max
{
|
a
q
|
q
,
|
r
p
|
q
}
≤
max
{
|
a
q
|
q
,
1
}
≤
1.
{\displaystyle \left|\alpha _{q}-r_{p}\right|_{q}\leq \max \left\{|a_{q}|_{q},|r_{p}|_{q}\right\}\leq \max \left\{|a_{q}|_{q},1\right\}\leq 1.}
Next, it can be claimed that:
|
α
q
−
r
p
|
q
≤
1
⟺
|
α
q
|
q
≤
1.
{\displaystyle |\alpha _{q}-r_{p}|_{q}\leq 1\Longleftrightarrow |\alpha _{q}|_{q}\leq 1.}
The reverse implication is trivially true. The implication is true, because the two terms of the strong triangle inequality are equal if the absolute values of both integers are different. As a consequence, the (finite) set of primes for which the components of
α
{\displaystyle \alpha }
are not in
Z
p
{\displaystyle \mathbb {Z} _{p}}
is reduced by 1. With iteration, it can be deduced that there exists
r
∈
Q
{\displaystyle r\in \mathbb {Q} }
such that
α
−
r
∈
Z
^
×
R
.
{\displaystyle \alpha -r\in {\widehat {\mathbb {Z} }}\times \mathbb {R} .}
Now select
s
∈
Z
{\displaystyle s\in \mathbb {Z} }
such that
α
∞
−
r
−
s
∈
[
−
1
2
,
1
2
]
.
{\displaystyle \alpha _{\infty }-r-s\in \left[-{\tfrac {1}{2}},{\tfrac {1}{2}}\right].}
Then
α
−
(
r
+
s
)
∈
W
.
{\displaystyle \alpha -(r+s)\in W.}
The continuous projection
π
:
W
→
A
Q
/
Q
{\displaystyle \pi :W\to \mathbb {A} _{\mathbb {Q} }/\mathbb {Q} }
is surjective, therefore
A
Q
/
Q
,
{\displaystyle \mathbb {A} _{\mathbb {Q} }/\mathbb {Q} ,}
as the continuous image of a compact set, is compact.
Corollary. Let
E
{\displaystyle E}
be a finite-dimensional vector-space over
K
.
{\displaystyle K.}
Then
E
{\displaystyle E}
is discrete and cocompact in
A
E
.
{\displaystyle \mathbb {A} _{E}.}
Theorem. The following are assumed:
A
Q
=
Q
+
A
Z
.
{\displaystyle \mathbb {A} _{\mathbb {Q} }=\mathbb {Q} +\mathbb {A} _{\mathbb {Z} }.}
Z
=
Q
∩
A
Z
.
{\displaystyle \mathbb {Z} =\mathbb {Q} \cap \mathbb {A} _{\mathbb {Z} }.}
A
Q
/
Z
{\displaystyle \mathbb {A} _{\mathbb {Q} }/\mathbb {Z} }
is a divisible group.
Q
⊂
A
Q
,
fin
{\displaystyle \mathbb {Q} \subset \mathbb {A} _{\mathbb {Q} ,{\text{fin}}}}
is dense.
Proof. The first two equations can be proved in an elementary way.
By definition
A
Q
/
Z
{\displaystyle \mathbb {A} _{\mathbb {Q} }/\mathbb {Z} }
is divisible if for any
n
∈
N
{\displaystyle n\in \mathbb {N} }
and
y
∈
A
Q
/
Z
{\displaystyle y\in \mathbb {A} _{\mathbb {Q} }/\mathbb {Z} }
the equation
n
x
=
y
{\displaystyle nx=y}
has a solution
x
∈
A
Q
/
Z
.
{\displaystyle x\in \mathbb {A} _{\mathbb {Q} }/\mathbb {Z} .}
It is sufficient to show
A
Q
{\displaystyle \mathbb {A} _{\mathbb {Q} }}
is divisible but this is true since
A
Q
{\displaystyle \mathbb {A} _{\mathbb {Q} }}
is a field with positive characteristic in each coordinate.
For the last statement note that
A
Q
,
fin
=
Q
Z
^
,
{\displaystyle \mathbb {A} _{\mathbb {Q} ,{\text{fin}}}=\mathbb {Q} {\widehat {\mathbb {Z} }},}
because the finite number of denominators in the coordinates of the elements of
A
Q
,
fin
{\displaystyle \mathbb {A} _{\mathbb {Q} ,{\text{fin}}}}
can be reached through an element
q
∈
Q
.
{\displaystyle q\in \mathbb {Q} .}
As a consequence, it is sufficient to show
Z
⊂
Z
^
{\displaystyle \mathbb {Z} \subset {\widehat {\mathbb {Z} }}}
is dense, that is each open subset
V
⊂
Z
^
{\displaystyle V\subset {\widehat {\mathbb {Z} }}}
contains an element of
Z
.
{\displaystyle \mathbb {Z} .}
Without loss of generality, it can be assumed that
V
=
∏
p
∈
E
(
a
p
+
p
l
p
Z
p
)
×
∏
p
∉
E
Z
p
,
{\displaystyle V=\prod _{p\in E}\left(a_{p}+p^{l_{p}}\mathbb {Z} _{p}\right)\times \prod _{p\notin E}\mathbb {Z} _{p},}
because
(
p
m
Z
p
)
m
∈
N
{\displaystyle (p^{m}\mathbb {Z} _{p})_{m\in \mathbb {N} }}
is a neighbourhood system of
0
{\displaystyle 0}
in
Z
p
.
{\displaystyle \mathbb {Z} _{p}.}
By Chinese Remainder Theorem there exists
l
∈
Z
{\displaystyle l\in \mathbb {Z} }
such that
l
≡
a
p
mod
p
l
p
.
{\displaystyle l\equiv a_{p}{\bmod {p}}^{l_{p}}.}
Since powers of distinct primes are coprime,
l
∈
V
{\displaystyle l\in V}
follows.
Remark.
A
Q
/
Z
{\displaystyle \mathbb {A} _{\mathbb {Q} }/\mathbb {Z} }
is not uniquely divisible. Let
y
=
(
0
,
0
,
…
)
+
Z
∈
A
Q
/
Z
{\displaystyle y=(0,0,\ldots )+\mathbb {Z} \in \mathbb {A} _{\mathbb {Q} }/\mathbb {Z} }
and
n
≥
2
{\displaystyle n\geq 2}
be given. Then
x
1
=
(
0
,
0
,
…
)
+
Z
x
2
=
(
1
n
,
1
n
,
…
)
+
Z
{\displaystyle {\begin{aligned}x_{1}&=(0,0,\ldots )+\mathbb {Z} \\x_{2}&=\left({\tfrac {1}{n}},{\tfrac {1}{n}},\ldots \right)+\mathbb {Z} \end{aligned}}}
both satisfy the equation
n
x
=
y
{\displaystyle nx=y}
and clearly
x
1
≠
x
2
{\displaystyle x_{1}\neq x_{2}}
(
x
2
{\displaystyle x_{2}}
is well-defined, because only finitely many primes divide
n
{\displaystyle n}
). In this case, being uniquely divisible is equivalent to being torsion-free, which is not true for
A
Q
/
Z
{\displaystyle \mathbb {A} _{\mathbb {Q} }/\mathbb {Z} }
since
n
x
2
=
0
,
{\displaystyle nx_{2}=0,}
but
x
2
≠
0
{\displaystyle x_{2}\neq 0}
and
n
≠
0.
{\displaystyle n\neq 0.}
Remark. The fourth statement is a special case of the strong approximation theorem.
= Haar measure on the adele ring
=Definition. A function
f
:
A
K
→
C
{\displaystyle f:\mathbb {A} _{K}\to \mathbb {C} }
is called simple if
f
=
∏
v
f
v
,
{\displaystyle \textstyle f=\prod _{v}f_{v},}
where
f
v
:
K
v
→
C
{\displaystyle f_{v}:K_{v}\to \mathbb {C} }
are measurable and
f
v
=
1
O
v
{\displaystyle f_{v}=\mathbf {1} _{O_{v}}}
for almost all
v
.
{\displaystyle v.}
Theorem. Since
A
K
{\displaystyle \mathbb {A} _{K}}
is a locally compact group with addition, there is an additive Haar measure
d
x
{\displaystyle dx}
on
A
K
.
{\displaystyle \mathbb {A} _{K}.}
This measure can be normalised such that every integrable simple function
f
=
∏
v
f
v
{\displaystyle \textstyle f=\prod _{v}f_{v}}
satisfies:
∫
A
K
f
d
x
=
∏
v
∫
K
v
f
v
d
x
v
,
{\displaystyle \int _{\mathbb {A} _{K}}f\,dx=\prod _{v}\int _{K_{v}}f_{v}\,dx_{v},}
where for
v
<
∞
,
d
x
v
{\displaystyle v<\infty ,dx_{v}}
is the measure on
K
v
{\displaystyle K_{v}}
such that
O
v
{\displaystyle O_{v}}
has unit measure and
d
x
∞
{\displaystyle dx_{\infty }}
is the Lebesgue measure. The product is finite, i.e., almost all factors are equal to one.
The idele group
Definition. Define the idele group of
K
{\displaystyle K}
as the group of units of the adele ring of
K
,
{\displaystyle K,}
that is
I
K
:=
A
K
×
.
{\displaystyle I_{K}:=\mathbb {A} _{K}^{\times }.}
The elements of the idele group are called the ideles of
K
.
{\displaystyle K.}
Remark.
I
K
{\displaystyle I_{K}}
is equipped with a topology so that it becomes a topological group. The subset topology inherited from
A
K
{\displaystyle \mathbb {A} _{K}}
is not a suitable candidate since the group of units of a topological ring equipped with subset topology may not be a topological group. For example, the inverse map in
A
Q
{\displaystyle \mathbb {A} _{\mathbb {Q} }}
is not continuous. The sequence
x
1
=
(
2
,
1
,
…
)
x
2
=
(
1
,
3
,
1
,
…
)
x
3
=
(
1
,
1
,
5
,
1
,
…
)
⋮
{\displaystyle {\begin{aligned}x_{1}&=(2,1,\ldots )\\x_{2}&=(1,3,1,\ldots )\\x_{3}&=(1,1,5,1,\ldots )\\&\vdots \end{aligned}}}
converges to
1
∈
A
Q
.
{\displaystyle 1\in \mathbb {A} _{\mathbb {Q} }.}
To see this let
U
{\displaystyle U}
be neighbourhood of
0
,
{\displaystyle 0,}
without loss of generality it can be assumed:
U
=
∏
p
≤
N
U
p
×
∏
p
>
N
Z
p
{\displaystyle U=\prod _{p\leq N}U_{p}\times \prod _{p>N}\mathbb {Z} _{p}}
Since
(
x
n
)
p
−
1
∈
Z
p
{\displaystyle (x_{n})_{p}-1\in \mathbb {Z} _{p}}
for all
p
,
{\displaystyle p,}
x
n
−
1
∈
U
{\displaystyle x_{n}-1\in U}
for
n
{\displaystyle n}
large enough. However, as was seen above the inverse of this sequence does not converge in
A
Q
.
{\displaystyle \mathbb {A} _{\mathbb {Q} }.}
Lemma. Let
R
{\displaystyle R}
be a topological ring. Define:
{
ι
:
R
×
→
R
×
R
x
↦
(
x
,
x
−
1
)
{\displaystyle {\begin{cases}\iota :R^{\times }\to R\times R\\x\mapsto (x,x^{-1})\end{cases}}}
Equipped with the topology induced from the product on topology on
R
×
R
{\displaystyle R\times R}
and
ι
,
R
×
{\displaystyle \iota ,R^{\times }}
is a topological group and the inclusion map
R
×
⊂
R
{\displaystyle R^{\times }\subset R}
is continuous. It is the coarsest topology, emerging from the topology on
R
,
{\displaystyle R,}
that makes
R
×
{\displaystyle R^{\times }}
a topological group.
Proof. Since
R
{\displaystyle R}
is a topological ring, it is sufficient to show that the inverse map is continuous. Let
U
⊂
R
×
{\displaystyle U\subset R^{\times }}
be open, then
U
×
U
−
1
⊂
R
×
R
{\displaystyle U\times U^{-1}\subset R\times R}
is open. It is necessary to show
U
−
1
⊂
R
×
{\displaystyle U^{-1}\subset R^{\times }}
is open or equivalently, that
U
−
1
×
(
U
−
1
)
−
1
=
U
−
1
×
U
⊂
R
×
R
{\displaystyle U^{-1}\times (U^{-1})^{-1}=U^{-1}\times U\subset R\times R}
is open. But this is the condition above.
The idele group is equipped with the topology defined in the Lemma making it a topological group.
Definition. For
S
{\displaystyle S}
a subset of places of
K
{\displaystyle K}
set:
I
K
,
S
:=
A
K
,
S
×
,
I
K
S
:=
(
A
K
S
)
×
.
{\displaystyle I_{K,S}:=\mathbb {A} _{K,S}^{\times },I_{K}^{S}:=(\mathbb {A} _{K}^{S})^{\times }.}
Lemma. The following identities of topological groups hold:
I
K
,
S
=
∏
v
∈
S
′
K
v
×
I
K
S
=
∏
v
∉
S
′
K
v
×
I
K
=
∏
v
′
K
v
×
{\displaystyle {\begin{aligned}I_{K,S}&={\prod _{v\in S}}^{'}K_{v}^{\times }\\I_{K}^{S}&={\prod _{v\notin S}}^{'}K_{v}^{\times }\\I_{K}&={\prod _{v}}^{'}K_{v}^{\times }\end{aligned}}}
where the restricted product has the restricted product topology, which is generated by restricted open rectangles of the form
∏
v
∈
E
U
v
×
∏
v
∉
E
O
v
×
,
{\displaystyle \prod _{v\in E}U_{v}\times \prod _{v\notin E}O_{v}^{\times },}
where
E
{\displaystyle E}
is a finite subset of the set of all places and
U
v
⊂
K
v
×
{\displaystyle U_{v}\subset K_{v}^{\times }}
are open sets.
Proof. Prove the identity for
I
K
{\displaystyle I_{K}}
; the other two follow similarly. First show the two sets are equal:
I
K
=
{
x
=
(
x
v
)
v
∈
A
K
:
∃
y
=
(
y
v
)
v
∈
A
K
:
x
y
=
1
}
=
{
x
=
(
x
v
)
v
∈
A
K
:
∃
y
=
(
y
v
)
v
∈
A
K
:
x
v
⋅
y
v
=
1
∀
v
}
=
{
x
=
(
x
v
)
v
:
x
v
∈
K
v
×
∀
v
and
x
v
∈
O
v
×
for almost all
v
}
=
∏
v
′
K
v
×
{\displaystyle {\begin{aligned}I_{K}&=\{x=(x_{v})_{v}\in \mathbb {A} _{K}:\exists y=(y_{v})_{v}\in \mathbb {A} _{K}:xy=1\}\\&=\{x=(x_{v})_{v}\in \mathbb {A} _{K}:\exists y=(y_{v})_{v}\in \mathbb {A} _{K}:x_{v}\cdot y_{v}=1\quad \forall v\}\\&=\{x=(x_{v})_{v}:x_{v}\in K_{v}^{\times }\forall v{\text{ and }}x_{v}\in O_{v}^{\times }{\text{ for almost all }}v\}\\&={\prod _{v}}^{'}K_{v}^{\times }\end{aligned}}}
In going from line 2 to 3,
x
{\displaystyle x}
as well as
x
−
1
=
y
{\displaystyle x^{-1}=y}
have to be in
A
K
,
{\displaystyle \mathbb {A} _{K},}
meaning
x
v
∈
O
v
{\displaystyle x_{v}\in O_{v}}
for almost all
v
{\displaystyle v}
and
x
v
−
1
∈
O
v
{\displaystyle x_{v}^{-1}\in O_{v}}
for almost all
v
.
{\displaystyle v.}
Therefore,
x
v
∈
O
v
×
{\displaystyle x_{v}\in O_{v}^{\times }}
for almost all
v
.
{\displaystyle v.}
Now, it is possible to show the topology on the left-hand side equals the topology on the right-hand side. Obviously, every open restricted rectangle is open in the topology of the idele group. On the other hand, for a given
U
⊂
I
K
,
{\displaystyle U\subset I_{K},}
which is open in the topology of the idele group, meaning
U
×
U
−
1
⊂
A
K
×
A
K
{\displaystyle U\times U^{-1}\subset \mathbb {A} _{K}\times \mathbb {A} _{K}}
is open, so for each
u
∈
U
{\displaystyle u\in U}
there exists an open restricted rectangle, which is a subset of
U
{\displaystyle U}
and contains
u
.
{\displaystyle u.}
Therefore,
U
{\displaystyle U}
is the union of all these restricted open rectangles and therefore is open in the restricted product topology.
Lemma. For each set of places,
S
,
I
K
,
S
{\displaystyle S,I_{K,S}}
is a locally compact topological group.
Proof. The local compactness follows from the description of
I
K
,
S
{\displaystyle I_{K,S}}
as a restricted product. It being a topological group follows from the above discussion on the group of units of a topological ring.
A neighbourhood system of
1
∈
A
K
(
P
∞
)
×
{\displaystyle 1\in \mathbb {A} _{K}(P_{\infty })^{\times }}
is a neighbourhood system of
1
∈
I
K
.
{\displaystyle 1\in I_{K}.}
Alternatively, take all sets of the form:
∏
v
U
v
,
{\displaystyle \prod _{v}U_{v},}
where
U
v
{\displaystyle U_{v}}
is a neighbourhood of
1
∈
K
v
×
{\displaystyle 1\in K_{v}^{\times }}
and
U
v
=
O
v
×
{\displaystyle U_{v}=O_{v}^{\times }}
for almost all
v
.
{\displaystyle v.}
Since the idele group is a locally compact, there exists a Haar measure
d
×
x
{\displaystyle d^{\times }x}
on it. This can be normalised, so that
∫
I
K
,
fin
1
O
^
d
×
x
=
1.
{\displaystyle \int _{I_{K,{\text{fin}}}}\mathbf {1} _{\widehat {O}}\,d^{\times }x=1.}
This is the normalisation used for the finite places. In this equation,
I
K
,
fin
{\displaystyle I_{K,{\text{fin}}}}
is the finite idele group, meaning the group of units of the finite adele ring. For the infinite places, use the multiplicative lebesgue measure
d
x
|
x
|
.
{\displaystyle {\tfrac {dx}{|x|}}.}
= The idele group of a finite extension
=Lemma. Let
L
/
K
{\displaystyle L/K}
be a finite extension. Then:
I
L
=
∏
v
′
L
v
×
.
{\displaystyle I_{L}={\prod _{v}}^{'}L_{v}^{\times }.}
where the restricted product is with respect to
O
v
~
×
.
{\displaystyle {\widetilde {O_{v}}}^{\times }.}
Lemma. There is a canonical embedding of
I
K
{\displaystyle I_{K}}
in
I
L
.
{\displaystyle I_{L}.}
Proof. Map
a
=
(
a
v
)
v
∈
I
K
{\displaystyle a=(a_{v})_{v}\in I_{K}}
to
a
′
=
(
a
w
′
)
w
∈
I
L
{\displaystyle a'=(a'_{w})_{w}\in I_{L}}
with the property
a
w
′
=
a
v
∈
K
v
×
⊂
L
w
×
{\displaystyle a'_{w}=a_{v}\in K_{v}^{\times }\subset L_{w}^{\times }}
for
w
|
v
.
{\displaystyle w|v.}
Therefore,
I
K
{\displaystyle I_{K}}
can be seen as a subgroup of
I
L
.
{\displaystyle I_{L}.}
An element
a
=
(
a
w
)
w
∈
I
L
{\displaystyle a=(a_{w})_{w}\in I_{L}}
is in this subgroup if and only if his components satisfy the following properties:
a
w
∈
K
v
×
{\displaystyle a_{w}\in K_{v}^{\times }}
for
w
|
v
{\displaystyle w|v}
and
a
w
=
a
w
′
{\displaystyle a_{w}=a_{w'}}
for
w
|
v
{\displaystyle w|v}
and
w
′
|
v
{\displaystyle w'|v}
for the same place
v
{\displaystyle v}
of
K
.
{\displaystyle K.}
= The case of vector spaces and algebras
=The idele group of an algebra
Let
A
{\displaystyle A}
be a finite-dimensional algebra over
K
.
{\displaystyle K.}
Since
A
A
×
{\displaystyle \mathbb {A} _{A}^{\times }}
is not a topological group with the subset-topology in general, equip
A
A
×
{\displaystyle \mathbb {A} _{A}^{\times }}
with the topology similar to
I
K
{\displaystyle I_{K}}
above and call
A
A
×
{\displaystyle \mathbb {A} _{A}^{\times }}
the idele group. The elements of the idele group are called idele of
A
.
{\displaystyle A.}
Proposition. Let
α
{\displaystyle \alpha }
be a finite subset of
A
,
{\displaystyle A,}
containing a basis of
A
{\displaystyle A}
over
K
.
{\displaystyle K.}
For each finite place
v
{\displaystyle v}
of
K
,
{\displaystyle K,}
let
α
v
{\displaystyle \alpha _{v}}
be the
O
v
{\displaystyle O_{v}}
-module generated by
α
{\displaystyle \alpha }
in
A
v
.
{\displaystyle A_{v}.}
There exists a finite set of places
P
0
{\displaystyle P_{0}}
containing
P
∞
{\displaystyle P_{\infty }}
such that for all
v
∉
P
0
,
{\displaystyle v\notin P_{0},}
α
v
{\displaystyle \alpha _{v}}
is a compact subring of
A
v
.
{\displaystyle A_{v}.}
Furthermore,
α
v
{\displaystyle \alpha _{v}}
contains
A
v
×
.
{\displaystyle A_{v}^{\times }.}
For each
v
,
A
v
×
{\displaystyle v,A_{v}^{\times }}
is an open subset of
A
v
{\displaystyle A_{v}}
and the map
x
↦
x
−
1
{\displaystyle x\mapsto x^{-1}}
is continuous on
A
v
×
.
{\displaystyle A_{v}^{\times }.}
As a consequence
x
↦
(
x
,
x
−
1
)
{\displaystyle x\mapsto (x,x^{-1})}
maps
A
v
×
{\displaystyle A_{v}^{\times }}
homeomorphically on its image in
A
v
×
A
v
.
{\displaystyle A_{v}\times A_{v}.}
For each
v
∉
P
0
,
{\displaystyle v\notin P_{0},}
the
α
v
×
{\displaystyle \alpha _{v}^{\times }}
are the elements of
A
v
×
,
{\displaystyle A_{v}^{\times },}
mapping in
α
v
×
α
v
{\displaystyle \alpha _{v}\times \alpha _{v}}
with the function above. Therefore,
α
v
×
{\displaystyle \alpha _{v}^{\times }}
is an open and compact subgroup of
A
v
×
.
{\displaystyle A_{v}^{\times }.}
Alternative characterisation of the idele group
Proposition. Let
P
⊃
P
∞
{\displaystyle P\supset P_{\infty }}
be a finite set of places. Then
A
A
(
P
,
α
)
×
:=
∏
v
∈
P
A
v
×
×
∏
v
∉
P
α
v
×
{\displaystyle \mathbb {A} _{A}(P,\alpha )^{\times }:=\prod _{v\in P}A_{v}^{\times }\times \prod _{v\notin P}\alpha _{v}^{\times }}
is an open subgroup of
A
A
×
,
{\displaystyle \mathbb {A} _{A}^{\times },}
where
A
A
×
{\displaystyle \mathbb {A} _{A}^{\times }}
is the union of all
A
A
(
P
,
α
)
×
.
{\displaystyle \mathbb {A} _{A}(P,\alpha )^{\times }.}
Corollary. In the special case of
A
=
K
{\displaystyle A=K}
for each finite set of places
P
⊃
P
∞
,
{\displaystyle P\supset P_{\infty },}
A
K
(
P
)
×
=
∏
v
∈
P
K
v
×
×
∏
v
∉
P
O
v
×
{\displaystyle \mathbb {A} _{K}(P)^{\times }=\prod _{v\in P}K_{v}^{\times }\times \prod _{v\notin P}O_{v}^{\times }}
is an open subgroup of
A
K
×
=
I
K
.
{\displaystyle \mathbb {A} _{K}^{\times }=I_{K}.}
Furthermore,
I
K
{\displaystyle I_{K}}
is the union of all
A
K
(
P
)
×
.
{\displaystyle \mathbb {A} _{K}(P)^{\times }.}
= Norm on the idele group
=The trace and the norm should be transfer from the adele ring to the idele group. It turns out the trace can't be transferred so easily. However, it is possible to transfer the norm from the adele ring to the idele group. Let
α
∈
I
K
.
{\displaystyle \alpha \in I_{K}.}
Then
con
L
/
K
(
α
)
∈
I
L
{\displaystyle \operatorname {con} _{L/K}(\alpha )\in I_{L}}
and therefore, it can be said that in injective group homomorphism
con
L
/
K
:
I
K
↪
I
L
.
{\displaystyle \operatorname {con} _{L/K}:I_{K}\hookrightarrow I_{L}.}
Since
α
∈
I
L
,
{\displaystyle \alpha \in I_{L},}
it is invertible,
N
L
/
K
(
α
)
{\displaystyle N_{L/K}(\alpha )}
is invertible too, because
(
N
L
/
K
(
α
)
)
−
1
=
N
L
/
K
(
α
−
1
)
.
{\displaystyle (N_{L/K}(\alpha ))^{-1}=N_{L/K}(\alpha ^{-1}).}
Therefore
N
L
/
K
(
α
)
∈
I
K
.
{\displaystyle N_{L/K}(\alpha )\in I_{K}.}
As a consequence, the restriction of the norm-function introduces a continuous function:
N
L
/
K
:
I
L
→
I
K
.
{\displaystyle N_{L/K}:I_{L}\to I_{K}.}
= The Idele class group
=Lemma. There is natural embedding of
K
×
{\displaystyle K^{\times }}
into
I
K
,
S
{\displaystyle I_{K,S}}
given by the diagonal map:
a
↦
(
a
,
a
,
a
,
…
)
.
{\displaystyle a\mapsto (a,a,a,\ldots ).}
Proof. Since
K
×
{\displaystyle K^{\times }}
is a subset of
K
v
×
{\displaystyle K_{v}^{\times }}
for all
v
,
{\displaystyle v,}
the embedding is well-defined and injective.
Corollary.
A
×
{\displaystyle A^{\times }}
is a discrete subgroup of
A
A
×
.
{\displaystyle \mathbb {A} _{A}^{\times }.}
Defenition. In analogy to the ideal class group, the elements of
K
×
{\displaystyle K^{\times }}
in
I
K
{\displaystyle I_{K}}
are called principal ideles of
I
K
.
{\displaystyle I_{K}.}
The quotient group
C
K
:=
I
K
/
K
×
{\displaystyle C_{K}:=I_{K}/K^{\times }}
is called idele class group of
K
.
{\displaystyle K.}
This group is related to the ideal class group and is a central object in class field theory.
Remark.
K
×
{\displaystyle K^{\times }}
is closed in
I
K
,
{\displaystyle I_{K},}
therefore
C
K
{\displaystyle C_{K}}
is a locally compact topological group and a Hausdorff space.
Lemma. Let
L
/
K
{\displaystyle L/K}
be a finite extension. The embedding
I
K
→
I
L
{\displaystyle I_{K}\to I_{L}}
induces an injective map:
{
C
K
→
C
L
α
K
×
↦
α
L
×
{\displaystyle {\begin{cases}C_{K}\to C_{L}\\\alpha K^{\times }\mapsto \alpha L^{\times }\end{cases}}}
= Properties of the idele group
=Absolute value on the idele group of K and 1-idele
Definition. For
α
=
(
α
v
)
v
∈
I
K
{\displaystyle \alpha =(\alpha _{v})_{v}\in I_{K}}
define:
|
α
|
:=
∏
v
|
α
v
|
v
.
{\displaystyle \textstyle |\alpha |:=\prod _{v}|\alpha _{v}|_{v}.}
Since
α
{\displaystyle \alpha }
is an idele this product is finite and therefore well-defined.
Remark. The definition can be extended to
A
K
{\displaystyle \mathbb {A} _{K}}
by allowing infinite products. However, these infinite products vanish and so
|
⋅
|
{\displaystyle |\cdot |}
vanishes on
A
K
∖
I
K
.
{\displaystyle \mathbb {A} _{K}\setminus I_{K}.}
|
⋅
|
{\displaystyle |\cdot |}
will be used to denote both the function on
I
K
{\displaystyle I_{K}}
and
A
K
.
{\displaystyle \mathbb {A} _{K}.}
Theorem.
|
⋅
|
:
I
K
→
R
+
{\displaystyle |\cdot |:I_{K}\to \mathbb {R} _{+}}
is a continuous group homomorphism.
Proof. Let
α
,
β
∈
I
K
.
{\displaystyle \alpha ,\beta \in I_{K}.}
|
α
⋅
β
|
=
∏
v
|
(
α
⋅
β
)
v
|
v
=
∏
v
|
α
v
⋅
β
v
|
v
=
∏
v
(
|
α
v
|
v
⋅
|
β
v
|
v
)
=
(
∏
v
|
α
v
|
v
)
⋅
(
∏
v
|
β
v
|
v
)
=
|
α
|
⋅
|
β
|
{\displaystyle {\begin{aligned}|\alpha \cdot \beta |&=\prod _{v}|(\alpha \cdot \beta )_{v}|_{v}\\&=\prod _{v}|\alpha _{v}\cdot \beta _{v}|_{v}\\&=\prod _{v}(|\alpha _{v}|_{v}\cdot |\beta _{v}|_{v})\\&=\left(\prod _{v}|\alpha _{v}|_{v}\right)\cdot \left(\prod _{v}|\beta _{v}|_{v}\right)\\&=|\alpha |\cdot |\beta |\end{aligned}}}
where it is used that all products are finite. The map is continuous which can be seen using an argument dealing with sequences. This reduces the problem to whether
|
⋅
|
{\displaystyle |\cdot |}
is continuous on
K
v
.
{\displaystyle K_{v}.}
However, this is clear, because of the reverse triangle inequality.
Definition. The set of
1
{\displaystyle 1}
-idele can be defined as:
I
K
1
:=
{
x
∈
I
K
:
|
x
|
=
1
}
=
ker
(
|
⋅
|
)
.
{\displaystyle I_{K}^{1}:=\{x\in I_{K}:|x|=1\}=\ker(|\cdot |).}
I
K
1
{\displaystyle I_{K}^{1}}
is a subgroup of
I
K
.
{\displaystyle I_{K}.}
Since
I
K
1
=
|
⋅
|
−
1
(
{
1
}
)
,
{\displaystyle I_{K}^{1}=|\cdot |^{-1}(\{1\}),}
it is a closed subset of
A
K
.
{\displaystyle \mathbb {A} _{K}.}
Finally the
A
K
{\displaystyle \mathbb {A} _{K}}
-topology on
I
K
1
{\displaystyle I_{K}^{1}}
equals the subset-topology of
I
K
{\displaystyle I_{K}}
on
I
K
1
.
{\displaystyle I_{K}^{1}.}
Artin's Product Formula.
|
k
|
=
1
{\displaystyle |k|=1}
for all
k
∈
K
×
.
{\displaystyle k\in K^{\times }.}
Proof. Proof of the formula for number fields, the case of global function fields can be proved similarly. Let
K
{\displaystyle K}
be a number field and
a
∈
K
×
.
{\displaystyle a\in K^{\times }.}
It has to be shown that:
∏
v
|
a
|
v
=
1.
{\displaystyle \prod _{v}|a|_{v}=1.}
For finite place
v
{\displaystyle v}
for which the corresponding prime ideal
p
v
{\displaystyle {\mathfrak {p}}_{v}}
does not divide
(
a
)
{\displaystyle (a)}
,
v
(
a
)
=
0
{\displaystyle v(a)=0}
and therefore
|
a
|
v
=
1.
{\displaystyle |a|_{v}=1.}
This is valid for almost all
p
v
.
{\displaystyle {\mathfrak {p}}_{v}.}
There is:
∏
v
|
a
|
v
=
∏
p
≤
∞
∏
v
|
p
|
a
|
v
=
∏
p
≤
∞
∏
v
|
p
|
N
K
v
/
Q
p
(
a
)
|
p
=
∏
p
≤
∞
|
N
K
/
Q
(
a
)
|
p
{\displaystyle {\begin{aligned}\prod _{v}|a|_{v}&=\prod _{p\leq \infty }\prod _{v|p}|a|_{v}\\&=\prod _{p\leq \infty }\prod _{v|p}|N_{K_{v}/\mathbb {Q} _{p}}(a)|_{p}\\&=\prod _{p\leq \infty }|N_{K/\mathbb {Q} }(a)|_{p}\end{aligned}}}
In going from line 1 to line 2, the identity
|
a
|
w
=
|
N
L
w
/
K
v
(
a
)
|
v
,
{\displaystyle |a|_{w}=|N_{L_{w}/K_{v}}(a)|_{v},}
was used where
v
{\displaystyle v}
is a place of
K
{\displaystyle K}
and
w
{\displaystyle w}
is a place of
L
,
{\displaystyle L,}
lying above
v
.
{\displaystyle v.}
Going from line 2 to line 3, a property of the norm is used. The norm is in
Q
{\displaystyle \mathbb {Q} }
so without loss of generality it can be assumed that
a
∈
Q
.
{\displaystyle a\in \mathbb {Q} .}
Then
a
{\displaystyle a}
possesses a unique integer factorisation:
a
=
±
∏
p
<
∞
p
v
p
,
{\displaystyle a=\pm \prod _{p<\infty }p^{v_{p}},}
where
v
p
∈
Z
{\displaystyle v_{p}\in \mathbb {Z} }
is
0
{\displaystyle 0}
for almost all
p
.
{\displaystyle p.}
By Ostrowski's theorem all absolute values on
Q
{\displaystyle \mathbb {Q} }
are equivalent to the real absolute value
|
⋅
|
∞
{\displaystyle |\cdot |_{\infty }}
or a
p
{\displaystyle p}
-adic absolute value. Therefore:
|
a
|
=
(
∏
p
<
∞
|
a
|
p
)
⋅
|
a
|
∞
=
(
∏
p
<
∞
p
−
v
p
)
⋅
(
∏
p
<
∞
p
v
p
)
=
1
{\displaystyle {\begin{aligned}|a|&=\left(\prod _{p<\infty }|a|_{p}\right)\cdot |a|_{\infty }\\&=\left(\prod _{p<\infty }p^{-v_{p}}\right)\cdot \left(\prod _{p<\infty }p^{v_{p}}\right)\\&=1\end{aligned}}}
Lemma. There exists a constant
C
,
{\displaystyle C,}
depending only on
K
,
{\displaystyle K,}
such that for every
α
=
(
α
v
)
v
∈
A
K
{\displaystyle \alpha =(\alpha _{v})_{v}\in \mathbb {A} _{K}}
satisfying
∏
v
|
α
v
|
v
>
C
,
{\displaystyle \textstyle \prod _{v}|\alpha _{v}|_{v}>C,}
there exists
β
∈
K
×
{\displaystyle \beta \in K^{\times }}
such that
|
β
v
|
v
≤
|
α
v
|
v
{\displaystyle |\beta _{v}|_{v}\leq |\alpha _{v}|_{v}}
for all
v
.
{\displaystyle v.}
Corollary. Let
v
0
{\displaystyle v_{0}}
be a place of
K
{\displaystyle K}
and let
δ
v
>
0
{\displaystyle \delta _{v}>0}
be given for all
v
≠
v
0
{\displaystyle v\neq v_{0}}
with the property
δ
v
=
1
{\displaystyle \delta _{v}=1}
for almost all
v
.
{\displaystyle v.}
Then there exists
β
∈
K
×
,
{\displaystyle \beta \in K^{\times },}
so that
|
β
|
≤
δ
v
{\displaystyle |\beta |\leq \delta _{v}}
for all
v
≠
v
0
.
{\displaystyle v\neq v_{0}.}
Proof. Let
C
{\displaystyle C}
be the constant from the lemma. Let
π
v
{\displaystyle \pi _{v}}
be a uniformising element of
O
v
.
{\displaystyle O_{v}.}
Define the adele
α
=
(
α
v
)
v
{\displaystyle \alpha =(\alpha _{v})_{v}}
via
α
v
:=
π
v
k
v
{\displaystyle \alpha _{v}:=\pi _{v}^{k_{v}}}
with
k
v
∈
Z
{\displaystyle k_{v}\in \mathbb {Z} }
minimal, so that
|
α
v
|
v
≤
δ
v
{\displaystyle |\alpha _{v}|_{v}\leq \delta _{v}}
for all
v
≠
v
0
.
{\displaystyle v\neq v_{0}.}
Then
k
v
=
0
{\displaystyle k_{v}=0}
for almost all
v
.
{\displaystyle v.}
Define
α
v
0
:=
π
v
0
k
v
0
{\displaystyle \alpha _{v_{0}}:=\pi _{v_{0}}^{k_{v_{0}}}}
with
k
v
0
∈
Z
,
{\displaystyle k_{v_{0}}\in \mathbb {Z} ,}
so that
∏
v
|
α
v
|
v
>
C
.
{\displaystyle \textstyle \prod _{v}|\alpha _{v}|_{v}>C.}
This works, because
k
v
=
0
{\displaystyle k_{v}=0}
for almost all
v
.
{\displaystyle v.}
By the Lemma there exists
β
∈
K
×
,
{\displaystyle \beta \in K^{\times },}
so that
|
β
|
v
≤
|
α
v
|
v
≤
δ
v
{\displaystyle |\beta |_{v}\leq |\alpha _{v}|_{v}\leq \delta _{v}}
for all
v
≠
v
0
.
{\displaystyle v\neq v_{0}.}
Theorem.
K
×
{\displaystyle K^{\times }}
is discrete and cocompact in
I
K
1
.
{\displaystyle I_{K}^{1}.}
Proof. Since
K
×
{\displaystyle K^{\times }}
is discrete in
I
K
{\displaystyle I_{K}}
it is also discrete in
I
K
1
.
{\displaystyle I_{K}^{1}.}
To prove the compactness of
I
K
1
/
K
×
{\displaystyle I_{K}^{1}/K^{\times }}
let
C
{\displaystyle C}
is the constant of the Lemma and suppose
α
∈
A
K
{\displaystyle \alpha \in \mathbb {A} _{K}}
satisfying
∏
v
|
α
v
|
v
>
C
{\displaystyle \textstyle \prod _{v}|\alpha _{v}|_{v}>C}
is given. Define:
W
α
:=
{
ξ
=
(
ξ
v
)
v
∈
A
K
|
|
ξ
v
|
v
≤
|
α
v
|
v
for all
v
}
.
{\displaystyle W_{\alpha }:=\left\{\xi =(\xi _{v})_{v}\in \mathbb {A} _{K}||\xi _{v}|_{v}\leq |\alpha _{v}|_{v}{\text{ for all }}v\right\}.}
Clearly
W
α
{\displaystyle W_{\alpha }}
is compact. It can be claimed that the natural projection
W
α
∩
I
K
1
→
I
K
1
/
K
×
{\displaystyle W_{\alpha }\cap I_{K}^{1}\to I_{K}^{1}/K^{\times }}
is surjective. Let
β
=
(
β
v
)
v
∈
I
K
1
{\displaystyle \beta =(\beta _{v})_{v}\in I_{K}^{1}}
be arbitrary, then:
|
β
|
=
∏
v
|
β
v
|
v
=
1
,
{\displaystyle |\beta |=\prod _{v}|\beta _{v}|_{v}=1,}
and therefore
∏
v
|
β
v
−
1
|
v
=
1.
{\displaystyle \prod _{v}|\beta _{v}^{-1}|_{v}=1.}
It follows that
∏
v
|
β
v
−
1
α
v
|
v
=
∏
v
|
α
v
|
v
>
C
.
{\displaystyle \prod _{v}|\beta _{v}^{-1}\alpha _{v}|_{v}=\prod _{v}|\alpha _{v}|_{v}>C.}
By the Lemma there exists
η
∈
K
×
{\displaystyle \eta \in K^{\times }}
such that
|
η
|
v
≤
|
β
v
−
1
α
v
|
v
{\displaystyle |\eta |_{v}\leq |\beta _{v}^{-1}\alpha _{v}|_{v}}
for all
v
,
{\displaystyle v,}
and therefore
η
β
∈
W
α
{\displaystyle \eta \beta \in W_{\alpha }}
proving the surjectivity of the natural projection. Since it is also continuous the compactness follows.
Theorem. There is a canonical isomorphism
I
Q
1
/
Q
×
≅
Z
^
×
.
{\displaystyle I_{\mathbb {Q} }^{1}/\mathbb {Q} ^{\times }\cong {\widehat {\mathbb {Z} }}^{\times }.}
Furthermore,
Z
^
×
×
{
1
}
⊂
I
Q
1
{\displaystyle {\widehat {\mathbb {Z} }}^{\times }\times \{1\}\subset I_{\mathbb {Q} }^{1}}
is a set of representatives for
I
Q
1
/
Q
×
{\displaystyle I_{\mathbb {Q} }^{1}/\mathbb {Q} ^{\times }}
and
Z
^
×
×
(
0
,
∞
)
⊂
I
Q
{\displaystyle {\widehat {\mathbb {Z} }}^{\times }\times (0,\infty )\subset I_{\mathbb {Q} }}
is a set of representatives for
I
Q
/
Q
×
.
{\displaystyle I_{\mathbb {Q} }/\mathbb {Q} ^{\times }.}
Proof. Consider the map
{
ϕ
:
Z
^
×
→
I
Q
1
/
Q
×
(
a
p
)
p
↦
(
(
a
p
)
p
,
1
)
Q
×
{\displaystyle {\begin{cases}\phi :{\widehat {\mathbb {Z} }}^{\times }\to I_{\mathbb {Q} }^{1}/\mathbb {Q} ^{\times }\\(a_{p})_{p}\mapsto ((a_{p})_{p},1)\mathbb {Q} ^{\times }\end{cases}}}
This map is well-defined, since
|
a
p
|
p
=
1
{\displaystyle |a_{p}|_{p}=1}
for all
p
{\displaystyle p}
and therefore
(
∏
p
<
∞
|
a
p
|
p
)
⋅
1
=
1.
{\displaystyle \textstyle \left(\prod _{p<\infty }|a_{p}|_{p}\right)\cdot 1=1.}
Obviously
ϕ
{\displaystyle \phi }
is a continuous group homomorphism. Now suppose
(
(
a
p
)
p
,
1
)
Q
×
=
(
(
b
p
)
p
,
1
)
Q
×
.
{\displaystyle ((a_{p})_{p},1)\mathbb {Q} ^{\times }=((b_{p})_{p},1)\mathbb {Q} ^{\times }.}
Then there exists
q
∈
Q
×
{\displaystyle q\in \mathbb {Q} ^{\times }}
such that
(
(
a
p
)
p
,
1
)
q
=
(
(
b
p
)
p
,
1
)
.
{\displaystyle ((a_{p})_{p},1)q=((b_{p})_{p},1).}
By considering the infinite place it can be seen that
q
=
1
{\displaystyle q=1}
proves injectivity. To show surjectivity let
(
(
β
p
)
p
,
β
∞
)
Q
×
∈
I
Q
1
/
Q
×
.
{\displaystyle ((\beta _{p})_{p},\beta _{\infty })\mathbb {Q} ^{\times }\in I_{\mathbb {Q} }^{1}/\mathbb {Q} ^{\times }.}
The absolute value of this element is
1
{\displaystyle 1}
and therefore
|
β
∞
|
∞
=
1
∏
p
|
β
p
|
p
∈
Q
.
{\displaystyle |\beta _{\infty }|_{\infty }={\frac {1}{\prod _{p}|\beta _{p}|_{p}}}\in \mathbb {Q} .}
Hence
β
∞
∈
Q
{\displaystyle \beta _{\infty }\in \mathbb {Q} }
and there is:
(
(
β
p
)
p
,
β
∞
)
Q
×
=
(
(
β
p
β
∞
)
p
,
1
)
Q
×
.
{\displaystyle ((\beta _{p})_{p},\beta _{\infty })\mathbb {Q} ^{\times }=\left(\left({\frac {\beta _{p}}{\beta _{\infty }}}\right)_{p},1\right)\mathbb {Q} ^{\times }.}
Since
∀
p
:
|
β
p
β
∞
|
p
=
1
,
{\displaystyle \forall p:\qquad \left|{\frac {\beta _{p}}{\beta _{\infty }}}\right|_{p}=1,}
It has been concluded that
ϕ
{\displaystyle \phi }
is surjective.
Theorem. The absolute value function induces the following isomorphisms of topological groups:
I
Q
≅
I
Q
1
×
(
0
,
∞
)
I
Q
1
≅
I
Q
,
fin
×
{
±
1
}
.
{\displaystyle {\begin{aligned}I_{\mathbb {Q} }&\cong I_{\mathbb {Q} }^{1}\times (0,\infty )\\I_{\mathbb {Q} }^{1}&\cong I_{\mathbb {Q} ,{\text{fin}}}\times \{\pm 1\}.\end{aligned}}}
Proof. The isomorphisms are given by:
{
ψ
:
I
Q
→
I
Q
1
×
(
0
,
∞
)
a
=
(
a
fin
,
a
∞
)
↦
(
a
fin
,
a
∞
|
a
|
,
|
a
|
)
and
{
ψ
~
:
I
Q
,
fin
×
{
±
1
}
→
I
Q
1
(
a
fin
,
ε
)
↦
(
a
fin
,
ε
|
a
fin
|
)
{\displaystyle {\begin{cases}\psi :I_{\mathbb {Q} }\to I_{\mathbb {Q} }^{1}\times (0,\infty )\\a=(a_{\text{fin}},a_{\infty })\mapsto \left(a_{\text{fin}},{\frac {a_{\infty }}{|a|}},|a|\right)\end{cases}}\qquad {\text{and}}\qquad {\begin{cases}{\widetilde {\psi }}:I_{\mathbb {Q} ,{\text{fin}}}\times \{\pm 1\}\to I_{\mathbb {Q} }^{1}\\(a_{\text{fin}},\varepsilon )\mapsto \left(a_{\text{fin}},{\frac {\varepsilon }{|a_{\text{fin}}|}}\right)\end{cases}}}
Relation between ideal class group and idele class group
Theorem. Let
K
{\displaystyle K}
be a number field with ring of integers
O
,
{\displaystyle O,}
group of fractional ideals
J
K
,
{\displaystyle J_{K},}
and ideal class group
Cl
K
=
J
K
/
K
×
.
{\displaystyle \operatorname {Cl} _{K}=J_{K}/K^{\times }.}
Here's the following isomorphisms
J
K
≅
I
K
,
fin
/
O
^
×
Cl
K
≅
C
K
,
fin
/
O
^
×
K
×
Cl
K
≅
C
K
/
(
O
^
×
×
∏
v
|
∞
K
v
×
)
K
×
{\displaystyle {\begin{aligned}J_{K}&\cong I_{K,{\text{fin}}}/{\widehat {O}}^{\times }\\\operatorname {Cl} _{K}&\cong C_{K,{\text{fin}}}/{\widehat {O}}^{\times }K^{\times }\\\operatorname {Cl} _{K}&\cong C_{K}/\left({\widehat {O}}^{\times }\times \prod _{v|\infty }K_{v}^{\times }\right)K^{\times }\end{aligned}}}
where
C
K
,
fin
:=
I
K
,
fin
/
K
×
{\displaystyle C_{K,{\text{fin}}}:=I_{K,{\text{fin}}}/K^{\times }}
has been defined.
Proof. Let
v
{\displaystyle v}
be a finite place of
K
{\displaystyle K}
and let
|
⋅
|
v
{\displaystyle |\cdot |_{v}}
be a representative of the equivalence class
v
.
{\displaystyle v.}
Define
p
v
:=
{
x
∈
O
:
|
x
|
v
<
1
}
.
{\displaystyle {\mathfrak {p}}_{v}:=\{x\in O:|x|_{v}<1\}.}
Then
p
v
{\displaystyle {\mathfrak {p}}_{v}}
is a prime ideal in
O
.
{\displaystyle O.}
The map
v
↦
p
v
{\displaystyle v\mapsto {\mathfrak {p}}_{v}}
is a bijection between finite places of
K
{\displaystyle K}
and non-zero prime ideals of
O
.
{\displaystyle O.}
The inverse is given as follows: a prime ideal
p
{\displaystyle {\mathfrak {p}}}
is mapped to the valuation
v
p
,
{\displaystyle v_{\mathfrak {p}},}
given by
v
p
(
x
)
:=
max
{
k
∈
N
0
:
x
∈
p
k
}
∀
x
∈
O
×
v
p
(
x
y
)
:=
v
p
(
x
)
−
v
p
(
y
)
∀
x
,
y
∈
O
×
{\displaystyle {\begin{aligned}v_{\mathfrak {p}}(x)&:=\max\{k\in \mathbb {N} _{0}:x\in {\mathfrak {p}}^{k}\}\quad \forall x\in O^{\times }\\v_{\mathfrak {p}}\left({\frac {x}{y}}\right)&:=v_{\mathfrak {p}}(x)-v_{\mathfrak {p}}(y)\quad \forall x,y\in O^{\times }\end{aligned}}}
The following map is well-defined:
{
(
⋅
)
:
I
K
,
fin
→
J
K
α
=
(
α
v
)
v
↦
∏
v
<
∞
p
v
v
(
α
v
)
,
{\displaystyle {\begin{cases}(\cdot ):I_{K,{\text{fin}}}\to J_{K}\\\alpha =(\alpha _{v})_{v}\mapsto \prod _{v<\infty }{\mathfrak {p}}_{v}^{v(\alpha _{v})},\end{cases}}}
The map
(
⋅
)
{\displaystyle (\cdot )}
is obviously a surjective homomorphism and
ker
(
(
⋅
)
)
=
O
^
×
.
{\displaystyle \ker((\cdot ))={\widehat {O}}^{\times }.}
The first isomorphism follows from fundamental theorem on homomorphism. Now, both sides are divided by
K
×
.
{\displaystyle K^{\times }.}
This is possible, because
(
α
)
=
(
(
α
,
α
,
…
)
)
=
∏
v
<
∞
p
v
v
(
α
)
=
(
α
)
for all
α
∈
K
×
.
{\displaystyle {\begin{aligned}(\alpha )&=((\alpha ,\alpha ,\dotsc ))\\&=\prod _{v<\infty }{\mathfrak {p}}_{v}^{v(\alpha )}\\&=(\alpha )&&{\text{ for all }}\alpha \in K^{\times }.\end{aligned}}}
Please, note the abuse of notation: On the left hand side in line 1 of this chain of equations,
(
⋅
)
{\displaystyle (\cdot )}
stands for the map defined above. Later, the embedding of
K
×
{\displaystyle K^{\times }}
into
I
K
,
fin
{\displaystyle I_{K,{\text{fin}}}}
is used. In line 2, the definition of the map is used. Finally, use
that
O
{\displaystyle O}
is a Dedekind domain and therefore each ideal can be written as a product of prime ideals. In other words, the map
(
⋅
)
{\displaystyle (\cdot )}
is a
K
×
{\displaystyle K^{\times }}
-equivariant group homomorphism. As a consequence, the map above induces a surjective homomorphism
{
ϕ
:
C
K
,
fin
→
Cl
K
α
K
×
↦
(
α
)
K
×
{\displaystyle {\begin{cases}\phi :C_{K,{\text{fin}}}\to \operatorname {Cl} _{K}\\\alpha K^{\times }\mapsto (\alpha )K^{\times }\end{cases}}}
To prove the second isomorphism, it has to be shown that
ker
(
ϕ
)
=
O
^
×
K
×
.
{\displaystyle \ker(\phi )={\widehat {O}}^{\times }K^{\times }.}
Consider
ξ
=
(
ξ
v
)
v
∈
O
^
×
.
{\displaystyle \xi =(\xi _{v})_{v}\in {\widehat {O}}^{\times }.}
Then
ϕ
(
ξ
K
×
)
=
∏
v
p
v
v
(
ξ
v
)
K
×
=
K
×
,
{\displaystyle \textstyle \phi (\xi K^{\times })=\prod _{v}{\mathfrak {p}}_{v}^{v(\xi _{v})}K^{\times }=K^{\times },}
because
v
(
ξ
v
)
=
0
{\displaystyle v(\xi _{v})=0}
for all
v
.
{\displaystyle v.}
On the other hand, consider
ξ
K
×
∈
C
K
,
fin
{\displaystyle \xi K^{\times }\in C_{K,{\text{fin}}}}
with
ϕ
(
ξ
K
×
)
=
O
K
×
,
{\displaystyle \phi (\xi K^{\times })=OK^{\times },}
which allows to write
∏
v
p
v
v
(
ξ
v
)
K
×
=
O
K
×
.
{\displaystyle \textstyle \prod _{v}{\mathfrak {p}}_{v}^{v(\xi _{v})}K^{\times }=OK^{\times }.}
As a consequence, there exists a representative, such that:
∏
v
p
v
v
(
ξ
v
′
)
=
O
.
{\displaystyle \textstyle \prod _{v}{\mathfrak {p}}_{v}^{v(\xi '_{v})}=O.}
Consequently,
ξ
′
∈
O
^
×
{\displaystyle \xi '\in {\widehat {O}}^{\times }}
and therefore
ξ
K
×
=
ξ
′
K
×
∈
O
^
×
K
×
.
{\displaystyle \xi K^{\times }=\xi 'K^{\times }\in {\widehat {O}}^{\times }K^{\times }.}
The second isomorphism of the theorem has been proven.
For the last isomorphism note that
ϕ
{\displaystyle \phi }
induces a surjective group homomorphism
ϕ
~
:
C
K
→
Cl
K
{\displaystyle {\widetilde {\phi }}:C_{K}\to \operatorname {Cl} _{K}}
with
ker
(
ϕ
~
)
=
(
O
^
×
×
∏
v
|
∞
K
v
×
)
K
×
.
{\displaystyle \ker({\widetilde {\phi }})=\left({\widehat {O}}^{\times }\times \prod _{v|\infty }K_{v}^{\times }\right)K^{\times }.}
Remark. Consider
I
K
,
fin
{\displaystyle I_{K,{\text{fin}}}}
with the idele topology and equip
J
K
,
{\displaystyle J_{K},}
with the discrete topology. Since
(
{
a
}
)
−
1
{\displaystyle (\{{\mathfrak {a}}\})^{-1}}
is open for each
a
∈
J
K
,
(
⋅
)
{\displaystyle {\mathfrak {a}}\in J_{K},(\cdot )}
is continuous. It stands, that
(
{
a
}
)
−
1
=
α
O
^
×
{\displaystyle (\{{\mathfrak {a}}\})^{-1}=\alpha {\widehat {O}}^{\times }}
is open, where
α
=
(
α
v
)
v
∈
A
K
,
fin
,
{\displaystyle \alpha =(\alpha _{v})_{v}\in \mathbb {A} _{K,{\text{fin}}},}
so that
a
=
∏
v
p
v
v
(
α
v
)
.
{\displaystyle \textstyle {\mathfrak {a}}=\prod _{v}{\mathfrak {p}}_{v}^{v(\alpha _{v})}.}
Decomposition of the idele group and idele class group of K
Theorem.
I
K
≅
I
K
1
×
M
:
{
M
⊂
I
K
discrete and
M
≅
Z
char
(
K
)
>
0
M
⊂
I
K
closed and
M
≅
R
+
char
(
K
)
=
0
C
K
≅
I
K
1
/
K
×
×
N
:
{
N
=
Z
char
(
K
)
>
0
N
=
R
+
char
(
K
)
=
0
{\displaystyle {\begin{aligned}I_{K}&\cong I_{K}^{1}\times M:\quad {\begin{cases}M\subset I_{K}{\text{ discrete and }}M\cong \mathbb {Z} &\operatorname {char} (K)>0\\M\subset I_{K}{\text{ closed and }}M\cong \mathbb {R} _{+}&\operatorname {char} (K)=0\end{cases}}\\C_{K}&\cong I_{K}^{1}/K^{\times }\times N:\quad {\begin{cases}N=\mathbb {Z} &\operatorname {char} (K)>0\\N=\mathbb {R} _{+}&\operatorname {char} (K)=0\end{cases}}\end{aligned}}}
Proof.
char
(
K
)
=
p
>
0.
{\displaystyle \operatorname {char} (K)=p>0.}
For each place
v
{\displaystyle v}
of
K
,
char
(
K
v
)
=
p
,
{\displaystyle K,\operatorname {char} (K_{v})=p,}
so that for all
x
∈
K
v
×
,
{\displaystyle x\in K_{v}^{\times },}
|
x
|
v
{\displaystyle |x|_{v}}
belongs to the subgroup of
R
+
,
{\displaystyle \mathbb {R} _{+},}
generated by
p
.
{\displaystyle p.}
Therefore for each
z
∈
I
K
,
{\displaystyle z\in I_{K},}
|
z
|
{\displaystyle |z|}
is in the subgroup of
R
+
,
{\displaystyle \mathbb {R} _{+},}
generated by
p
.
{\displaystyle p.}
Therefore the image of the homomorphism
z
↦
|
z
|
{\displaystyle z\mapsto |z|}
is a discrete subgroup of
R
+
,
{\displaystyle \mathbb {R} _{+},}
generated by
p
.
{\displaystyle p.}
Since this group is non-trivial, it is generated by
Q
=
p
m
{\displaystyle Q=p^{m}}
for some
m
∈
N
.
{\displaystyle m\in \mathbb {N} .}
Choose
z
1
∈
I
K
,
{\displaystyle z_{1}\in I_{K},}
so that
|
z
1
|
=
Q
,
{\displaystyle |z_{1}|=Q,}
then
I
K
{\displaystyle I_{K}}
is the direct product of
I
K
1
{\displaystyle I_{K}^{1}}
and the subgroup generated by
z
1
.
{\displaystyle z_{1}.}
This subgroup is discrete and isomorphic to
Z
.
{\displaystyle \mathbb {Z} .}
char
(
K
)
=
0.
{\displaystyle \operatorname {char} (K)=0.}
For
λ
∈
R
+
{\displaystyle \lambda \in \mathbb {R} _{+}}
define:
z
(
λ
)
=
(
z
v
)
v
,
z
v
=
{
1
v
∉
P
∞
λ
v
∈
P
∞
{\displaystyle z(\lambda )=(z_{v})_{v},\quad z_{v}={\begin{cases}1&v\notin P_{\infty }\\\lambda &v\in P_{\infty }\end{cases}}}
The map
λ
↦
z
(
λ
)
{\displaystyle \lambda \mapsto z(\lambda )}
is an isomorphism of
R
+
{\displaystyle \mathbb {R} _{+}}
in a closed subgroup
M
{\displaystyle M}
of
I
K
{\displaystyle I_{K}}
and
I
K
≅
M
×
I
K
1
.
{\displaystyle I_{K}\cong M\times I_{K}^{1}.}
The isomorphism is given by multiplication:
{
ϕ
:
M
×
I
K
1
→
I
K
,
(
(
α
v
)
v
,
(
β
v
)
v
)
↦
(
α
v
β
v
)
v
{\displaystyle {\begin{cases}\phi :M\times I_{K}^{1}\to I_{K},\\((\alpha _{v})_{v},(\beta _{v})_{v})\mapsto (\alpha _{v}\beta _{v})_{v}\end{cases}}}
Obviously,
ϕ
{\displaystyle \phi }
is a homomorphism. To show it is injective, let
(
α
v
β
v
)
v
=
1.
{\displaystyle (\alpha _{v}\beta _{v})_{v}=1.}
Since
α
v
=
1
{\displaystyle \alpha _{v}=1}
for
v
<
∞
,
{\displaystyle v<\infty ,}
it stands that
β
v
=
1
{\displaystyle \beta _{v}=1}
for
v
<
∞
.
{\displaystyle v<\infty .}
Moreover, it exists a
λ
∈
R
+
,
{\displaystyle \lambda \in \mathbb {R} _{+},}
so that
α
v
=
λ
{\displaystyle \alpha _{v}=\lambda }
for
v
|
∞
.
{\displaystyle v|\infty .}
Therefore,
β
v
=
λ
−
1
{\displaystyle \beta _{v}=\lambda ^{-1}}
for
v
|
∞
.
{\displaystyle v|\infty .}
Moreover
∏
v
|
β
v
|
v
=
1
,
{\displaystyle \textstyle \prod _{v}|\beta _{v}|_{v}=1,}
implies
λ
n
=
1
,
{\displaystyle \lambda ^{n}=1,}
where
n
{\displaystyle n}
is the number of infinite places of
K
.
{\displaystyle K.}
As a consequence
λ
=
1
{\displaystyle \lambda =1}
and therefore
ϕ
{\displaystyle \phi }
is injective. To show surjectivity, let
γ
=
(
γ
v
)
v
∈
I
K
.
{\displaystyle \gamma =(\gamma _{v})_{v}\in I_{K}.}
It is defined that
λ
:=
|
γ
|
1
n
{\displaystyle \lambda :=|\gamma |^{\frac {1}{n}}}
and furthermore,
α
v
=
1
{\displaystyle \alpha _{v}=1}
for
v
<
∞
{\displaystyle v<\infty }
and
α
v
=
λ
{\displaystyle \alpha _{v}=\lambda }
for
v
|
∞
.
{\displaystyle v|\infty .}
Define
β
=
γ
α
.
{\displaystyle \textstyle \beta ={\frac {\gamma }{\alpha }}.}
It stands, that
|
β
|
=
|
γ
|
|
α
|
=
λ
n
λ
n
=
1.
{\displaystyle \textstyle |\beta |={\frac {|\gamma |}{|\alpha |}}={\frac {\lambda ^{n}}{\lambda ^{n}}}=1.}
Therefore,
ϕ
{\displaystyle \phi }
is surjective.
The other equations follow similarly.
Characterisation of the idele group
Theorem. Let
K
{\displaystyle K}
be a number field. There exists a finite set of places
S
,
{\displaystyle S,}
such that:
I
K
=
(
I
K
,
S
×
∏
v
∉
S
O
v
×
)
K
×
=
(
∏
v
∈
S
K
v
×
×
∏
v
∉
S
O
v
×
)
K
×
.
{\displaystyle I_{K}=\left(I_{K,S}\times \prod _{v\notin S}O_{v}^{\times }\right)K^{\times }=\left(\prod _{v\in S}K_{v}^{\times }\times \prod _{v\notin S}O_{v}^{\times }\right)K^{\times }.}
Proof. The class number of a number field is finite so let
a
1
,
…
,
a
h
{\displaystyle {\mathfrak {a}}_{1},\ldots ,{\mathfrak {a}}_{h}}
be the ideals, representing the classes in
Cl
K
.
{\displaystyle \operatorname {Cl} _{K}.}
These ideals are generated by a finite number of prime ideals
p
1
,
…
,
p
n
.
{\displaystyle {\mathfrak {p}}_{1},\ldots ,{\mathfrak {p}}_{n}.}
Let
S
{\displaystyle S}
be a finite set of places containing
P
∞
{\displaystyle P_{\infty }}
and the finite places corresponding to
p
1
,
…
,
p
n
.
{\displaystyle {\mathfrak {p}}_{1},\ldots ,{\mathfrak {p}}_{n}.}
Consider the isomorphism:
I
K
/
(
∏
v
<
∞
O
v
×
×
∏
v
|
∞
K
v
×
)
≅
J
K
,
{\displaystyle I_{K}/\left(\prod _{v<\infty }O_{v}^{\times }\times \prod _{v|\infty }K_{v}^{\times }\right)\cong J_{K},}
induced by
(
α
v
)
v
↦
∏
v
<
∞
p
v
v
(
α
v
)
.
{\displaystyle (\alpha _{v})_{v}\mapsto \prod _{v<\infty }{\mathfrak {p}}_{v}^{v(\alpha _{v})}.}
At infinite places the statement is immediate, so the statement has been proved for finite places. The inclusion ″
⊃
{\displaystyle \supset }
″ is obvious. Let
α
∈
I
K
,
fin
.
{\displaystyle \alpha \in I_{K,{\text{fin}}}.}
The corresponding ideal
(
α
)
=
∏
v
<
∞
p
v
v
(
α
v
)
{\displaystyle \textstyle (\alpha )=\prod _{v<\infty }{\mathfrak {p}}_{v}^{v(\alpha _{v})}}
belongs to a class
a
i
K
×
,
{\displaystyle {\mathfrak {a}}_{i}K^{\times },}
meaning
(
α
)
=
a
i
(
a
)
{\displaystyle (\alpha )={\mathfrak {a}}_{i}(a)}
for a principal ideal
(
a
)
.
{\displaystyle (a).}
The idele
α
′
=
α
a
−
1
{\displaystyle \alpha '=\alpha a^{-1}}
maps to the ideal
a
i
{\displaystyle {\mathfrak {a}}_{i}}
under the map
I
K
,
fin
→
J
K
.
{\displaystyle I_{K,{\text{fin}}}\to J_{K}.}
That means
a
i
=
∏
v
<
∞
p
v
v
(
α
v
′
)
.
{\displaystyle \textstyle {\mathfrak {a}}_{i}=\prod _{v<\infty }{\mathfrak {p}}_{v}^{v(\alpha '_{v})}.}
Since the prime ideals in
a
i
{\displaystyle {\mathfrak {a}}_{i}}
are in
S
,
{\displaystyle S,}
it follows
v
(
α
v
′
)
=
0
{\displaystyle v(\alpha '_{v})=0}
for all
v
∉
S
,
{\displaystyle v\notin S,}
that means
α
v
′
∈
O
v
×
{\displaystyle \alpha '_{v}\in O_{v}^{\times }}
for all
v
∉
S
.
{\displaystyle v\notin S.}
It follows, that
α
′
=
α
a
−
1
∈
I
K
,
S
,
{\displaystyle \alpha '=\alpha a^{-1}\in I_{K,S},}
therefore
α
∈
I
K
,
S
K
×
.
{\displaystyle \alpha \in I_{K,S}K^{\times }.}
Applications
= Finiteness of the class number of a number field
=In the previous section the fact that the class number of a number field is finite had been used. Here this statement can be proved:
Theorem (finiteness of the class number of a number field). Let
K
{\displaystyle K}
be a number field. Then
|
Cl
K
|
<
∞
.
{\displaystyle |\operatorname {Cl} _{K}|<\infty .}
Proof. The map
{
I
K
1
→
J
K
(
(
α
v
)
v
<
∞
,
(
α
v
)
v
|
∞
)
↦
∏
v
<
∞
p
v
v
(
α
v
)
{\displaystyle {\begin{cases}I_{K}^{1}\to J_{K}\\\left((\alpha _{v})_{v<\infty },(\alpha _{v})_{v|\infty }\right)\mapsto \prod _{v<\infty }{\mathfrak {p}}_{v}^{v(\alpha _{v})}\end{cases}}}
is surjective and therefore
Cl
K
{\displaystyle \operatorname {Cl} _{K}}
is the continuous image of the compact set
I
K
1
/
K
×
.
{\displaystyle I_{K}^{1}/K^{\times }.}
Thus,
Cl
K
{\displaystyle \operatorname {Cl} _{K}}
is compact. In addition, it is discrete and so finite.
Remark. There is a similar result for the case of a global function field. In this case, the so-called divisor group is defined. It can be shown that the quotient of the set of all divisors of degree
0
{\displaystyle 0}
by the set of the principal divisors is a finite group.
= Group of units and Dirichlet's unit theorem
=Let
P
⊃
P
∞
{\displaystyle P\supset P_{\infty }}
be a finite set of places. Define
Ω
(
P
)
:=
∏
v
∈
P
K
v
×
×
∏
v
∉
P
O
v
×
=
(
A
K
(
P
)
)
×
E
(
P
)
:=
K
×
∩
Ω
(
P
)
{\displaystyle {\begin{aligned}\Omega (P)&:=\prod _{v\in P}K_{v}^{\times }\times \prod _{v\notin P}O_{v}^{\times }=(\mathbb {A} _{K}(P))^{\times }\\E(P)&:=K^{\times }\cap \Omega (P)\end{aligned}}}
Then
E
(
P
)
{\displaystyle E(P)}
is a subgroup of
K
×
,
{\displaystyle K^{\times },}
containing all elements
ξ
∈
K
×
{\displaystyle \xi \in K^{\times }}
satisfying
v
(
ξ
)
=
0
{\displaystyle v(\xi )=0}
for all
v
∉
P
.
{\displaystyle v\notin P.}
Since
K
×
{\displaystyle K^{\times }}
is discrete in
I
K
,
{\displaystyle I_{K},}
E
(
P
)
{\displaystyle E(P)}
is a discrete subgroup of
Ω
(
P
)
{\displaystyle \Omega (P)}
and with the same argument,
E
(
P
)
{\displaystyle E(P)}
is discrete in
Ω
1
(
P
)
:=
Ω
(
P
)
∩
I
K
1
.
{\displaystyle \Omega _{1}(P):=\Omega (P)\cap I_{K}^{1}.}
An alternative definition is:
E
(
P
)
=
K
(
P
)
×
,
{\displaystyle E(P)=K(P)^{\times },}
where
K
(
P
)
{\displaystyle K(P)}
is a subring of
K
{\displaystyle K}
defined by
K
(
P
)
:=
K
∩
(
∏
v
∈
P
K
v
×
∏
v
∉
P
O
v
)
.
{\displaystyle K(P):=K\cap \left(\prod _{v\in P}K_{v}\times \prod _{v\notin P}O_{v}\right).}
As a consequence,
K
(
P
)
{\displaystyle K(P)}
contains all elements
ξ
∈
K
,
{\displaystyle \xi \in K,}
which fulfil
v
(
ξ
)
≥
0
{\displaystyle v(\xi )\geq 0}
for all
v
∉
P
.
{\displaystyle v\notin P.}
Lemma 1. Let
0
<
c
≤
C
<
∞
.
{\displaystyle 0
The following set is finite:
{
η
∈
E
(
P
)
:
{
|
η
v
|
v
=
1
∀
v
∉
P
c
≤
|
η
v
|
v
≤
C
∀
v
∈
P
}
}
.
{\displaystyle \left\{\eta \in E(P):\left.{\begin{cases}|\eta _{v}|_{v}=1&\forall v\notin P\\c\leq |\eta _{v}|_{v}\leq C&\forall v\in P\end{cases}}\right\}\right\}.}
Proof. Define
W
:=
{
(
α
v
)
v
:
{
|
α
v
|
v
=
1
∀
v
∉
P
c
≤
|
α
v
|
v
≤
C
∀
v
∈
P
}
}
.
{\displaystyle W:=\left\{(\alpha _{v})_{v}:\left.{\begin{cases}|\alpha _{v}|_{v}=1&\forall v\notin P\\c\leq |\alpha _{v}|_{v}\leq C&\forall v\in P\end{cases}}\right\}\right\}.}
W
{\displaystyle W}
is compact and the set described above is the intersection of
W
{\displaystyle W}
with the discrete subgroup
K
×
{\displaystyle K^{\times }}
in
I
K
{\displaystyle I_{K}}
and therefore finite.
Lemma 2. Let
E
{\displaystyle E}
be set of all
ξ
∈
K
{\displaystyle \xi \in K}
such that
|
ξ
|
v
=
1
{\displaystyle |\xi |_{v}=1}
for all
v
.
{\displaystyle v.}
Then
E
=
μ
(
K
)
,
{\displaystyle E=\mu (K),}
the group of all roots of unity of
K
.
{\displaystyle K.}
In particular it is finite and cyclic.
Proof. All roots of unity of
K
{\displaystyle K}
have absolute value
1
{\displaystyle 1}
so
μ
(
K
)
⊂
E
.
{\displaystyle \mu (K)\subset E.}
For converse note that Lemma 1 with
c
=
C
=
1
{\displaystyle c=C=1}
and any
P
{\displaystyle P}
implies
E
{\displaystyle E}
is finite. Moreover
E
⊂
E
(
P
)
{\displaystyle E\subset E(P)}
for each finite set of places
P
⊃
P
∞
.
{\displaystyle P\supset P_{\infty }.}
Finally suppose there exists
ξ
∈
E
,
{\displaystyle \xi \in E,}
which is not a root of unity of
K
.
{\displaystyle K.}
Then
ξ
n
≠
1
{\displaystyle \xi ^{n}\neq 1}
for all
n
∈
N
{\displaystyle n\in \mathbb {N} }
contradicting the finiteness of
E
.
{\displaystyle E.}
Unit Theorem.
E
(
P
)
{\displaystyle E(P)}
is the direct product of
E
{\displaystyle E}
and a group isomorphic to
Z
s
,
{\displaystyle \mathbb {Z} ^{s},}
where
s
=
0
,
{\displaystyle s=0,}
if
P
=
∅
{\displaystyle P=\emptyset }
and
s
=
|
P
|
−
1
,
{\displaystyle s=|P|-1,}
if
P
≠
∅
.
{\displaystyle P\neq \emptyset .}
Dirichlet's Unit Theorem. Let
K
{\displaystyle K}
be a number field. Then
O
×
≅
μ
(
K
)
×
Z
r
+
s
−
1
,
{\displaystyle O^{\times }\cong \mu (K)\times \mathbb {Z} ^{r+s-1},}
where
μ
(
K
)
{\displaystyle \mu (K)}
is the finite cyclic group of all roots of unity of
K
,
r
{\displaystyle K,r}
is the number of real embeddings of
K
{\displaystyle K}
and
s
{\displaystyle s}
is the number of conjugate pairs of complex embeddings of
K
.
{\displaystyle K.}
It stands, that
[
K
:
Q
]
=
r
+
2
s
.
{\displaystyle [K:\mathbb {Q} ]=r+2s.}
Remark. The Unit Theorem generalises Dirichlet's Unit Theorem. To see this, let
K
{\displaystyle K}
be a number field. It is already known that
E
=
μ
(
K
)
,
{\displaystyle E=\mu (K),}
set
P
=
P
∞
{\displaystyle P=P_{\infty }}
and note
|
P
∞
|
=
r
+
s
.
{\displaystyle |P_{\infty }|=r+s.}
Then there is:
E
×
Z
r
+
s
−
1
=
E
(
P
∞
)
=
K
×
∩
(
∏
v
|
∞
K
v
×
×
∏
v
<
∞
O
v
×
)
≅
K
×
∩
(
∏
v
<
∞
O
v
×
)
≅
O
×
{\displaystyle {\begin{aligned}E\times \mathbb {Z} ^{r+s-1}=E(P_{\infty })&=K^{\times }\cap \left(\prod _{v|\infty }K_{v}^{\times }\times \prod _{v<\infty }O_{v}^{\times }\right)\\&\cong K^{\times }\cap \left(\prod _{v<\infty }O_{v}^{\times }\right)\\&\cong O^{\times }\end{aligned}}}
= Approximation theorems
=Weak Approximation Theorem. Let
|
⋅
|
1
,
…
,
|
⋅
|
N
,
{\displaystyle |\cdot |_{1},\ldots ,|\cdot |_{N},}
be inequivalent valuations of
K
.
{\displaystyle K.}
Let
K
n
{\displaystyle K_{n}}
be the completion of
K
{\displaystyle K}
with respect to
|
⋅
|
n
.
{\displaystyle |\cdot |_{n}.}
Embed
K
{\displaystyle K}
diagonally in
K
1
×
⋯
×
K
N
.
{\displaystyle K_{1}\times \cdots \times K_{N}.}
Then
K
{\displaystyle K}
is everywhere dense in
K
1
×
⋯
×
K
N
.
{\displaystyle K_{1}\times \cdots \times K_{N}.}
In other words, for each
ε
>
0
{\displaystyle \varepsilon >0}
and for each
(
α
1
,
…
,
α
N
)
∈
K
1
×
⋯
×
K
N
,
{\displaystyle (\alpha _{1},\ldots ,\alpha _{N})\in K_{1}\times \cdots \times K_{N},}
there exists
ξ
∈
K
,
{\displaystyle \xi \in K,}
such that:
∀
n
∈
{
1
,
…
,
N
}
:
|
α
n
−
ξ
|
n
<
ε
.
{\displaystyle \forall n\in \{1,\ldots ,N\}:\quad |\alpha _{n}-\xi |_{n}<\varepsilon .}
Strong Approximation Theorem. Let
v
0
{\displaystyle v_{0}}
be a place of
K
.
{\displaystyle K.}
Define
V
:=
∏
v
≠
v
0
′
K
v
.
{\displaystyle V:={\prod _{v\neq v_{0}}}^{'}K_{v}.}
Then
K
{\displaystyle K}
is dense in
V
.
{\displaystyle V.}
Remark. The global field is discrete in its adele ring. The strong approximation theorem tells us that, if one place (or more) is omitted, the property of discreteness of
K
{\displaystyle K}
is turned into a denseness of
K
.
{\displaystyle K.}
= Hasse principle
=Hasse-Minkowski Theorem. A quadratic form on
K
{\displaystyle K}
is zero, if and only if, the quadratic form is zero in each completion
K
v
.
{\displaystyle K_{v}.}
Remark. This is the Hasse principle for quadratic forms. For polynomials of degree larger than 2 the Hasse principle isn't valid in general. The idea of the Hasse principle (also known as local–global principle) is to solve a given problem of a number field
K
{\displaystyle K}
by doing so in its completions
K
v
{\displaystyle K_{v}}
and then concluding on a solution in
K
.
{\displaystyle K.}
= Characters on the adele ring
=Definition. Let
G
{\displaystyle G}
be a locally compact abelian group. The character group of
G
{\displaystyle G}
is the set of all characters of
G
{\displaystyle G}
and is denoted by
G
^
.
{\displaystyle {\widehat {G}}.}
Equivalently
G
^
{\displaystyle {\widehat {G}}}
is the set of all continuous group homomorphisms from
G
{\displaystyle G}
to
T
:=
{
z
∈
C
:
|
z
|
=
1
}
.
{\displaystyle \mathbb {T} :=\{z\in \mathbb {C} :|z|=1\}.}
Equip
G
^
{\displaystyle {\widehat {G}}}
with the topology of uniform convergence on compact subsets of
G
.
{\displaystyle G.}
One can show that
G
^
{\displaystyle {\widehat {G}}}
is also a locally compact abelian group.
Theorem. The adele ring is self-dual:
A
K
≅
A
K
^
.
{\displaystyle \mathbb {A} _{K}\cong {\widehat {\mathbb {A} _{K}}}.}
Proof. By reduction to local coordinates, it is sufficient to show each
K
v
{\displaystyle K_{v}}
is self-dual. This can be done by using a fixed character of
K
v
.
{\displaystyle K_{v}.}
The idea has been illustrated by showing
R
{\displaystyle \mathbb {R} }
is self-dual. Define:
{
e
∞
:
R
→
T
e
∞
(
t
)
:=
exp
(
2
π
i
t
)
{\displaystyle {\begin{cases}e_{\infty }:\mathbb {R} \to \mathbb {T} \\e_{\infty }(t):=\exp(2\pi it)\end{cases}}}
Then the following map is an isomorphism which respects topologies:
{
ϕ
:
R
→
R
^
s
↦
{
ϕ
s
:
R
→
T
ϕ
s
(
t
)
:=
e
∞
(
t
s
)
{\displaystyle {\begin{cases}\phi :\mathbb {R} \to {\widehat {\mathbb {R} }}\\s\mapsto {\begin{cases}\phi _{s}:\mathbb {R} \to \mathbb {T} \\\phi _{s}(t):=e_{\infty }(ts)\end{cases}}\end{cases}}}
Theorem (algebraic and continuous duals of the adele ring). Let
χ
{\displaystyle \chi }
be a non-trivial character of
A
K
,
{\displaystyle \mathbb {A} _{K},}
which is trivial on
K
.
{\displaystyle K.}
Let
E
{\displaystyle E}
be a finite-dimensional vector-space over
K
.
{\displaystyle K.}
Let
E
⋆
{\displaystyle E^{\star }}
and
A
E
⋆
{\displaystyle \mathbb {A} _{E}^{\star }}
be the algebraic duals of
E
{\displaystyle E}
and
A
E
.
{\displaystyle \mathbb {A} _{E}.}
Denote the topological dual of
A
E
{\displaystyle \mathbb {A} _{E}}
by
A
E
′
{\displaystyle \mathbb {A} _{E}'}
and use
⟨
⋅
,
⋅
⟩
{\displaystyle \langle \cdot ,\cdot \rangle }
and
[
⋅
,
⋅
]
{\displaystyle [{\cdot },{\cdot }]}
to indicate the natural bilinear pairings on
A
E
×
A
E
′
{\displaystyle \mathbb {A} _{E}\times \mathbb {A} _{E}'}
and
A
E
×
A
E
⋆
.
{\displaystyle \mathbb {A} _{E}\times \mathbb {A} _{E}^{\star }.}
Then the formula
⟨
e
,
e
′
⟩
=
χ
(
[
e
,
e
⋆
]
)
{\displaystyle \langle e,e'\rangle =\chi ([e,e^{\star }])}
for all
e
∈
A
E
{\displaystyle e\in \mathbb {A} _{E}}
determines an isomorphism
e
⋆
↦
e
′
{\displaystyle e^{\star }\mapsto e'}
of
A
E
⋆
{\displaystyle \mathbb {A} _{E}^{\star }}
onto
A
E
′
,
{\displaystyle \mathbb {A} _{E}',}
where
e
′
∈
A
E
′
{\displaystyle e'\in \mathbb {A} _{E}'}
and
e
⋆
∈
A
E
⋆
.
{\displaystyle e^{\star }\in \mathbb {A} _{E}^{\star }.}
Moreover, if
e
⋆
∈
A
E
⋆
{\displaystyle e^{\star }\in \mathbb {A} _{E}^{\star }}
fulfils
χ
(
[
e
,
e
⋆
]
)
=
1
{\displaystyle \chi ([e,e^{\star }])=1}
for all
e
∈
E
,
{\displaystyle e\in E,}
then
e
⋆
∈
E
⋆
.
{\displaystyle e^{\star }\in E^{\star }.}
= Tate's thesis
=With the help of the characters of
A
K
,
{\displaystyle \mathbb {A} _{K},}
Fourier analysis can be done on the adele ring. John Tate in his thesis "Fourier analysis in Number Fields and Hecke Zeta Functions" proved results about Dirichlet L-functions using Fourier analysis on the adele ring and the idele group. Therefore, the adele ring and the idele group have been applied to study the Riemann zeta function and more general zeta functions and the L-functions. Adelic forms of these functions can be defined and represented as integrals over the adele ring or the idele group, with respect to corresponding Haar measures. Functional equations and meromorphic continuations of these functions can be shown. For example, for all
s
∈
C
{\displaystyle s\in \mathbb {C} }
with
ℜ
(
s
)
>
1
,
{\displaystyle \Re (s)>1,}
∫
Z
^
|
x
|
s
d
×
x
=
ζ
(
s
)
,
{\displaystyle \int _{\widehat {\mathbb {Z} }}|x|^{s}d^{\times }x=\zeta (s),}
where
d
×
x
{\displaystyle d^{\times }x}
is the unique Haar measure on
I
Q
,
fin
{\displaystyle I_{\mathbb {Q} ,{\text{fin}}}}
normalised such that
Z
^
×
{\displaystyle {\widehat {\mathbb {Z} }}^{\times }}
has volume one and is extended by zero to the finite adele ring. As a result, the Riemann zeta function can be written as an integral over (a subset of) the adele ring.
= Automorphic forms
=The theory of automorphic forms is a generalisation of Tate's thesis by replacing the idele group with analogous higher dimensional groups. To see this note:
I
Q
=
GL
(
1
,
A
Q
)
I
Q
1
=
(
GL
(
1
,
A
Q
)
)
1
:=
{
x
∈
GL
(
1
,
A
Q
)
:
|
x
|
=
1
}
Q
×
=
GL
(
1
,
Q
)
{\displaystyle {\begin{aligned}I_{\mathbb {Q} }&=\operatorname {GL} (1,\mathbb {A} _{\mathbb {Q} })\\I_{\mathbb {Q} }^{1}&=(\operatorname {GL} (1,\mathbb {A} _{\mathbb {Q} }))^{1}:=\{x\in \operatorname {GL} (1,\mathbb {A} _{\mathbb {Q} }):|x|=1\}\\\mathbb {Q} ^{\times }&=\operatorname {GL} (1,\mathbb {Q} )\end{aligned}}}
Based on these identification a natural generalisation would be to replace the idele group and the 1-idele with:
I
Q
↭
GL
(
2
,
A
Q
)
I
Q
1
↭
(
GL
(
2
,
A
Q
)
)
1
:=
{
x
∈
GL
(
2
,
A
Q
)
:
|
det
(
x
)
|
=
1
}
Q
↭
GL
(
2
,
Q
)
{\displaystyle {\begin{aligned}I_{\mathbb {Q} }&\leftrightsquigarrow \operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} })\\I_{\mathbb {Q} }^{1}&\leftrightsquigarrow (\operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} }))^{1}:=\{x\in \operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} }):|\det(x)|=1\}\\\mathbb {Q} &\leftrightsquigarrow \operatorname {GL} (2,\mathbb {Q} )\end{aligned}}}
And finally
Q
×
∖
I
Q
1
≅
Q
×
∖
I
Q
↭
(
GL
(
2
,
Q
)
∖
(
GL
(
2
,
A
Q
)
)
1
≅
(
GL
(
2
,
Q
)
Z
R
)
∖
GL
(
2
,
A
Q
)
,
{\displaystyle \mathbb {Q} ^{\times }\backslash I_{\mathbb {Q} }^{1}\cong \mathbb {Q} ^{\times }\backslash I_{\mathbb {Q} }\leftrightsquigarrow (\operatorname {GL} (2,\mathbb {Q} )\backslash (\operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} }))^{1}\cong (\operatorname {GL} (2,\mathbb {Q} )Z_{\mathbb {R} })\backslash \operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} }),}
where
Z
R
{\displaystyle Z_{\mathbb {R} }}
is the centre of
GL
(
2
,
R
)
.
{\displaystyle \operatorname {GL} (2,\mathbb {R} ).}
Then it define an automorphic form as an element of
L
2
(
(
GL
(
2
,
Q
)
Z
R
)
∖
GL
(
2
,
A
Q
)
)
.
{\displaystyle L^{2}((\operatorname {GL} (2,\mathbb {Q} )Z_{\mathbb {R} })\backslash \operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} })).}
In other words an automorphic form is a function on
GL
(
2
,
A
Q
)
{\displaystyle \operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} })}
satisfying certain algebraic and analytic conditions. For studying automorphic forms, it is important to know the representations of the group
GL
(
2
,
A
Q
)
.
{\displaystyle \operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} }).}
It is also possible to study automorphic L-functions, which can be described as integrals over
GL
(
2
,
A
Q
)
.
{\displaystyle \operatorname {GL} (2,\mathbb {A} _{\mathbb {Q} }).}
Generalise even further is possible by replacing
Q
{\displaystyle \mathbb {Q} }
with a number field and
GL
(
2
)
{\displaystyle \operatorname {GL} (2)}
with an arbitrary reductive algebraic group.
= Further applications
=A generalisation of Artin reciprocity law leads to the connection of representations of
GL
(
2
,
A
K
)
{\displaystyle \operatorname {GL} (2,\mathbb {A} _{K})}
and of Galois representations of
K
{\displaystyle K}
(Langlands program).
The idele class group is a key object of class field theory, which describes abelian extensions of the field. The product of the local reciprocity maps in local class field theory gives a homomorphism of the idele group to the Galois group of the maximal abelian extension of the global field. The Artin reciprocity law, which is a sweeping generalisation of the Gauss quadratic reciprocity law, states that the product vanishes on the multiplicative group of the number field. Thus, the global reciprocity map of the idele class group to the abelian part of the absolute Galois group of the field will be obtained.
The self-duality of the adele ring of the function field of a curve over a finite field easily implies the Riemann–Roch theorem and the duality theory for the curve.
References
Sources
Cassels, John; Fröhlich, Albrecht (1967). Algebraic number theory: proceedings of an instructional conference, organized by the London Mathematical Society, (a NATO Advanced Study Institute). Vol. XVIII. London: Academic Press. ISBN 978-0-12-163251-9. 366 pages.
Neukirch, Jürgen (2007). Algebraische Zahlentheorie, unveränd. nachdruck der 1. aufl. edn (in German). Vol. XIII. Berlin: Springer. ISBN 9783540375470. 595 pages.
Weil, André (1967). Basic number theory. Vol. XVIII. Berlin; Heidelberg; New York: Springer. ISBN 978-3-662-00048-9. 294 pages.
Deitmar, Anton (2010). Automorphe Formen (in German). Vol. VIII. Berlin; Heidelberg (u.a.): Springer. ISBN 978-3-642-12389-4. 250 pages.
Lang, Serge (1994). Algebraic number theory, Graduate Texts in Mathematics 110 (2nd ed.). New York: Springer-Verlag. ISBN 978-0-387-94225-4.
External links
What problem do the adeles solve?
Some good books on adeles
Kata Kunci Pencarian:
- Crazy Rich Asians (film)
- Festival Film Cannes 2013
- Bring Me the Horizon
- The Next Boy/Girl Band (musim 2)
- Britney Spears
- DJ Earworm
- Lagu Terbaik (Critics' Choice Movie Award)
- Selena Gomez
- The Voice Kids Indonesia (musim 1)
- Céline Dion
- Adele ring
- Adelic algebraic group
- Topological ring
- Adele
- Tamagawa number
- Adele (disambiguation)
- Ring (mathematics)
- Restricted product
- Langlands program
- Algebraic number theory
No More Posts Available.
No more pages to load.