Rational adeles

For ${\displaystyle K=\mathbb {Q} }$, Ostrowski's theorem says that the places of ${\displaystyle \mathbb {Q} }$ are given by the usual absolute value and the ${\displaystyle p}$-adic absolute values, one for each prime number ${\displaystyle p}$. The completion at the infinite place is

${\displaystyle \mathbb {Q} _{\infty }=\mathbb {R} ,}$

and the completion at the place corresponding to ${\displaystyle p}$ is the field of ${\displaystyle p}$-adic numbers ${\displaystyle \mathbb {Q} _{p}}$, with valuation ring ${\displaystyle \mathbb {Z} _{p}}$. Thus the adele ring of ${\displaystyle \mathbb {Q} }$ is

${\displaystyle \mathbb {A} _{\mathbb {Q} }=\mathbb {R} \times \prod _{p}'\mathbb {Q} _{p},}$

where the restricted product is taken with respect to the subrings ${\displaystyle \mathbb {Z} _{p}}$. Equivalently,

${\displaystyle \mathbb {A} _{\mathbb {Q} }=\left\{(x_{\infty },x_{2},x_{3},x_{5},\ldots ):x_{\infty }\in \mathbb {R} ,\ x_{p}\in \mathbb {Q} _{p},\ x_{p}\in \mathbb {Z} _{p}{\text{ for all but finitely many }}p\right\}.}$

Thus an adele of ${\displaystyle \mathbb {Q} }$ is a real number together with a ${\displaystyle p}$-adic rational number for each prime ${\displaystyle p}$, such that all but finitely many of the ${\displaystyle p}$-adic components are ${\displaystyle p}$-adic integers.^[1][2]

The finite adeles of ${\displaystyle \mathbb {Q} }$ are

${\displaystyle \mathbb {A} _{\mathbb {Q} ,\mathrm {fin} }=\prod _{p}'\mathbb {Q} _{p}.}$

The integral finite adeles are

${\displaystyle {\widehat {\mathbb {Z} }}=\prod _{p}\mathbb {Z} _{p},}$

the ring of profinite integers. With this notation,

${\displaystyle \mathbb {A} _{\mathbb {Q} }=\mathbb {R} \times \mathbb {A} _{\mathbb {Q} ,\mathrm {fin} },\qquad {\widehat {\mathbb {Z} }}\subset \mathbb {A} _{\mathbb {Q} ,\mathrm {fin} }.}$

The diagonal embedding of ${\displaystyle \mathbb {Q} }$ sends a rational number ${\displaystyle a}$ to the adele

${\displaystyle (a,a,a,\ldots ).}$

This is well-defined because a rational number has only finitely many prime factors in its denominator, so ${\displaystyle a\in \mathbb {Z} _{p}}$ for all but finitely many primes ${\displaystyle p}$.

Number fields

Let ${\displaystyle K}$ be a number field with ring of integers ${\displaystyle {\mathcal {O}}_{K}}$. At each finite place ${\displaystyle v}$, the completion ${\displaystyle K_{v}}$ is a finite extension of some ${\displaystyle \mathbb {Q} _{p}}$, and its valuation ring is denoted ${\displaystyle {\mathcal {O}}_{v}}$. At each infinite place, the completion is isomorphic to either ${\displaystyle \mathbb {R} }$ or ${\displaystyle \mathbb {C} }$. The adele ring is

${\displaystyle \mathbb {A} _{K}=\prod _{v\nmid \infty }'K_{v}\times \prod _{v\mid \infty }K_{v},}$

where the restricted product over finite places is taken with respect to the rings ${\displaystyle {\mathcal {O}}_{v}}$. Thus an adele of ${\displaystyle K}$ is a family ${\displaystyle (x_{v})_{v}}$ with ${\displaystyle x_{v}\in K_{v}}$ for every place ${\displaystyle v}$, such that ${\displaystyle x_{v}\in {\mathcal {O}}_{v}}$ for all but finitely many finite places.

For example, if ${\displaystyle K}$ is a quadratic number field, then its archimedean factor is either ${\displaystyle \mathbb {R} ^{2}}$, when ${\displaystyle K}$ has two real embeddings, or ${\displaystyle \mathbb {C} }$, when ${\displaystyle K}$ has one pair of complex embeddings. The finite part is a restricted product over the nonzero prime ideals of ${\displaystyle {\mathcal {O}}_{K}}$.^[2][1]

If ${\displaystyle L/K}$ is a finite extension of number fields, then the adelic construction is compatible with extension of scalars. In particular, one has a natural isomorphism

${\displaystyle \mathbb {A} _{L}\cong \mathbb {A} _{K}\otimes _{K}L,}$

and, in the special case ${\displaystyle K=\mathbb {Q} }$,

${\displaystyle \mathbb {A} _{L}\cong \mathbb {A} _{\mathbb {Q} }\otimes _{\mathbb {Q} }L.}$

This gives another way to view the adele ring of a number field as the adelic extension of the rational adele ring.^[3][1]

Function fields and curves

Now take the function field

${\displaystyle K=\mathbb {F} _{q}(\mathbb {P} ^{1})=\mathbb {F} _{q}(t)}$

of the projective line over a finite field. Its places correspond to the closed points ${\displaystyle x}$ of ${\displaystyle X=\mathbb {P} ^{1}}$. Such points may be described as maps

${\displaystyle x:\operatorname {Spec} \mathbb {F} _{q^{n}}\longrightarrow \mathbb {P} ^{1}}$

over ${\displaystyle \operatorname {Spec} \mathbb {F} _{q}}$. For instance, there are ${\displaystyle q+1}$ points of the form

${\displaystyle \operatorname {Spec} \mathbb {F} _{q}\longrightarrow \mathbb {P} ^{1}.}$

For a point ${\displaystyle x}$, the local ring used in the restricted product is the completed local ring

${\displaystyle {\widehat {\mathcal {O}}}_{X,x},}$

and the corresponding local field is its fraction field, often denoted ${\displaystyle K_{X,x}}$. Thus the adele ring of ${\displaystyle \mathbb {F} _{q}(\mathbb {P} ^{1})}$ may be written

${\displaystyle \mathbb {A} _{\mathbb {F} _{q}(\mathbb {P} ^{1})}=\prod _{x\in X}'K_{X,x},}$

where the restricted product is taken with respect to the completed local rings ${\displaystyle {\widehat {\mathcal {O}}}_{X,x}}$. Equivalently, its elements are families ${\displaystyle (f_{x})_{x}}$, with ${\displaystyle f_{x}\in K_{X,x}}$, such that ${\displaystyle f_{x}\in {\widehat {\mathcal {O}}}_{X,x}}$ for all but finitely many points ${\displaystyle x}$.^[1]

The same description holds for any smooth proper curve ${\displaystyle X/\mathbb {F} _{q}}$ over a finite field. If ${\displaystyle K=\mathbb {F} _{q}(X)}$ is its function field, then

${\displaystyle \mathbb {A} _{K}=\prod _{x\in X}'K_{X,x},}$

where ${\displaystyle x}$ runs over the closed points of ${\displaystyle X}$. Unlike number fields, global function fields have no archimedean places, so the finite adele ring and the full adele ring are the same.

Class field theory

The adele ring enters class field theory through its group of units, the idele group ${\displaystyle \mathbb {A} _{K}^{\times }}$. The quotient

${\displaystyle C_{K}=\mathbb {A} _{K}^{\times }/K^{\times }}$

is the idele class group of ${\displaystyle K}$. Global class field theory describes the abelian extensions of ${\displaystyle K}$ in terms of topological quotients of ${\displaystyle C_{K}}$. In one formulation, the global Artin reciprocity law gives a reciprocity homomorphism from the idele class group to the Galois group of the maximal abelian extension of ${\displaystyle K}$. At finite level, for a finite abelian extension ${\displaystyle L/K}$, the corresponding quotient of ${\displaystyle C_{K}}$ is described using the norm subgroup from ${\displaystyle C_{L}}$.^[10][11]

This adelic formulation packages the local reciprocity maps of local class field theory into a global statement. It replaces the older ideal-theoretic formulation, involving ideal class groups and ray class groups, by a statement about the topology and quotients of the idele class group.

Ideal classes and units

The idele group gives a topological refinement of the group of fractional ideals of a number field. For a number field ${\displaystyle K}$, the finite part of the idele group maps onto the group of fractional ideals by

${\displaystyle (x_{\mathfrak {p}})_{\mathfrak {p}}\longmapsto \prod _{\mathfrak {p}}{\mathfrak {p}}^{v_{\mathfrak {p}}(x_{\mathfrak {p}})}.}$

The kernel is the product of the local unit groups. Consequently, the ordinary ideal class group can be recovered as a quotient of the idele class group. This viewpoint gives an adelic interpretation of the finiteness of the class number: the compactness of the norm-one idele classes implies that the ideal class group is compact, and since it is discrete, it is finite.^[3][1]

The same circle of ideas also gives an adelic formulation of the unit theorem. If ${\displaystyle P}$ is a finite set of places containing the archimedean places, the group of ${\displaystyle P}$-units appears as an intersection of ${\displaystyle K^{\times }}$ with a natural open subgroup of the idele group. In particular, for a number field ${\displaystyle K}$, Dirichlet's unit theorem states that

${\displaystyle {\mathcal {O}}_{K}^{\times }\cong \mu (K)\times \mathbb {Z} ^{r+s-1},}$

where ${\displaystyle \mu (K)}$ is the finite cyclic group of roots of unity in ${\displaystyle K}$, ${\displaystyle r}$ is the number of real embeddings, and ${\displaystyle s}$ is the number of conjugate pairs of complex embeddings.^[1][3]

Tate's thesis and L-functions

The topology on ${\displaystyle \mathbb {A} _{K}}$ makes the quotient ${\displaystyle \mathbb {A} _{K}/K}$ compact, allowing one to do harmonic analysis on the adele ring. With the help of the characters of ${\displaystyle \mathbb {A} _{K}}$, Fourier analysis can be done on the adele ring; integration over the idele group then gives zeta integrals.^[5][4]

In Tate's thesis, John Tate used Fourier analysis on the adele ring and the idele group to study the Riemann zeta function, Dirichlet ${\displaystyle L}$-functions, and more general Hecke ${\displaystyle L}$-functions. Adelic forms of these functions can be represented as integrals over the adele ring or the idele group, with respect to corresponding Haar measures. Their functional equations and meromorphic continuations can then be proved using Fourier analysis and Poisson summation in the adelic setting.^[5][12][6]

For example, for ${\displaystyle \operatorname {Re} (s)>1}$, one has an adelic integral representation of the Riemann zeta function,

${\displaystyle \int _{\widehat {\mathbb {Z} }}|x|^{s}\,d^{\times }x=\zeta (s),}$

where ${\displaystyle d^{\times }x}$ is the multiplicative Haar measure on the finite idele group ${\displaystyle I_{\mathbb {Q} ,\mathrm {fin} }}$, normalized so that ${\displaystyle {\widehat {\mathbb {Z} }}^{\times }}$ has volume ${\displaystyle 1}$, and extended by zero to the finite adele ring. Thus the Riemann zeta function can be written as an integral over a subset of the adele ring.

Automorphic forms

Adeles also provide the natural language for automorphic forms. Instead of studying functions separately over the real, complex, and ${\displaystyle p}$-adic points of an algebraic group, one studies functions on adelic groups such as ${\displaystyle G(\mathbb {A} _{K})}$. For example, automorphic forms for ${\displaystyle \operatorname {GL} _{2}}$ over ${\displaystyle \mathbb {Q} }$ may be viewed as functions on

${\displaystyle \operatorname {GL} _{2}(\mathbb {Q} )\backslash \operatorname {GL} _{2}(\mathbb {A} _{\mathbb {Q} })}$

satisfying suitable algebraic, analytic, and growth conditions. In this setting, automorphic ${\displaystyle L}$-functions can often be described by integrals over adelic groups.^[13][14]

More generally, the use of adelic points ${\displaystyle G(\mathbb {A} _{K})}$ for reductive algebraic groups ${\displaystyle G}$ is central in the modern theory of automorphic representations. This viewpoint is also one of the starting points of the Langlands program, which relates automorphic representations of adelic groups to Galois representations.^[13]

Approximation and local-global principles

The adele ring provides a unified interpretation of approximation theorems and local-global questions. The weak approximation theorem says that, for finitely many inequivalent valuations of ${\displaystyle K}$, the diagonal image of ${\displaystyle K}$ is dense in the product of the corresponding completions. The strong approximation theorem says that, after omitting one place ${\displaystyle v_{0}}$, the field ${\displaystyle K}$ is dense in the restricted product over all other places. Thus the global field is discrete in its full adele ring, but becomes dense when one place is omitted.^[3]

Adelic language is also used to formulate local-global principles, such as the Hasse principle. In such problems one compares solutions over the global field ${\displaystyle K}$ with compatible families of solutions over all completions ${\displaystyle K_{v}}$. The adele ring provides a single space in which these local conditions can be collected and studied together.

Curves, divisors, and bundles

For a smooth proper curve ${\displaystyle X/\mathbb {F} _{q}}$ with function field ${\displaystyle K}$, the adele ring of ${\displaystyle K}$ can be described using the completions at the closed points of ${\displaystyle X}$. In this setting, ideles recover the divisor and Picard groups of the curve. One has

${\displaystyle \operatorname {Div} (X)=\mathbb {A} _{X}^{\times }/\mathbb {O} _{X}^{\times }}$

and

${\displaystyle \operatorname {Pic} (X)=K^{\times }\backslash \mathbb {A} _{X}^{\times }/\mathbb {O} _{X}^{\times }.}$

Thus the divisor-class description of line bundles on a curve can be expressed adelically.

More generally, for an algebraic group ${\displaystyle G}$, adelic double quotients describe moduli of bundles on curves. In Weil uniformization, for suitable groups such as semisimple groups, and also for ${\displaystyle \operatorname {GL} _{n}}$, one has an adelic description of the form

${\displaystyle \operatorname {Bun} _{G}(X)=G(K)\backslash G(\mathbb {A} _{X})/G(\mathbb {O} _{X}).}$

For ${\displaystyle G=\mathbb {G} _{m}}$, this recovers the adelic description of the Picard group.

Serre duality on curves

Adeles also occur in the cohomology of algebraic curves. If ${\displaystyle X}$ is a smooth proper curve over the complex numbers, one can define the adeles of its function field ${\displaystyle \mathbb {C} (X)}$ in a way analogous to the function-field case over finite fields. Tate proved that Serre duality on ${\displaystyle X}$,

${\displaystyle H^{1}(X,{\mathcal {L}})\simeq H^{0}(X,\Omega _{X}\otimes {\mathcal {L}}^{-1})^{*},}$

can be deduced by working with this adele ring ${\displaystyle \mathbb {A} _{\mathbb {C} (X)}}$, where ${\displaystyle {\mathcal {L}}}$ is a line bundle on ${\displaystyle X}$.^[15]

Restricted product topology

The difference between the restricted and unrestricted product topologies can be illustrated using a sequence in ${\displaystyle \mathbb {A} _{\mathbb {Q} }}$.

Lemma. Consider the following sequence in ${\displaystyle \mathbb {A} _{\mathbb {Q} }}$:

${\displaystyle {\begin{aligned}x_{1}&=\left({\frac {1}{2}},1,1,\ldots \right)\\x_{2}&=\left(1,{\frac {1}{3}},1,\ldots \right)\\x_{3}&=\left(1,1,{\frac {1}{5}},1,\ldots \right)\\x_{4}&=\left(1,1,1,{\frac {1}{7}},1,\ldots \right)\\&\vdots \end{aligned}}}$

In the product topology this converges to ${\displaystyle (1,1,\ldots )}$, 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 does not converge in restricted product topology. For each adele ${\displaystyle a=(a_{p})_{p}\in \mathbb {A} _{\mathbb {Q} }}$ and for each restricted open rectangle ${\displaystyle \textstyle U=\prod _{p\in E}U_{p}\times \prod _{p\notin E}\mathbb {Z} _{p},}$ it has ${\displaystyle {\tfrac {1}{p}}-a_{p}\notin \mathbb {Z} _{p}}$ for ${\displaystyle a_{p}\in \mathbb {Z} _{p}}$ and therefore ${\displaystyle {\tfrac {1}{p}}-a_{p}\notin \mathbb {Z} _{p}}$ for all ${\displaystyle p\notin F.}$ As a result ${\displaystyle x_{n}-a\notin U}$ for almost all ${\displaystyle n\in \mathbb {N} .}$ In this consideration, ${\displaystyle E}$ and ${\displaystyle F}$ are finite subsets of the set of all places.

Alternative descriptions for number fields

The profinite integers are defined as the profinite completion of the rings ${\displaystyle \mathbb {Z} /n\mathbb {Z} }$ with the partial order ${\displaystyle n\geq m\Leftrightarrow m|n,}$ i.e.,

${\displaystyle {\widehat {\mathbb {Z} }}:=\varprojlim _{n}\mathbb {Z} /n\mathbb {Z} .}$

Lemma. ${\displaystyle \textstyle {\widehat {\mathbb {Z} }}\cong \prod _{p}\mathbb {Z} _{p}.}$

Proof. This follows from the Chinese Remainder Theorem.

Lemma. ${\displaystyle \mathbb {A} _{\mathbb {Q} ,\mathrm {fin} }={\widehat {\mathbb {Z} }}\otimes _{\mathbb {Z} }\mathbb {Q} .}$

Proof. Use the universal property of the tensor product. Define a ${\displaystyle \mathbb {Z} }$-bilinear function

${\displaystyle {\begin{cases}\Psi$ :{\widehat {\mathbb {Z} }}\times \mathbb {Q} \to \mathbb {A} _{\mathbb {Q} ,\mathrm {fin} }\\\left((a_{p})_{p},q\right)\mapsto (a_{p}q)_{p}.\end{cases}}}

This is well-defined because for a given ${\displaystyle q={\tfrac {m}{n}}\in \mathbb {Q} }$ with ${\displaystyle m,n}$ coprime there are only finitely many primes dividing ${\displaystyle n.}$ Let ${\displaystyle M}$ be another ${\displaystyle \mathbb {Z} }$-module with a ${\displaystyle \mathbb {Z} }$-bilinear map ${\displaystyle \Phi$ :{\widehat {\mathbb {Z} }}\times \mathbb {Q} \to M.} It must be the case that ${\displaystyle \Phi }$ factors through ${\displaystyle \Psi }$ uniquely, i.e., there exists a unique ${\displaystyle \mathbb {Z} }$-linear map ${\displaystyle {\tilde {\Phi }}:\mathbb {A} _{\mathbb {Q} ,\mathrm {fin} }\to M}$ such that ${\displaystyle \Phi ={\tilde {\Phi }}\circ \Psi .}$ ${\displaystyle {\tilde {\Phi }}}$ can be defined as follows: for a given ${\displaystyle (u_{p})_{p}}$ there exist ${\displaystyle u\in \mathbb {N} }$ and ${\displaystyle (v_{p})_{p}\in {\widehat {\mathbb {Z} }}}$ such that ${\displaystyle u_{p}={\tfrac {1}{u}}\cdot v_{p}}$ for all ${\displaystyle p.}$ Define ${\displaystyle {\tilde {\Phi }}((u_{p})_{p}):=\Phi ((v_{p})_{p},{\tfrac {1}{u}}).}$ One can show ${\displaystyle {\tilde {\Phi }}}$ is well-defined, ${\displaystyle \mathbb {Z} }$-linear, satisfies ${\displaystyle \Phi ={\tilde {\Phi }}\circ \Psi }$ and is unique with these properties.

Corollary. Define ${\displaystyle \mathbb {A} _{\mathbb {Z} }:={\widehat {\mathbb {Z} }}\times \mathbb {R} .}$ This results in an algebraic isomorphism ${\displaystyle \mathbb {A} _{\mathbb {Q} }\cong \mathbb {A} _{\mathbb {Z} }\otimes _{\mathbb {Z} }\mathbb {Q} .}$

Proof.

${\displaystyle \mathbb {A} _{\mathbb {Z} }\otimes _{\mathbb {Z} }\mathbb {Q} =\left({\widehat {\mathbb {Z} }}\times \mathbb {R} \right)\otimes _{\mathbb {Z} }\mathbb {Q} \cong \left({\widehat {\mathbb {Z} }}\otimes _{\mathbb {Z} }\mathbb {Q} \right)\times (\mathbb {R} \otimes _{\mathbb {Z} }\mathbb {Q} )\cong \left({\widehat {\mathbb {Z} }}\otimes _{\mathbb {Z} }\mathbb {Q} \right)\times \mathbb {R} =\mathbb {A} _{\mathbb {Q} ,\mathrm {fin} }\times \mathbb {R} =\mathbb {A} _{\mathbb {Q} }.}$

Lemma. For a number field ${\displaystyle K}$, ${\displaystyle \mathbb {A} _{K}=\mathbb {A} _{\mathbb {Q} }\otimes _{\mathbb {Q} }K.}$

Remark. Using ${\displaystyle \mathbb {A} _{\mathbb {Q} }\otimes _{\mathbb {Q} }K\cong \mathbb {A} _{\mathbb {Q} }\oplus \dots \oplus \mathbb {A} _{\mathbb {Q} },}$ where there are ${\displaystyle [K:\mathbb {Q} ]}$ summands, the right side receives the product topology and this topology is transported via the isomorphism onto ${\displaystyle \mathbb {A} _{\mathbb {Q} }\otimes _{\mathbb {Q} }K.}$

Finite extensions

If ${\displaystyle L/K}$ is a finite extension, then ${\displaystyle L}$ is a global field. Thus ${\displaystyle \mathbb {A} _{L}}$ is defined, and ${\displaystyle \textstyle \mathbb {A} _{L}={\prod _{v}}'L_{v}.}$ The ring ${\displaystyle \mathbb {A} _{K}}$ can be identified with a subring of ${\displaystyle \mathbb {A} _{L}.}$ Map ${\displaystyle a=(a_{v})_{v}\in \mathbb {A} _{K}}$ to ${\displaystyle a'=(a'_{w})_{w}\in \mathbb {A} _{L}}$, where ${\displaystyle a'_{w}=a_{v}\in K_{v}\subset L_{w}}$ for ${\displaystyle w|v.}$ Then ${\displaystyle a=(a_{w})_{w}\in \mathbb {A} _{L}}$ is in the subring ${\displaystyle \mathbb {A} _{K}}$ if ${\displaystyle a_{w}\in K_{v}}$ for ${\displaystyle w|v}$ and ${\displaystyle a_{w}=a_{w'}}$ for all ${\displaystyle w,w'}$ lying above the same place ${\displaystyle v}$ of ${\displaystyle K.}$

Lemma. If ${\displaystyle L/K}$ is a finite extension, then ${\displaystyle \mathbb {A} _{L}\cong \mathbb {A} _{K}\otimes _{K}L}$ both algebraically and topologically.

With the help of this isomorphism, the inclusion ${\displaystyle \mathbb {A} _{K}\subset \mathbb {A} _{L}}$ is given by

${\displaystyle {\begin{cases}\mathbb {A} _{K}\to \mathbb {A} _{L}\\\alpha \mapsto \alpha \otimes _{K}1.\end{cases}}}$

Furthermore, the principal adeles in ${\displaystyle \mathbb {A} _{K}}$ can be identified with a subgroup of principal adeles in ${\displaystyle \mathbb {A} _{L}}$ via the natural embedding ${\displaystyle K\to L.}$

Proof.^[16] Let ${\displaystyle \omega _{1},\ldots ,\omega _{n}}$ be a basis of ${\displaystyle L}$ over ${\displaystyle K.}$ Then for almost all ${\displaystyle v,}$

${\displaystyle {\widetilde {O_{v}}}\cong O_{v}\omega _{1}\oplus \cdots \oplus O_{v}\omega _{n}.}$

Furthermore, there are the following isomorphisms:

${\displaystyle K_{v}\omega _{1}\oplus \cdots \oplus K_{v}\omega _{n}\cong K_{v}\otimes _{K}L\cong L_{v}=\prod \nolimits _{w|v}L_{w}.}$

For the second use the map

${\displaystyle {\begin{cases}K_{v}\otimes _{K}L\to L_{v}\\\alpha _{v}\otimes a\mapsto (\alpha _{v}\cdot (\tau _{w}(a)))_{w}\end{cases}}}$

in which ${\displaystyle \tau _{w}:L\to L_{w}}$ is the canonical embedding and ${\displaystyle w|v.}$ The restricted product is taken on both sides with respect to ${\displaystyle {\widetilde {O_{v}}}:}$

${\displaystyle {\begin{aligned}\mathbb {A} _{K}\otimes _{K}L&=\left({\prod _{v}}'K_{v}\right)\otimes _{K}L\\&\cong {\prod _{v}}'(K_{v}\omega _{1}\oplus \cdots \oplus K_{v}\omega _{n})\\&\cong {\prod _{v}}'(K_{v}\otimes _{K}L)\\&\cong {\prod _{v}}'L_{v}\\&=\mathbb {A} _{L}.\end{aligned}}}$