Restricted power series

In algebra, the ring of restricted power series is the subring of a formal power series ring that consists of power series whose coefficients approach zero as degree goes to infinity.^[1] Over a non-archimedean complete field, the ring is also called a Tate algebra. Quotient rings of the ring are used in the study of a formal algebraic space as well as rigid analysis, the latter over non-archimedean complete fields.

Over a discrete topological ring, the ring of restricted power series coincides with a polynomial ring; thus, in this sense, the notion of "restricted power series" is a generalization of a polynomial.

Definition[edit]

Let A be a linearly topologized ring, separated and complete and $\{I_{\lambda }\}$ the fundamental system of open ideals. Then the ring of restricted power series is defined as the projective limit of the polynomial rings over $A/I_{\lambda }$ :

A\langle x_{1},\dots ,x_{n}\rangle =\varprojlim _{\lambda }A/I_{\lambda }[x_{1},\dots ,x_{n}]

.^[2]^[3]

In other words, it is the completion of the polynomial ring $A[x_{1},\dots ,x_{n}]$ with respect to the filtration $\{I_{\lambda }[x_{1},\dots ,x_{n}]\}$ . Sometimes this ring of restricted power series is also denoted by $A\{x_{1},\dots ,x_{n}\}$ .

Clearly, the ring $A\langle x_{1},\dots ,x_{n}\rangle$ can be identified with the subring of the formal power series ring $A[[x_{1},\dots ,x_{n}]]$ that consists of series $\sum c_{\alpha }x^{\alpha }$ with coefficients $c_{\alpha }\to 0$ ; i.e., each $I_{\lambda }$ contains all but finitely many coefficients $c_{\alpha }$ . Also, the ring satisfies (and in fact is characterized by) the universal property:^[4] for (1) each continuous ring homomorphism $A\to B$ to a linearly topologized ring $B$ , separated and complete and (2) each elements $b_{1},\dots ,b_{n}$ in $B$ , there exists a unique continuous ring homomorphism

A\langle x_{1},\dots ,x_{n}\rangle \to B,\,x_{i}\mapsto b_{i}

extending $A\to B$ .

Tate algebra[edit]

In rigid analysis, when the base ring A is the valuation ring of a complete non-archimedean field $(K,|\cdot |)$ , the ring of restricted power series tensored with $K$ ,

T_{n}=K\langle \xi _{1},\dots \xi _{n}\rangle =A\langle \xi _{1},\dots ,\xi _{n}\rangle \otimes _{A}K

is called a Tate algebra, named for John Tate.^[5] It is equivalently the subring of formal power series $k[[\xi _{1},\dots ,\xi _{n}]]$ which consists of series convergent on ${\mathfrak {o}}_{\overline {k}}^{n}$ , where ${\mathfrak {o}}_{\overline {k}}:=\{x\in {\overline {k}}:|x|\leq 1\}$ is the valuation ring in the algebraic closure ${\overline {k}}$ .

The maximal spectrum of $T_{n}$ is then a rigid-analytic space that models an affine space in rigid geometry.

Define the Gauss norm of $f=\sum a_{\alpha }\xi ^{\alpha }$ in $T_{n}$ by

\|f\|=\max _{\alpha }|a_{\alpha }|.

This makes $T_{n}$ a Banach algebra over k; i.e., a normed algebra that is complete as a metric space. With this norm, any ideal $I$ of $T_{n}$ is closed^[6] and thus, if I is radical, the quotient $T_{n}/I$ is also a (reduced) Banach algebra called an affinoid algebra.

Some key results are:

(Weierstrass division) Let $g\in T_{n}$ be a $\xi _{n}$ -distinguished series of order s; i.e., $g=\sum _{\nu =0}^{\infty }g_{\nu }\xi _{n}^{\nu }$ where $g_{\nu }\in T_{n-1}$ , $g_{s}$ is a unit element and $|g_{s}|=\|g\|>|g_{v}|$ for $\nu >s$ .^[7] Then for each $f\in T_{n}$ , there exist a unique $q\in T_{n}$ and a unique polynomial $r\in T_{n-1}[\xi _{n}]$ of degree $<s$ such that
$f=qg+r.$ ^[8]
(Weierstrass preparation) As above, let $g$ be a $\xi _{n}$ -distinguished series of order s. Then there exist a unique monic polynomial $f\in T_{n-1}[\xi _{n}]$ of degree $s$ and a unit element $u\in T_{n}$ such that $g=fu$ .^[9]
(Noether normalization) If ${\mathfrak {a}}\subset T_{n}$ is an ideal, then there is a finite homomorphism $T_{d}\hookrightarrow T_{n}/{\mathfrak {a}}$ .^[10]

As consequence of the division, preparation theorems and Noether normalization, $T_{n}$ is a Noetherian unique factorization domain of Krull dimension n.^[11] An analog of Hilbert's Nullstellensatz is valid: the radical of an ideal is the intersection of all maximal ideals containing the ideal (we say the ring is Jacobson).^[12]

Results[edit]

Results for polynomial rings such as Hensel's lemma, division algorithms (or the theory of Gröbner bases) are also true for the ring of restricted power series. Throughout the section, let A denote a linearly topologized ring, separated and complete.

(Hensel) Let ${\mathfrak {m}}\subset A$ a maximal ideal and $\varphi :A\to k:=A/{\mathfrak {m}}$ the quotient map. Given a $F$ in $A\langle \xi \rangle$ , if $\varphi (F)=gh$ for some monic polynomial $g\in k[\xi ]$ and a restricted power series $h\in k\langle \xi \rangle$ such that $g,h$ generate the unit ideal of $k\langle \xi \rangle$ , then there exist $G$ in $A[\xi ]$ and $H$ in $A\langle \xi \rangle$ such that
$F=GH,\,\varphi (G)=g,\varphi (H)=h$ .^[13]

Notes[edit]

^ Stacks Project, Tag 0AKZ.
^ Grothendieck & Dieudonné 1960, Ch. 0, § 7.5.1.
^ Bourbaki 2006, Ch. III, § 4. Definition 2 and Proposition 3.
^ Grothendieck & Dieudonné 1960, Ch. 0, § 7.5.3.
^ Fujiwara & Kato 2018, Ch 0, just after Proposition 9.3.
^ Bosch 2014, § 2.3. Corollary 8
^ Bosch 2014, § 2.2. Definition 6.
^ Bosch 2014, § 2.2. Theorem 8.
^ Bosch 2014, § 2.2. Corollary 9.
^ Bosch 2014, § 2.2. Corollary 11.
^ Bosch 2014, § 2.2. Proposition 14, Proposition 15, Proposition 17.
^ Bosch 2014, § 2.2. Proposition 16.
^ Bourbaki 2006, Ch. III, § 4. Theorem 1.

References[edit]

Bourbaki, N. (2006). Algèbre commutative: Chapitres 1 à 4. Springer Berlin Heidelberg. ISBN 9783540339373.
Grothendieck, Alexandre; Dieudonné, Jean (1960). "Éléments de géométrie algébrique: I. Le langage des schémas". Publications Mathématiques de l'IHÉS. 4. doi:10.1007/bf02684778. MR 0217083.
Bosch, Siegfried; Güntzer, Ulrich; Remmert, Reinhold (1984), "Chapter 5", Non-archimedean analysis, Springer
Bosch, Siegfried (2014), Lectures on Formal and Rigid Geometry, ISBN 9783319044170
Fujiwara, Kazuhiro; Kato, Fumiharu (2018), Foundations of Rigid Geometry I

External links[edit]

[Def-1] Stacks Project, Tag 0AKZ.

[2] Grothendieck & Dieudonné 1960, Ch. 0, § 7.5.1.

[3] Bourbaki 2006, Ch. III, § 4. Definition 2 and Proposition 3.

[4] Grothendieck & Dieudonné 1960, Ch. 0, § 7.5.3.

[5] Fujiwara & Kato 2018, Ch 0, just after Proposition 9.3.

[6] Bosch 2014, § 2.3. Corollary 8

[7] Bosch 2014, § 2.2. Definition 6.

[8] Bosch 2014, § 2.2. Theorem 8.

[9] Bosch 2014, § 2.2. Corollary 9.

[10] Bosch 2014, § 2.2. Corollary 11.

[11] Bosch 2014, § 2.2. Proposition 14, Proposition 15, Proposition 17.

[12] Bosch 2014, § 2.2. Proposition 16.

[13] Bourbaki 2006, Ch. III, § 4. Theorem 1.

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