Substitution matrix: Difference between revisions

From formulasearchengine
Jump to navigation Jump to search
en>Rjwilmsi
m Journal cites (journal names):, using AWB (8060)
 
en>Materialscientist
m Reverted 1 edit by 140.113.239.51 identified as test/vandalism using STiki
Line 1: Line 1:
== '秦ゆうの心はこの可能性を否定するために「殺す」だろう ==
In the subfield of [[Abstract algebra|algebra]] named [[field theory (mathematics)|field theory]], a '''separable extension''' is an [[algebraic field extension]] <math>E\supset F</math> such that for every <math>\alpha\in E</math>, the [[minimal polynomial (field theory)|minimal polynomial]] of <math>\alpha</math> over ''F'' is a [[separable polynomial]] (i.e., has distinct [[Root of a polynomial|roots]]; see [[#Separable and inseparable polynomials|below]] for the definition in this context).<ref name="Isaacs281">Isaacs, p. 281</ref> Otherwise, the extension is called '''inseparable'''. There are other equivalent definitions of the notion of a separable algebraic extension, and these are outlined later in the article.


黒その場合に実際にある場合、その [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_10.php クリスチャンルブタン 値段]......<br><br>「いいえ、無名の兄による、彼は死んだ鳥の数に加えて、家族のことを聞いたことがなかったと言って、任意の強力な上司、そこに思い出のスーパー動物高騰。黒い遺産を持っていますが、黒鷹ファミリーのこの一種類の無動物小黒は世界が動物を見ていない妖精の魔法の悪魔に属している必要があります。 [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_4.php クリスチャンルブタン セール] '<br><br>秦Yuは脳の速度を考える [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_5.php クリスチャンルブタン スニーカー]。<br><br>「黒い悪魔の世界はちょうど到着した。強さは、彼の大きな範囲を移動する方法強敵。がなくても、恐怖はそれのための他の理由があるとされ、まだ弱いです。 [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_14.php クリスチャンルブタン バッグ] '秦ゆうの心はこの可能性を否定するために「殺す」だろう。<br><br>×××<br>今の状況を何であるかを最終的に黒い羽に3人の兄弟を<br>、秦Yuは何とか目覚めです。侯飛この場所まで待機する神秘的な場所、であるように、秦Yuは三日待つ必要があります。<br><br>などその牛のマジック陛下リターン [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_0.php クリスチャンルブタン メンズ 靴]。<br>突破口は今9セント皇帝となっている時に<br>、今回は一度秦ゆう、ゆう黄を知らない。秦ゆうと無謀トーク半日は、それは無謀取り決めた
The importance of separable extensions lies in the fundamental role they play in [[Galois theory]] in [[characteristic (algebra)#Case of fields|finite characteristic]]. More specifically, a finite degree field extension is [[Galois extension|Galois]] if and only if it is both [[Normal extension|normal]] and separable.<ref>Isaacs, Theorem 18.13, p. 282</ref> Since algebraic extensions of fields of characteristic zero, and of finite fields, are separable, separability is not an obstacle in most applications of [[Galois theory]].<ref name="Isaacs18.11p281">Isaacs, Theorem 18.11, p. 281</ref><ref>Isaacs, p. 293</ref> For instance, every algebraic (in particular, finite degree) extension of the field of rational numbers is necessarily separable.
相关的主题文章:
<ul>
 
  <li>[http://castiron.m78.com/bbs/light.cgi http://castiron.m78.com/bbs/light.cgi]</li>
 
  <li>[http://www.eliasentertainment.com/cgi-bin/guestbook/guestbook.cgi http://www.eliasentertainment.com/cgi-bin/guestbook/guestbook.cgi]</li>
 
  <li>[http://www.0710hdyz.com/forum.php?mod=viewthread&tid=12405&fromuid=6011 http://www.0710hdyz.com/forum.php?mod=viewthread&tid=12405&fromuid=6011]</li>
 
</ul>


== 「製油所の進行状況が99%を超えています ==
Despite the ubiquity of the class of separable extensions in mathematics, its extreme opposite, namely the class of [[purely inseparable extensions]], also occurs quite naturally. An algebraic extension <math>E\supset F</math> is a purely inseparable extension if and only if for every <math>\alpha\in E\setminus F</math>, the minimal polynomial of <math>\alpha</math> over ''F'' is ''not'' a [[separable polynomial]] (i.e., ''does not'' have distinct roots).<ref name="Isaacs298">Isaacs, p. 298</ref> For a field ''F'' to possess a non-trivial purely inseparable extension, it must necessarily be an infinite field of prime characteristic (i.e. specifically, [[imperfect field|imperfect]]), since any algebraic extension of a [[perfect field]] is necessarily separable.<ref name="Isaacs18.11p281"/>


ボールの回転速度の始まりは、互いの範囲は大きくない、あまりにも高速ではありません [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_2.php クリスチャンルブタン 日本]。<br><br>しかし時間をかけて、それ以降の数年間で、それはZhefanのように見えるようになりましになってきている [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_12.php 靴 クリスチャンルブタン]。<br><br>「製油所の進行状況が99%を超えています。だけなので少し、それは一年があると推定されている最後の製油所を完了することができます。 '秦ゆうの心は非常に明確で、彼はまだ静かに精製しようとしています魂の力は黒蓮、黄金のボールに統合し続けています。<br><br>しかし、今黒蓮、ゴールドビーズ、さらにいくつかのオーダーフローの周囲の [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_2.php クリスチャンルブタン 東京]。<br>時間の経過<br> [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_10.php クリスチャンルブタン ブーツ]......<br>年<br>と半分が瞬時に行ってきました。<br><br>秦Yuはエラーを推定した。もともと最後まで、実際にはそんなに魂の力を費やしたと思った唯一の年は、完全に成功したことを考えた。<br><br>年半、フル精錬成功。<br>この瞬間を<br> [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_6.php クリスチャンルブタン セール] - <br><br>秦ゆうタオは、無限の波の頂上、黒蓮にあぐらをかいて座って、金色のビーズが巨大太極拳、秦ゆうを形成し、
==Informal discussion==
相关的主题文章:
''The reader may wish to assume that, in what follows, F is the field of rational, real or complex numbers, unless otherwise stated.''
<ul>
 
  <li>[http://92kr.net/plus/feedback.php?aid=1 http://92kr.net/plus/feedback.php?aid=1]</li>
 
  <li>[http://max-race.com/plus/feedback.php?aid=1585 http://max-race.com/plus/feedback.php?aid=1585]</li>
 
  <li>[http://www.jsjcpm.com.cn/plus/view.php?aid=67363 http://www.jsjcpm.com.cn/plus/view.php?aid=67363]</li>
 
</ul>


== 見つめて目を丸くしながら、約9淡い話をするために一緒に ==
An arbitrary polynomial ''f'' with coefficients in some field ''F'' is said to have ''distinct roots'' if and only if it has deg(''f'') roots in some [[extension field]] <math>E\supseteq F</math>. For instance, the polynomial ''g''(''X'')=''X''<sup>2</sup>+1 with real coefficients has precisely deg(''g'')=2 roots in the complex plane; namely the [[imaginary unit]] ''i'', and its additive inverse &minus;''i'', and hence ''does have'' distinct roots. On the other hand, the polynomial ''h''(''X'')=(''X''&minus;2)<sup>2</sup> with real coefficients ''does not'' have distinct roots; only 2 can be a root of this polynomial in the complex plane and hence it has only one, and not deg(''h'')=2 roots.


過去には、そのようなヘア厚み空間としてであっても霊の世界のある場所の上の雪の殺し屋は、亀裂の余地がある [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_10.php クリスチャンルブタン 銀座]<br>'まあ!'<br><br>3秦ゆうにカット手は約9思えるに銃をブロックするために、直接固執して非常に自信を持ってこの「タン9 '<br>右側、彼らの神は秦ゆうが上の神々を使用している耐えるのに十分セントラル付きです。<br><br>しかし - [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_3.php クリスチャンルブタン ブーツ] <br>9顔約<br>が突然変更され、スティック3カットが驚いていることを見て、その後、オープン割れ、Nabingガンは直接彼の首を刺し9仰天について話している。<br><br>「クラック! [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_10.php クリスチャンルブタン 直営店] '<br><br>秦Yuは大声で雷。<br>jifenに約9が創傷に火を開くには、首に沿って拡散エキゾチックの力、、、その後頭、胸の敵を感じた<br>!元英と魂セーバーもシ​​エラのjifenトレジャーに沈んでいる。<br>見つめて目を丸くしながら、約9淡い話をするために一緒に<br>他の二つ。<br><br>約九から二最初の反応は [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_10.php クリスチャンルブタン 銀座] - [http://www.lamartcorp.com/modules/mod_menu/rakuten_cl_11.php クリスチャンルブタン 取扱店] 脱出!<br><br>は9、北朝鮮についての2話を見ました
To test if a polynomial has distinct roots, it is not necessary to consider explicitly any field extension nor to compute the roots: a polynomial has distinct roots if and only if the [[polynomial greatest common divisor|greatest common divisor]] of the polynomial and its [[derivative]] is a constant.
相关的主题文章:
For instance, the polynomial ''g''(''X'')=''X''<sup>2</sup>+1 in the above paragraph, has 2''X'' as derivative, and, over a field of [[characteristic of a field|characteristic]] different of 2, we have ''g''(''X'') - (1/2 ''X'') 2''X'' = 1, which proves, by [[Bézout's identity]], that the greatest common divisor is a constant. On the other hand,  over a field where 2=0, the greatest common divisor is ''g'', and we have ''g''(''X'') = (''X''+1)<sup>2</sup> has 1=-1 as double root.
<ul>
On the other hand, the polynomial ''h'' ''does not'' have distinct roots, whichever is the field of the coefficients, and indeed, ''h''(''X'')=(''X''&minus;2)<sup>2</sup>, its derivative is 2 (''X''-2) and divides it, and hence ''does'' have a factor of the form <math>(X-\alpha)^2</math> for <math>\alpha=2</math>).  
 
 
  <li>[http://www.6k6k6k.cn/my/space.php?uid=11786&do=blog&id=43293 http://www.6k6k6k.cn/my/space.php?uid=11786&do=blog&id=43293]</li>
Although an arbitrary polynomial with rational or real coefficients may not have distinct roots, it is natural to ask at this stage whether or not there exists an ''[[irreducible polynomial]]'' with rational or real coefficients that does not have distinct roots. The polynomial ''h''(''X'')=(''X''&minus;2)<sup>2</sup> does not have distinct roots but it is not irreducible as it has a non-trivial factor (''X''&minus;2). In fact, it is true that there is ''no irreducible polynomial with rational or real coefficients that does not have distinct roots''; in the language of field theory, every [[algebraic extension]] of <math>\mathbb{Q}</math> or <math>\mathbb{R}</math> is separable and hence both of these fields are [[Perfect field|perfect]].
 
 
  <li>[http://hanko-store.com/voice/voice.cgi http://hanko-store.com/voice/voice.cgi]</li>
==Separable and inseparable polynomials==
 
A polynomial ''f'' in ''F''[''X''] is a ''separable polynomial'' if and only if every irreducible factor of ''f'' in ''F''[''X''] has distinct roots.<ref>Isaacs, p. 280</ref> The separability of a polynomial depends on the field in which its coefficients are considered to lie; for instance, if ''g'' is an inseparable polynomial in ''F''[''X''], and one considers a [[splitting field]], ''E'', for ''g'' over ''F'', ''g'' is necessarily separable in ''E''[''X''] since an arbitrary irreducible factor of ''g'' in ''E''[''X''] is linear and hence has distinct roots.<ref name="Isaacs281"/> Despite this, a separable polynomial ''h'' in ''F''[''X''] must necessarily be separable over ''every'' extension field of ''F''.<ref>Isaacs, Lemma 18.10, p. 281</ref>
  <li>[http://www.folders.jp/cgi-bin/enq/enq.cgi http://www.folders.jp/cgi-bin/enq/enq.cgi]</li>
 
 
Let ''f'' in ''F''[''X''] be an irreducible polynomial and ''f''<nowiki>'</nowiki> its [[formal derivative]]. Then the following are equivalent conditions for ''f'' to be separable; that is, to have distinct roots:
</ul>
* If <math>E\supseteq F</math> and <math>\alpha\in E</math>, then <math>(X-\alpha)^2</math> does not divide ''f'' in ''E''[''X''].<ref name=IsaacsLem18.7>Isaacs, Lemma 18.7, p. 280</ref>
* There exists <math>K \supseteq F</math> such that ''f'' has deg(''f'') roots in ''K''.<ref name=IsaacsLem18.7/>
* ''f'' and ''f''<nowiki>'</nowiki> do not have a common root in any extension field of ''F''.<ref>Isaacs, Theorem 19.4, p. 295</ref>
* ''f''<nowiki>'</nowiki> is not the zero polynomial.<ref>Isaacs, Corollary 19.5, p. 296</ref>
 
By the last condition above, if an irreducible polynomial does not have distinct roots, its derivative must be zero. Since the formal derivative of a positive degree polynomial can be zero only if the field has prime characteristic, for an irreducible polynomial to not have distinct roots its coefficients must lie in a field of prime characteristic. More generally, if an irreducible (non-zero) polynomial ''f'' in ''F''[''X''] does not have distinct roots, not only must the characteristic of ''F'' be a (non-zero) prime number ''p'', but also ''f''(''X'')=''g''(''X''<sup>''p''</sup>) for some ''irreducible'' polynomial ''g'' in ''F''[''X''].<ref>Isaacs, Corollary 19.6, p. 296</ref> By repeated application of this property, it follows that in fact, <math>f(X)=g(X^{p^n})</math> for a non-negative integer ''n'' and some ''separable irreducible'' polynomial ''g'' in ''F''[''X''] (where ''F'' is assumed to have prime characteristic ''p'').<ref>Isaacs, Corollary 19.9, p. 298</ref>
 
By the property noted in the above paragraph, if ''f'' is an irreducible (non-zero) polynomial with coefficients in the field ''F'' of prime characteristic ''p'', and does not have distinct roots, it is possible to write ''f''(''X'')=''g''(''X''<sup>''p''</sup>). Furthermore, if <math>g(X)=\sum a_iX^i</math>, and if the [[Frobenius endomorphism]] of ''F'' is an [[automorphism]], ''g'' may be written as <math>g(X)=\sum b_i^{p}X^i</math>, and in particular, <math>f(X)=g(X^p)=\sum b_i^{p}X^{pi}=(\sum b_iX^i)^p</math>; a contradiction of the irreducibility of ''f''. Therefore, if ''F''[''X''] possesses an inseparable irreducible (non-zero) polynomial, then the Frobenius endomorphism of ''F'' cannot be an automorphism (where ''F'' is assumed to have prime characteristic ''p'').<ref>Isaacs, Theorem 19.7, p. 297</ref>
 
If ''K'' is a finite field of prime characteristic ''p'', and if ''X'' is an indeterminant, then the field of rational functions over ''K'', ''K''(''X''), is necessarily [[Imperfect field|imperfect]]. Furthermore, the polynomial ''f''(''Y'')=''Y''<sup>''p''</sup>&minus;''X'' is inseparable.<ref name="Isaacs281"/> (To see this, note that there is some extension field <math>E\supseteq K(X)</math> in which ''f'' has a root <math>\alpha</math>; necessarily, <math>\alpha^{p}=X</math> in ''E''. Therefore, working over ''E'', <math>f(Y)=Y^p-X=Y^p-\alpha^{p}=(Y-\alpha)^p</math> (the final equality in the sequence follows from [[freshman's dream]]), and ''f'' does not have distinct roots.) More generally, if ''F'' is any field of (non-zero) prime characteristic for which the [[Frobenius endomorphism]] is not an automorphism, ''F'' possesses an inseparable algebraic extension.<ref name="Isaacs299">Isaacs, p. 299</ref>
 
A field ''F'' is [[Perfect field|perfect]] if and only if all of its algebraic extensions are separable (in fact, all algebraic extensions of ''F'' are separable if and only if all finite degree extensions of ''F'' are separable). By the argument outlined in the above paragraphs, it follows that ''F'' is perfect if and only if ''F'' has characteristic zero, or ''F'' has (non-zero) prime characteristic ''p'' and the [[Frobenius endomorphism]] of ''F'' is an automorphism.
 
==Properties==
*If <math>E\supseteq F</math> is an algebraic field extension, and if <math>\alpha,\beta\in E</math> are separable over ''F'', then <math>\alpha+\beta</math> and <math>\alpha\beta</math> are separable over ''F''. In particular, the set of all elements in ''E'' separable over ''F'' forms a field.<ref>Isaacs, Lemma 19.15, p. 300</ref>
*If <math>E\supseteq L\supseteq F</math> is such that <math>E\supseteq L</math> and <math>L\supseteq F</math> are separable extensions, then <math>E\supseteq F</math> is separable.<ref>Isaacs, Corollary 19.17, p. 301</ref> Conversely, if <math>E\supseteq F</math> is a separable algebraic extension, and if ''L'' is any intermediate field, then <math>E\supseteq L</math> and <math>L\supseteq F</math> are separable extensions.<ref>Isaacs, Corollary 18.12, p. 281</ref>
*If <math>E\supseteq F</math> is a finite degree separable extension, then it has a primitive element; i.e., there exists <math>\alpha\in E</math> with <math>E=F[\alpha]</math>. This fact is also known as the ''[[primitive element theorem]]'' or ''Artin's theorem on primitive elements''.
 
==Separable extensions within algebraic extensions==
Separable extensions occur quite naturally within arbitrary algebraic field extensions. More specifically, if <math>E\supseteq F</math> is an algebraic extension and if <math>S=\{\alpha\in E|\alpha \mbox{ is separable over } F\}</math>, then ''S'' is the unique intermediate field that is ''separable'' over ''F'' and over which ''E'' is ''purely inseparable''.<ref>Isaacs, Theorem 19.14, p. 300</ref> If <math>E\supseteq F</math> is a finite degree extension, the degree [''S'' : ''F''] is referred to as the '''separable part''' of the degree of the extension <math>E\supseteq F</math> (or the '''separable degree''' of ''E''/''F''), and is often denoted by [''E'' : ''F'']<sub>sep</sub> or [''E'' : ''F'']<sub>s</sub>.<ref name="Isaacs302">Isaacs, p. 302</ref> The '''inseparable degree''' of ''E''/''F'' is the quotient of the degree by the separable degree. When the characteristic of ''F'' is ''p''&nbsp;>&nbsp;0, it is a power of ''p''.<ref>{{harvnb|Lang|2002|loc=Corollary V.6.2}}</ref> Since the extension <math>E\supseteq F</math> is separable if and only if <math>S=E</math>, it follows that for separable extensions, [''E'' : ''F'']=[''E'' : ''F'']<sub>sep</sub>, and conversely. If <math>E\supseteq F</math> is not separable (i.e., inseparable), then [''E'' : ''F'']<sub>sep</sub> is necessarily a non-trivial divisor of [''E'' : ''F''], and the quotient is necessarily a power of the characteristic of ''F''.<ref name="Isaacs302"/>  
 
On the other hand, an arbitrary algebraic extension <math>E\supseteq F</math> may not possess an intermediate extension ''K'' that is ''purely inseparable'' over ''F'' and over which ''E'' is ''separable'' (however, such an intermediate extension does exist when <math>E\supseteq F</math> is a finite degree normal extension (in this case, ''K'' can be the fixed field of the Galois group of ''E'' over ''F'')). If such an intermediate extension does exist, and if [''E'' : ''F''] is finite, then if ''S'' is defined as in the previous paragraph, [''E'' : ''F'']<sub>sep</sub>=[''S'' : ''F'']=[''E'' : ''K''].<ref>Isaacs, Theorem 19.19, p. 302</ref> One known proof of this result depends on the [[primitive element theorem]], but there does exist a proof of this result independent of the primitive element theorem (both proofs use the fact that if <math>K\supseteq F</math> is a purely inseparable extension, and if ''f'' in ''F''[''X''] is a separable irreducible polynomial, then ''f'' remains irreducible in ''K''[''X'']<ref>Isaacs, Lemma 19.20, p. 302</ref>). The equality above ([''E'' : ''F'']<sub>sep</sub>=[''S'' : ''F'']=[''E'' : ''K'']) may be used to prove that if <math>E\supseteq U\supseteq F</math> is such that [''E'' : ''F''] is finite, then [''E'' : ''F'']<sub>sep</sub>=[''E'' : ''U'']<sub>sep</sub>[''U'' : ''F'']<sub>sep</sub>.<ref>Isaacs, Corollary 19.21, p. 303</ref>
 
If ''F'' is any field, the '''separable closure''' ''F''<sup>sep</sup> of ''F'' is the field of all elements in an [[algebraic closure]] of ''F'' that are separable over ''F''. This is the maximal [[Galois extension]] of ''F''.  By definition, ''F'' is perfect if and only if its separable and algebraic closures coincide (in particular, the notion of a separable closure is only interesting for imperfect fields).
 
== The definition of separable non-algebraic extension fields ==
Although many important applications of the theory of separable extensions stem from the context of algebraic field extensions, there are important instances in mathematics where it is profitable to study (not necessarily algebraic) separable field extensions.
 
Let <math>F/k</math> be a field extension and let ''p'' be the [[characteristic exponent of a field|characteristic exponent]] of <math>k</math>.<ref>The characteristic exponent of ''k'' is ''1'' if ''k'' has characteristic zero; otherwise, it is the characteristic of ''k''.</ref> For any field extension ''L'' of ''k'', we write <math>F_L = L \otimes_k F</math> (cf. [[Tensor product of fields]].) Then ''F'' is said to be ''separable over <math>k</math>'' if the following equivalent conditions are met:
*<math>F^p</math> and <math>k</math> are [[linearly disjoint]] over <math>k^p</math>
*<math>F_{k^{1/p}}</math> is reduced.
*<math>F_L</math> is reduced for all field extensions ''L'' of ''k''.
(In other words, ''F'' is separable over ''k'' if ''F'' is a [[separable algebra|separable ''k''-algebra]].)
 
Suppose there is some field extension ''L'' of ''k'' such that <math>F_L</math> is a domain. Then <math>F</math> is separable over ''k'' if and only if the field of fractions of <math>F_L</math> is separable over ''L''.
 
An algebraic element of ''F'' is said to be ''separable over <math>k</math>'' if its minimal polynomial is separable. If <math>F/k</math> is an algebraic extension, then the following are equivalent.
*''F'' is separable over ''k''.
*''F'' consists of elements that are separable over ''k''.
*Every subextension of ''F/k'' is separable.
*Every finite subextension of ''F/k'' is separable.
 
If <math>F/k</math> is finite extension, then the following are equivalent.
*(i) ''F'' is separable over ''k''.
*(ii) <math>F = k(a_1, ..., a_r)</math> where <math>a_1, ..., a_r</math> are separable over ''k''.
*(iii) In (ii), one can take <math>r = 1.</math>
*(iv) For some very large field <math>\Omega</math>, there are precisely <math>[F : k]</math> ''k''-isomorphisms from <math>F</math> to <math>\Omega</math>.
In the above, (iii) is known as the ''[[primitive element theorem]]''.
 
Fix the algebraic closure <math>\overline{k}</math>, and denote by <math>k_s</math> the set of all elements of <math>\overline{k}</math> that are separable over ''k''. <math>k_s</math> is then separable algebraic over ''k'' and any separable algebraic subextension of <math>\overline{k}</math> is contained in <math>k_s</math>; it is called the '''separable closure''' of ''k'' (inside <math>\overline{k}</math>). <math>\overline{k}</math> is then purely inseparable over <math>k_s</math>. Put in another way, ''k'' is perfect if and only if <math>\overline{k} = k_s</math>.
 
== Differential criteria ==
The separability can be studied with the aid of derivations and [[Kähler differential]]s. Let <math>F</math> be a [[finitely generated field extension]] of a field <math>k</math>. Then
:<math>\dim_F \operatorname{Der}_k(F, F) \ge \operatorname{tr.deg}_k F</math>
where the equality holds if and only if ''F'' is separable over ''k''.
 
In particular, if <math>F/k</math> is an algebraic extension, then <math>\operatorname{Der}_k(F, F) = 0</math> if and only if <math>F/k</math> is separable.
 
Let <math>D_1, ..., D_m</math> be a basis of <math>\operatorname{Der}_k(F, F)</math> and <math>a_1, ..., a_m \in F</math>. Then <math>F</math> is separable algebraic over <math>k(a_1, ..., a_m)</math> if and only if the matrix <math>D_i(a_j)</math> is invertible. In particular, when <math>m = \operatorname{tr.deg}_k F</math>, <math>\{ a_1, ..., a_m \}</math> above is called the ''separating transcendence basis.''
 
==See also==
*[[Purely inseparable extension]]
*[[Separable polynomial]]
*[[Perfect field]]
*[[Primitive element theorem]]
*[[Normal extension]]
*[[Galois extension]]
*[[Algebraic closure]]
*[[Derivation (algebra)|Derivation]]
 
==Notes==
{{reflist|30em}}
 
==References==
* Borel, A. ''Linear algebraic groups'', 2nd ed.
* P.M. Cohn (2003). Basic algebra
* {{cite book
| author = I. Martin Isaacs
| year = 1993
| title = Algebra, a graduate course
| edition = 1st
| publisher = Brooks/Cole Publishing Company
| isbn = 0-534-19002-2
}}
* M. Nagata (1985). Commutative field theory: new edition, Shokado. (Japanese) [http://www.shokabo.co.jp/mybooks/ISBN978-4-7853-1309-8.htm]
*{{cite book |last=Silverman |first=Joseph |title=The Arithmetic of Elliptic Curves |year=1993 |publisher=Springer |isbn=0-387-96203-4}}
 
==External links==
*{{Springer|id=s/s084470|title=separable extension of a field k}}
 
[[Category:Field extensions]]
 
[[de:Körpererweiterung#Separable Erweiterungen]]

Revision as of 12:33, 17 October 2013

In the subfield of algebra named field theory, a separable extension is an algebraic field extension EF such that for every αE, the minimal polynomial of α over F is a separable polynomial (i.e., has distinct roots; see below for the definition in this context).[1] Otherwise, the extension is called inseparable. There are other equivalent definitions of the notion of a separable algebraic extension, and these are outlined later in the article.

The importance of separable extensions lies in the fundamental role they play in Galois theory in finite characteristic. More specifically, a finite degree field extension is Galois if and only if it is both normal and separable.[2] Since algebraic extensions of fields of characteristic zero, and of finite fields, are separable, separability is not an obstacle in most applications of Galois theory.[3][4] For instance, every algebraic (in particular, finite degree) extension of the field of rational numbers is necessarily separable.

Despite the ubiquity of the class of separable extensions in mathematics, its extreme opposite, namely the class of purely inseparable extensions, also occurs quite naturally. An algebraic extension EF is a purely inseparable extension if and only if for every αEF, the minimal polynomial of α over F is not a separable polynomial (i.e., does not have distinct roots).[5] For a field F to possess a non-trivial purely inseparable extension, it must necessarily be an infinite field of prime characteristic (i.e. specifically, imperfect), since any algebraic extension of a perfect field is necessarily separable.[3]

Informal discussion

The reader may wish to assume that, in what follows, F is the field of rational, real or complex numbers, unless otherwise stated.

An arbitrary polynomial f with coefficients in some field F is said to have distinct roots if and only if it has deg(f) roots in some extension field EF. For instance, the polynomial g(X)=X2+1 with real coefficients has precisely deg(g)=2 roots in the complex plane; namely the imaginary unit i, and its additive inverse −i, and hence does have distinct roots. On the other hand, the polynomial h(X)=(X−2)2 with real coefficients does not have distinct roots; only 2 can be a root of this polynomial in the complex plane and hence it has only one, and not deg(h)=2 roots.

To test if a polynomial has distinct roots, it is not necessary to consider explicitly any field extension nor to compute the roots: a polynomial has distinct roots if and only if the greatest common divisor of the polynomial and its derivative is a constant. For instance, the polynomial g(X)=X2+1 in the above paragraph, has 2X as derivative, and, over a field of characteristic different of 2, we have g(X) - (1/2 X) 2X = 1, which proves, by Bézout's identity, that the greatest common divisor is a constant. On the other hand, over a field where 2=0, the greatest common divisor is g, and we have g(X) = (X+1)2 has 1=-1 as double root. On the other hand, the polynomial h does not have distinct roots, whichever is the field of the coefficients, and indeed, h(X)=(X−2)2, its derivative is 2 (X-2) and divides it, and hence does have a factor of the form (Xα)2 for α=2).

Although an arbitrary polynomial with rational or real coefficients may not have distinct roots, it is natural to ask at this stage whether or not there exists an irreducible polynomial with rational or real coefficients that does not have distinct roots. The polynomial h(X)=(X−2)2 does not have distinct roots but it is not irreducible as it has a non-trivial factor (X−2). In fact, it is true that there is no irreducible polynomial with rational or real coefficients that does not have distinct roots; in the language of field theory, every algebraic extension of or is separable and hence both of these fields are perfect.

Separable and inseparable polynomials

A polynomial f in F[X] is a separable polynomial if and only if every irreducible factor of f in F[X] has distinct roots.[6] The separability of a polynomial depends on the field in which its coefficients are considered to lie; for instance, if g is an inseparable polynomial in F[X], and one considers a splitting field, E, for g over F, g is necessarily separable in E[X] since an arbitrary irreducible factor of g in E[X] is linear and hence has distinct roots.[1] Despite this, a separable polynomial h in F[X] must necessarily be separable over every extension field of F.[7]

Let f in F[X] be an irreducible polynomial and f' its formal derivative. Then the following are equivalent conditions for f to be separable; that is, to have distinct roots:

  • If EF and αE, then (Xα)2 does not divide f in E[X].[8]
  • There exists KF such that f has deg(f) roots in K.[8]
  • f and f' do not have a common root in any extension field of F.[9]
  • f' is not the zero polynomial.[10]

By the last condition above, if an irreducible polynomial does not have distinct roots, its derivative must be zero. Since the formal derivative of a positive degree polynomial can be zero only if the field has prime characteristic, for an irreducible polynomial to not have distinct roots its coefficients must lie in a field of prime characteristic. More generally, if an irreducible (non-zero) polynomial f in F[X] does not have distinct roots, not only must the characteristic of F be a (non-zero) prime number p, but also f(X)=g(Xp) for some irreducible polynomial g in F[X].[11] By repeated application of this property, it follows that in fact, f(X)=g(Xpn) for a non-negative integer n and some separable irreducible polynomial g in F[X] (where F is assumed to have prime characteristic p).[12]

By the property noted in the above paragraph, if f is an irreducible (non-zero) polynomial with coefficients in the field F of prime characteristic p, and does not have distinct roots, it is possible to write f(X)=g(Xp). Furthermore, if g(X)=aiXi, and if the Frobenius endomorphism of F is an automorphism, g may be written as g(X)=bipXi, and in particular, f(X)=g(Xp)=bipXpi=(biXi)p; a contradiction of the irreducibility of f. Therefore, if F[X] possesses an inseparable irreducible (non-zero) polynomial, then the Frobenius endomorphism of F cannot be an automorphism (where F is assumed to have prime characteristic p).[13]

If K is a finite field of prime characteristic p, and if X is an indeterminant, then the field of rational functions over K, K(X), is necessarily imperfect. Furthermore, the polynomial f(Y)=YpX is inseparable.[1] (To see this, note that there is some extension field EK(X) in which f has a root α; necessarily, αp=X in E. Therefore, working over E, f(Y)=YpX=Ypαp=(Yα)p (the final equality in the sequence follows from freshman's dream), and f does not have distinct roots.) More generally, if F is any field of (non-zero) prime characteristic for which the Frobenius endomorphism is not an automorphism, F possesses an inseparable algebraic extension.[14]

A field F is perfect if and only if all of its algebraic extensions are separable (in fact, all algebraic extensions of F are separable if and only if all finite degree extensions of F are separable). By the argument outlined in the above paragraphs, it follows that F is perfect if and only if F has characteristic zero, or F has (non-zero) prime characteristic p and the Frobenius endomorphism of F is an automorphism.

Properties

  • If EF is an algebraic field extension, and if α,βE are separable over F, then α+β and αβ are separable over F. In particular, the set of all elements in E separable over F forms a field.[15]
  • If ELF is such that EL and LF are separable extensions, then EF is separable.[16] Conversely, if EF is a separable algebraic extension, and if L is any intermediate field, then EL and LF are separable extensions.[17]
  • If EF is a finite degree separable extension, then it has a primitive element; i.e., there exists αE with E=F[α]. This fact is also known as the primitive element theorem or Artin's theorem on primitive elements.

Separable extensions within algebraic extensions

Separable extensions occur quite naturally within arbitrary algebraic field extensions. More specifically, if EF is an algebraic extension and if S={αE|α is separable over F}, then S is the unique intermediate field that is separable over F and over which E is purely inseparable.[18] If EF is a finite degree extension, the degree [S : F] is referred to as the separable part of the degree of the extension EF (or the separable degree of E/F), and is often denoted by [E : F]sep or [E : F]s.[19] The inseparable degree of E/F is the quotient of the degree by the separable degree. When the characteristic of F is p > 0, it is a power of p.[20] Since the extension EF is separable if and only if S=E, it follows that for separable extensions, [E : F]=[E : F]sep, and conversely. If EF is not separable (i.e., inseparable), then [E : F]sep is necessarily a non-trivial divisor of [E : F], and the quotient is necessarily a power of the characteristic of F.[19]

On the other hand, an arbitrary algebraic extension EF may not possess an intermediate extension K that is purely inseparable over F and over which E is separable (however, such an intermediate extension does exist when EF is a finite degree normal extension (in this case, K can be the fixed field of the Galois group of E over F)). If such an intermediate extension does exist, and if [E : F] is finite, then if S is defined as in the previous paragraph, [E : F]sep=[S : F]=[E : K].[21] One known proof of this result depends on the primitive element theorem, but there does exist a proof of this result independent of the primitive element theorem (both proofs use the fact that if KF is a purely inseparable extension, and if f in F[X] is a separable irreducible polynomial, then f remains irreducible in K[X][22]). The equality above ([E : F]sep=[S : F]=[E : K]) may be used to prove that if EUF is such that [E : F] is finite, then [E : F]sep=[E : U]sep[U : F]sep.[23]

If F is any field, the separable closure Fsep of F is the field of all elements in an algebraic closure of F that are separable over F. This is the maximal Galois extension of F. By definition, F is perfect if and only if its separable and algebraic closures coincide (in particular, the notion of a separable closure is only interesting for imperfect fields).

The definition of separable non-algebraic extension fields

Although many important applications of the theory of separable extensions stem from the context of algebraic field extensions, there are important instances in mathematics where it is profitable to study (not necessarily algebraic) separable field extensions.

Let F/k be a field extension and let p be the characteristic exponent of k.[24] For any field extension L of k, we write FL=LkF (cf. Tensor product of fields.) Then F is said to be separable over k if the following equivalent conditions are met:

(In other words, F is separable over k if F is a separable k-algebra.)

Suppose there is some field extension L of k such that FL is a domain. Then F is separable over k if and only if the field of fractions of FL is separable over L.

An algebraic element of F is said to be separable over k if its minimal polynomial is separable. If F/k is an algebraic extension, then the following are equivalent.

  • F is separable over k.
  • F consists of elements that are separable over k.
  • Every subextension of F/k is separable.
  • Every finite subextension of F/k is separable.

If F/k is finite extension, then the following are equivalent.

  • (i) F is separable over k.
  • (ii) F=k(a1,...,ar) where a1,...,ar are separable over k.
  • (iii) In (ii), one can take r=1.
  • (iv) For some very large field Ω, there are precisely [F:k] k-isomorphisms from F to Ω.

In the above, (iii) is known as the primitive element theorem.

Fix the algebraic closure k, and denote by ks the set of all elements of k that are separable over k. ks is then separable algebraic over k and any separable algebraic subextension of k is contained in ks; it is called the separable closure of k (inside k). k is then purely inseparable over ks. Put in another way, k is perfect if and only if k=ks.

Differential criteria

The separability can be studied with the aid of derivations and Kähler differentials. Let F be a finitely generated field extension of a field k. Then

dimFDerk(F,F)tr.degkF

where the equality holds if and only if F is separable over k.

In particular, if F/k is an algebraic extension, then Derk(F,F)=0 if and only if F/k is separable.

Let D1,...,Dm be a basis of Derk(F,F) and a1,...,amF. Then F is separable algebraic over k(a1,...,am) if and only if the matrix Di(aj) is invertible. In particular, when m=tr.degkF, {a1,...,am} above is called the separating transcendence basis.

See also

Notes

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro.

References

  • Borel, A. Linear algebraic groups, 2nd ed.
  • P.M. Cohn (2003). Basic algebra
  • 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
  • M. Nagata (1985). Commutative field theory: new edition, Shokado. (Japanese) [1]
  • 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

    My blog: http://www.primaboinca.com/view_profile.php?userid=5889534

External links

  • Other Sports Official Kull from Drumheller, has hobbies such as telescopes, property developers in singapore and crocheting. Identified some interesting places having spent 4 months at Saloum Delta.

    my web-site http://himerka.com/

de:Körpererweiterung#Separable Erweiterungen

  1. 1.0 1.1 1.2 Isaacs, p. 281
  2. Isaacs, Theorem 18.13, p. 282
  3. 3.0 3.1 Isaacs, Theorem 18.11, p. 281
  4. Isaacs, p. 293
  5. Isaacs, p. 298
  6. Isaacs, p. 280
  7. Isaacs, Lemma 18.10, p. 281
  8. 8.0 8.1 Isaacs, Lemma 18.7, p. 280
  9. Isaacs, Theorem 19.4, p. 295
  10. Isaacs, Corollary 19.5, p. 296
  11. Isaacs, Corollary 19.6, p. 296
  12. Isaacs, Corollary 19.9, p. 298
  13. Isaacs, Theorem 19.7, p. 297
  14. Isaacs, p. 299
  15. Isaacs, Lemma 19.15, p. 300
  16. Isaacs, Corollary 19.17, p. 301
  17. Isaacs, Corollary 18.12, p. 281
  18. Isaacs, Theorem 19.14, p. 300
  19. 19.0 19.1 Isaacs, p. 302
  20. Template:Harvnb
  21. Isaacs, Theorem 19.19, p. 302
  22. Isaacs, Lemma 19.20, p. 302
  23. Isaacs, Corollary 19.21, p. 303
  24. The characteristic exponent of k is 1 if k has characteristic zero; otherwise, it is the characteristic of k.