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In mathematics, especially in the field of ring theory, a (right) free ideal ring, or fir, is a ring in which all right ideals are free modules with unique rank. A ring such that all right ideals with at most ''n'' generators are free and have unique rank is called an n-fir. A semifir is a ring in which all finitely generated right ideals are free modules of unique rank. (Thus, a ring is semifir if it is ''n''-fir for all ''n'' ≥ 0.) The semifir property is left-right symmetric, but the fir property is not. ==Properties and examples== It turns out that a left and right fir is a domain. Furthermore, a commutative fir is precisely a principal ideal domain, while a commutative semifir is precisely a Bézout domain. These last facts are not generally true for noncommutative rings, however . Every principal right ideal domain ''R'' is a right fir, since every nonzero principal right ideal of a domain is isomorphic to ''R''. In the same way, a right Bézout domain is a semifir. Since all right ideals of a right fir are free, they are projective. So, any right fir is a right hereditary ring, and likewise a right semifir is a right semihereditary ring. Because projective modules over local rings are free, and because local rings have invariant basis number, it follows that a local, right hereditary ring is a right fir, and a local, right semihereditary ring is a right semifir. Unlike a principal right idea domain, a right fir is not necessarily right Noetherian, however in the commutative case, ''R'' is a Dedekind domain since it is a hereditary domain, and so is necessarily Noetherian. Another important and motivating example of a free ideal ring are the free associative (unital) ''k''-algebras for division rings ''k'', also called non-commutative polynomial rings . Semifirs have invariant basis number and every semifir is a Sylvester domain. 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Free ideal ring」の詳細全文を読む スポンサード リンク
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