Difference between revisions of "Ring with operators"
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| − | + | ''ring with domain of operators $ \Sigma $'' | |
| − | + | A [[Ring|ring]] on which a an action ( "multiplication" ) of elements of the ring by elements from a fixed set $ \Sigma $ | |
| + | is defined (an external law of composition), such that the following axioms are satisfied: | ||
| − | + | $$ \tag{1 } | |
| + | ( a + b) \alpha = a \alpha + b \alpha , | ||
| + | $$ | ||
| − | + | $$ \tag{2 } | |
| + | ( ab) \alpha = ( a \alpha ) b = a( b \alpha ), | ||
| + | $$ | ||
| − | + | where $ \alpha $ | |
| + | is an element of $ \Sigma $ | ||
| + | while $ a $, | ||
| + | $ b $, | ||
| + | $ a \alpha $, | ||
| + | $ b \alpha $ | ||
| + | are elements of the ring. In this way, the operators act as endomorphisms of the additive group, commuting with multiplication by an element of the ring. A ring with domain of operators $ \Sigma $, | ||
| + | or, more succinctly, a $ \Sigma $- | ||
| + | operator ring, can also be treated as a [[Universal algebra|universal algebra]] with two binary operations (addition and multiplication) and with a set $ \Sigma $ | ||
| + | of unary operations linked by the usual ring identities as well as by the identities (1) and (2). The concepts of a $ \Sigma $- | ||
| + | permissible subring, a $ \Sigma $- | ||
| + | permissible ideal, a $ \Sigma $- | ||
| + | operator isomorphism, and a $ \Sigma $- | ||
| + | operator homomorphism can be defined in the same way as for groups with operators (cf. [[Operator group|Operator group]]). If a $ \Sigma $- | ||
| + | operator ring $ R $ | ||
| + | possesses a unit element, then all ideals and all one-sided ideals of the ring $ R $ | ||
| + | are $ \Sigma $- | ||
| + | permissible. | ||
| − | + | A ring $ R $ | |
| + | is called a ring with a ring of operators $ \Sigma $ | ||
| + | if it is a $ \Sigma $- | ||
| + | operator ring whose domain of operators $ \Sigma $ | ||
| + | is itself an associative ring, while for any $ \alpha , \beta \in \Sigma $ | ||
| + | and $ a \in R $ | ||
| + | the following equalities hold: | ||
| − | + | $$ \tag{3 } | |
| + | a( \alpha + \beta ) = a \alpha + a \beta , | ||
| + | $$ | ||
| − | + | $$ \tag{4 } | |
| + | a( \alpha \beta ) = ( a \alpha ) \beta . | ||
| + | $$ | ||
| + | |||
| + | A ring with a ring of operators can also be defined as a ring which is simultaneously a $ \Sigma $- | ||
| + | module and which satisfies axiom (2). Every ring can naturally be considered as an operator ring over the ring of integers. | ||
| + | |||
| + | For all $ a $ | ||
| + | from $ R $ | ||
| + | and $ \alpha , \beta $ | ||
| + | from $ \Sigma $, | ||
| + | the element $ a( \alpha \beta - \beta \alpha ) $ | ||
| + | is an [[Annihilator|annihilator]] of $ R $. | ||
| + | Therefore, if $ R $ | ||
| + | is a ring with operators without annihilators, then its ring of operators $ \Sigma $ | ||
| + | must be commutative. | ||
The most commonly studied rings with operators are those with an associative-commutative ring of operators possessing a unit element. This type of ring is usually called an algebra over a commutative ring, and also a linear algebra. The most commonly studied linear algebras are those over fields; the theory of these algebras is evolving in parallel with the general theory of rings (without operators). | The most commonly studied rings with operators are those with an associative-commutative ring of operators possessing a unit element. This type of ring is usually called an algebra over a commutative ring, and also a linear algebra. The most commonly studied linear algebras are those over fields; the theory of these algebras is evolving in parallel with the general theory of rings (without operators). | ||
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====References==== | ====References==== | ||
<table><TR><TD valign="top">[1]</TD> <TD valign="top"> A.G. Kurosh, "Lectures on general algebra" , Chelsea (1963) (Translated from Russian)</TD></TR></table> | <table><TR><TD valign="top">[1]</TD> <TD valign="top"> A.G. Kurosh, "Lectures on general algebra" , Chelsea (1963) (Translated from Russian)</TD></TR></table> | ||
| − | |||
| − | |||
====Comments==== | ====Comments==== | ||
| − | Thus, the bilinearity properties (1), (2) and the module properties (3), (4) are practically incompatible for rings | + | Thus, the bilinearity properties (1), (2) and the module properties (3), (4) are practically incompatible for rings $ A $ |
| + | with a non-commutative ring of operators $ R $ | ||
| + | in that $ b \cdot a ( \alpha \beta - \beta \alpha ) = 0 $ | ||
| + | for all $ a, b \in A $, | ||
| + | $ \alpha , \beta \in R $. | ||
| + | This explains why algebras are usually only considered over commutative rings. Instead of algebra (over a ring) one also sometimes finds vector algebra. Both this phrase and the phrase linear algebra for an algebra over a ring are nowadays rarely used. | ||
| − | For algebras over non-commutative rings the bilinearity property (2) is weakened to | + | For algebras over non-commutative rings the bilinearity property (2) is weakened to $ ( ab) \alpha = a( b \alpha ) $. |
| + | Cf. also [[Algebra|Algebra]] and [[Ring|Ring]]. | ||
Revision as of 08:11, 6 June 2020
ring with domain of operators $ \Sigma $
A ring on which a an action ( "multiplication" ) of elements of the ring by elements from a fixed set $ \Sigma $ is defined (an external law of composition), such that the following axioms are satisfied:
$$ \tag{1 } ( a + b) \alpha = a \alpha + b \alpha , $$
$$ \tag{2 } ( ab) \alpha = ( a \alpha ) b = a( b \alpha ), $$
where $ \alpha $ is an element of $ \Sigma $ while $ a $, $ b $, $ a \alpha $, $ b \alpha $ are elements of the ring. In this way, the operators act as endomorphisms of the additive group, commuting with multiplication by an element of the ring. A ring with domain of operators $ \Sigma $, or, more succinctly, a $ \Sigma $- operator ring, can also be treated as a universal algebra with two binary operations (addition and multiplication) and with a set $ \Sigma $ of unary operations linked by the usual ring identities as well as by the identities (1) and (2). The concepts of a $ \Sigma $- permissible subring, a $ \Sigma $- permissible ideal, a $ \Sigma $- operator isomorphism, and a $ \Sigma $- operator homomorphism can be defined in the same way as for groups with operators (cf. Operator group). If a $ \Sigma $- operator ring $ R $ possesses a unit element, then all ideals and all one-sided ideals of the ring $ R $ are $ \Sigma $- permissible.
A ring $ R $ is called a ring with a ring of operators $ \Sigma $ if it is a $ \Sigma $- operator ring whose domain of operators $ \Sigma $ is itself an associative ring, while for any $ \alpha , \beta \in \Sigma $ and $ a \in R $ the following equalities hold:
$$ \tag{3 } a( \alpha + \beta ) = a \alpha + a \beta , $$
$$ \tag{4 } a( \alpha \beta ) = ( a \alpha ) \beta . $$
A ring with a ring of operators can also be defined as a ring which is simultaneously a $ \Sigma $- module and which satisfies axiom (2). Every ring can naturally be considered as an operator ring over the ring of integers.
For all $ a $ from $ R $ and $ \alpha , \beta $ from $ \Sigma $, the element $ a( \alpha \beta - \beta \alpha ) $ is an annihilator of $ R $. Therefore, if $ R $ is a ring with operators without annihilators, then its ring of operators $ \Sigma $ must be commutative.
The most commonly studied rings with operators are those with an associative-commutative ring of operators possessing a unit element. This type of ring is usually called an algebra over a commutative ring, and also a linear algebra. The most commonly studied linear algebras are those over fields; the theory of these algebras is evolving in parallel with the general theory of rings (without operators).
References
| [1] | A.G. Kurosh, "Lectures on general algebra" , Chelsea (1963) (Translated from Russian) |
Comments
Thus, the bilinearity properties (1), (2) and the module properties (3), (4) are practically incompatible for rings $ A $ with a non-commutative ring of operators $ R $ in that $ b \cdot a ( \alpha \beta - \beta \alpha ) = 0 $ for all $ a, b \in A $, $ \alpha , \beta \in R $. This explains why algebras are usually only considered over commutative rings. Instead of algebra (over a ring) one also sometimes finds vector algebra. Both this phrase and the phrase linear algebra for an algebra over a ring are nowadays rarely used.
For algebras over non-commutative rings the bilinearity property (2) is weakened to $ ( ab) \alpha = a( b \alpha ) $. Cf. also Algebra and Ring.
Ring with operators. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Ring_with_operators&oldid=17809