Exercises in Classical Ring TheorySpringer Science & Business Media, 9 mai 2006 - 364 pages This useful book, which grew out of the author's lectures at Berkeley, presents some 400 exercises of varying degrees of difficulty in classical ring theory, together with complete solutions, background information, historical commentary, bibliographic details, and indications of possible improvements or generalizations. The book should be especially helpful to graduate students as a model of the problem-solving process and an illustration of the applications of different theorems in ring theory. The author also discusses "the folklore of the subject: the `tricks of the trade' in ring theory, which are well known to the experts in the field but may not be familiar to others, and for which there is usually no good reference". The problems are from the following areas: the Wedderburn-Artin theory of semisimple rings, the Jacobson radical, representation theory of groups and algebras, (semi)prime rings, (semi)primitive rings, division rings, ordered rings, (semi)local rings, the theory of idempotents, and (semi)perfect rings. Problems in the areas of module theory, category theory, and rings of quotients are not included, since they will appear in a later book. T. W. Hungerford, Mathematical Reviews |
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... rings, Jacobson's theory of the radical, and the representation theory of groups and algebras, then continuing with prime and semiprime rings, primitive and semiprimitive rings, division rings, ordered rings, local and semilocal rings ...
... rings, Jacobson's theory of the radical, and the representation theory of groups and algebras, then continuing with prime and semiprime rings, primitive and semiprimitive rings, division rings, ordered rings, local and semilocal rings ...
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... Rings ............................. 141 §10. The Prime Radical; Prime and Semiprime Rings . . . . . . . . . . 141 32 Exercises §11. Structure of Primitive Rings; the ... Division Rings.......................... 201 §13. Division Rings ...
... Rings ............................. 141 §10. The Prime Radical; Prime and Semiprime Rings . . . . . . . . . . 141 32 Exercises §11. Structure of Primitive Rings; the ... Division Rings.......................... 201 §13. Division Rings ...
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... division ring. To verify that a nonzero ring R is a division ring, it suffices to check that every a ∈ R\{0} is right-invertible: see Exercise 2 below. All (say, left) R-modules RM are assumed to be unital, that is, 1 · m = m for all m ...
... division ring. To verify that a nonzero ring R is a division ring, it suffices to check that every a ∈ R\{0} is right-invertible: see Exercise 2 below. All (say, left) R-modules RM are assumed to be unital, that is, 1 · m = m for all m ...
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... ring S of 2 × 2 upper triangular matrices over k. (The fact that R ∼= S is a special case of Exercise 1.22(1) below.) Ex. 1.19. Let R be a domain. If R has a minimal left ideal, show that R is a division ring. (In particular, a left ...
... ring S of 2 × 2 upper triangular matrices over k. (The fact that R ∼= S is a special case of Exercise 1.22(1) below.) Ex. 1.19. Let R be a domain. If R has a minimal left ideal, show that R is a division ring. (In particular, a left ...
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... division ring. If S(R/A) is cyclic, R/A is a 1-dimensional left E-vector space. Since S/A is a nonzero E-subspace in R/A, we must have S = R, from which (4) follows immediately. Ex. 1.29B. Let R be a ring with center C. Show that a ...
... division ring. If S(R/A) is cyclic, R/A is a 1-dimensional left E-vector space. Since S/A is a nonzero E-subspace in R/A, we must have S = R, from which (4) follows immediately. Ex. 1.29B. Let R be a ring with center C. Show that a ...
Table des matières
Jacobson Radical Theory | 49 |
Introduction to Representation Theory | 99 |
Ordered Structures in Rings 247 | 246 |
Perfect and Semiperfect Rings 325 | 324 |
Name Index | 349 |
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Expressions et termes fréquents
0-divisor 2-primal abelian algebra artinian ring assume automorphism commutative ring conjugate constructed contradiction cyclic Dedekind-finite defined direct product direct summand division ring domain element endomorphism equation Exercise exists fact field finite group finite-dimensional follows group G hence homomorphism hopfian idempotent identity implies indecomposable induction infinite integer inverse irreducible isomorphism J-semisimple Jacobson radical k-algebra kG-module left ideal left primitive Lemma Let G local ring Math maximal ideal maximal left ideal Mn(k Mn(R module multiplication Neumann regular ring nil ideal Nilº noetherian ring noncommutative nonzero polynomial prime ideal primitive rings proof prove R-module R/rad rad kG representation resp right ideal right R-module ring theory semilocal ring semiprime semisimple ring show that rad simple ring Solution stable range subdirect product subgroup submodule subring suffices to show surjective Theorem unit-regular von Neumann regular zero