Ring Theory
... A2 Addition is commutative. r + s = s + r for all r, s ∈ R. A3 R contains an identity element for addition, denoted by 0R and called the zero element of R. r + 0R = 0R + r = r for all r ∈ R. A4 Every element of R has an inverse with respect to addition. (The additive inverse of r is often denoted by ...
... A2 Addition is commutative. r + s = s + r for all r, s ∈ R. A3 R contains an identity element for addition, denoted by 0R and called the zero element of R. r + 0R = 0R + r = r for all r ∈ R. A4 Every element of R has an inverse with respect to addition. (The additive inverse of r is often denoted by ...
Elementary Number Theory
... A.18. Definition. A commutative ring is a set R with two binary operations, multiplication · and addition +, such that for all a, b, c in the set R we have: (a) a + b = b + a; ab = ba (commutativity) (b) a + (b + c) = (a + b) + c; a(bc) = (ab)c (associativity) (c) a(b + c) = ab + ac (distributivity) ...
... A.18. Definition. A commutative ring is a set R with two binary operations, multiplication · and addition +, such that for all a, b, c in the set R we have: (a) a + b = b + a; ab = ba (commutativity) (b) a + (b + c) = (a + b) + c; a(bc) = (ab)c (associativity) (c) a(b + c) = ab + ac (distributivity) ...
Euler`s groups of powers of prime complex integers
... Comparing Lemma 5 which we have thus proved with the sequence of the numbers of roots (mentioned above, see the text preceding Lemma 3) we deduce (from the numbers (1, 8, 64) of the roots of degrees (1, 2, 4)) that the minimal multiplier is Z2 p , where p > 2. The presence of the multiplier Z4 is im ...
... Comparing Lemma 5 which we have thus proved with the sequence of the numbers of roots (mentioned above, see the text preceding Lemma 3) we deduce (from the numbers (1, 8, 64) of the roots of degrees (1, 2, 4)) that the minimal multiplier is Z2 p , where p > 2. The presence of the multiplier Z4 is im ...
Introduction for the seminar on complex multiplication
... • A 1-dimensional abelian variety is exactly the same as an elliptic curve. • Every abelian variety over k = C is (as a complex manifold) isomorphic to a complex torus, i.e. a manifold of the form Cg /Λ, for a lattice Λ of rank 2g in Cg . A complex torus is an abelian variety if and only if it has a ...
... • A 1-dimensional abelian variety is exactly the same as an elliptic curve. • Every abelian variety over k = C is (as a complex manifold) isomorphic to a complex torus, i.e. a manifold of the form Cg /Λ, for a lattice Λ of rank 2g in Cg . A complex torus is an abelian variety if and only if it has a ...
MORE ON THE SYLOW THEOREMS 1. Introduction
... related to the Sylow theorems and formulates (but does not prove) two extensions of Sylow III to p-subgroups, by Frobenius and Weisner. 2. Sylow I by Sylow In modern language, here is Sylow’s proof that his subgroups exist. Pick a prime p dividing #G. Let P be a p-subgroup of G which is as large as ...
... related to the Sylow theorems and formulates (but does not prove) two extensions of Sylow III to p-subgroups, by Frobenius and Weisner. 2. Sylow I by Sylow In modern language, here is Sylow’s proof that his subgroups exist. Pick a prime p dividing #G. Let P be a p-subgroup of G which is as large as ...
Invariants and Algebraic Quotients
... the trivial one-dimensional module. In particular, Vsoc = V C and so C+ is not linearly reductive. Proposition 2.1. Let G be an algebraic group. The following statements are equivalent: (i) G is linearly reductive. (ii) The representation of G on O(G) (by left or right multiplication) is completely ...
... the trivial one-dimensional module. In particular, Vsoc = V C and so C+ is not linearly reductive. Proposition 2.1. Let G be an algebraic group. The following statements are equivalent: (i) G is linearly reductive. (ii) The representation of G on O(G) (by left or right multiplication) is completely ...
Dowling, T.A.; (1972)A class of geometric lattices based on finite groups."
... M6bius function and characteristic polynomial, and show that the \fuitney numbers of the partial G-partition lattices satisfy recursions and inverse relations analogous to those of the Stirling numbers. primarily to the representation problem of ...
... M6bius function and characteristic polynomial, and show that the \fuitney numbers of the partial G-partition lattices satisfy recursions and inverse relations analogous to those of the Stirling numbers. primarily to the representation problem of ...
a * b - St. Cloud State University
... • 1. GF(p) consists of p elements • 2. The binary operations + and * are defined over the set. The operations of addition, subtraction, multiplication, and division can be performed without leaving the set. Each element of the set other than 0 has a multiplicative inverse • We have shown that the el ...
... • 1. GF(p) consists of p elements • 2. The binary operations + and * are defined over the set. The operations of addition, subtraction, multiplication, and division can be performed without leaving the set. Each element of the set other than 0 has a multiplicative inverse • We have shown that the el ...
Group (mathematics)
In mathematics, a group is an algebraic structure consisting of a set of elements together with an operation that combines any two elements to form a third element. The operation satisfies four conditions called the group axioms, namely closure, associativity, identity and invertibility. One of the most familiar examples of a group is the set of integers together with the addition operation; the addition of any two integers forms another integer. The abstract formalization of the group axioms, detached as it is from the concrete nature of any particular group and its operation, allows entities with highly diverse mathematical origins in abstract algebra and beyond to be handled in a flexible way, while retaining their essential structural aspects. The ubiquity of groups in numerous areas within and outside mathematics makes them a central organizing principle of contemporary mathematics.Groups share a fundamental kinship with the notion of symmetry. For example, a symmetry group encodes symmetry features of a geometrical object: the group consists of the set of transformations that leave the object unchanged and the operation of combining two such transformations by performing one after the other. Lie groups are the symmetry groups used in the Standard Model of particle physics; Point groups are used to help understand symmetry phenomena in molecular chemistry; and Poincaré groups can express the physical symmetry underlying special relativity.The concept of a group arose from the study of polynomial equations, starting with Évariste Galois in the 1830s. After contributions from other fields such as number theory and geometry, the group notion was generalized and firmly established around 1870. Modern group theory—an active mathematical discipline—studies groups in their own right. To explore groups, mathematicians have devised various notions to break groups into smaller, better-understandable pieces, such as subgroups, quotient groups and simple groups. In addition to their abstract properties, group theorists also study the different ways in which a group can be expressed concretely (its group representations), both from a theoretical and a computational point of view. A theory has been developed for finite groups, which culminated with the classification of finite simple groups announced in 1983. Since the mid-1980s, geometric group theory, which studies finitely generated groups as geometric objects, has become a particularly active area in group theory.