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1	From multisets to matrix groups : some algorithms related to the exterior square Greenhill, Catherine January 1996 (has links) No description available. 510 Polynomials; Abelian group elements
2	O-minimal expansions of groups Edmundo, Mario Jorge January 1999 (has links) No description available. 510
3	The Cohomology Ring of a Finite Abelian Group Roberts, Collin Donald 11 January 2013 (has links) The cohomology ring of a finite cyclic group was explicitly computed by Cartan and Eilenberg in their 1956 book on Homological Algebra. It is surprising that the cohomology ring for the next simplest example, that of a finite abelian group, has still not been treated in a systematic way. The results that we do have are combinatorial in nature and have been obtained using "brute force" computations. In this thesis we will give a systematic method for computing the cohomology ring of a finite abelian group. A major ingredient in this treatment will be the Tate resolution of a commutative ring R (with trivial group action) over the group ring RG, for some finite abelian group G. Using the Tate resolution we will be able to compute the cohomology ring for a finite cyclic group, and confirm that this computation agrees with what is known from Cartan-Eilenberg. Then we will generalize this technique to compute the cohomology ring for a finite abelian group. The presentation we will give is simpler than what is in the literature to date. We will then see that a straightforward generalization of the Tate resolution from a group ring to an arbitrary ring defined by monic polynomials will yield a method for computing the Hochschild cohomology algebra of that ring. In particular we will re-prove some results from the literature in a much more unified way than they were originally proved. We will also be able to prove some new results. Group Cohomology Cohomology Ring Finite Abelian Group Pure Mathematics
4	Reciprocal class of random walks on an Abelian group Conforti, Giovanni, Roelly, Sylvie January 2015 (has links) Processes having the same bridges as a given reference Markov process constitute its reciprocal class. In this paper we study the reciprocal class of a continuous time random walk with values in a countable Abelian group, we compute explicitly its reciprocal characteristics and we present an integral characterization of it. Our main tool is a new iterated version of the celebrated Mecke's formula from the point process theory, which allows us to study, as transformation on the path space, the addition of random loops. Thanks to the lattice structure of the set of loops, we even obtain a sharp characterization. At the end, we discuss several examples to illustrate the richness of reciprocal classes. We observe how their structure depends on the algebraic properties of the underlying group. reciprocal class stochastic bridge random walk on Abelian group Mathematics
5	The Cohomology Ring of a Finite Abelian Group Roberts, Collin Donald 11 January 2013 (has links) The cohomology ring of a finite cyclic group was explicitly computed by Cartan and Eilenberg in their 1956 book on Homological Algebra. It is surprising that the cohomology ring for the next simplest example, that of a finite abelian group, has still not been treated in a systematic way. The results that we do have are combinatorial in nature and have been obtained using "brute force" computations. In this thesis we will give a systematic method for computing the cohomology ring of a finite abelian group. A major ingredient in this treatment will be the Tate resolution of a commutative ring R (with trivial group action) over the group ring RG, for some finite abelian group G. Using the Tate resolution we will be able to compute the cohomology ring for a finite cyclic group, and confirm that this computation agrees with what is known from Cartan-Eilenberg. Then we will generalize this technique to compute the cohomology ring for a finite abelian group. The presentation we will give is simpler than what is in the literature to date. We will then see that a straightforward generalization of the Tate resolution from a group ring to an arbitrary ring defined by monic polynomials will yield a method for computing the Hochschild cohomology algebra of that ring. In particular we will re-prove some results from the literature in a much more unified way than they were originally proved. We will also be able to prove some new results. Group Cohomology Cohomology Ring Finite Abelian Group Pure Mathematics
6	The non-cancellation groups of certain groups which are split extensions of a finite abelian group by a finite rank free abelian group. Mkiva, Soga Loyiso Tiyo. January 2008 (has links) <p>&nbsp / </p> <p align="left">The groups we consider in this study belong to the class <font face="F30">X</font><font face="F25" size="1"><font face="F25" size="1">0 </font></font><font face="F15">of all finitely generated groups with finite commutator subgroups.</font></p> Automorphism Finite abelian group Finitely generated group Finite rank free group.
7	The non-cancellation groups of certain groups which are split extensions of a finite abelian group by a finite rank free abelian group. Mkiva, Soga Loyiso Tiyo. January 2008 (has links) <p>&nbsp / </p> <p align="left">The groups we consider in this study belong to the class <font face="F30">X</font><font face="F25" size="1"><font face="F25" size="1">0 </font></font><font face="F15">of all finitely generated groups with finite commutator subgroups.</font></p> Automorphism Finite abelian group Finitely generated group Finite rank free group.
8	The non-cancellation groups of certain groups which are split extensions of a finite abelian group by a finite rank free abelian group Mkiva, Soga Loyiso Tiyo January 2008 (has links) Magister Scientiae - MSc / The groups we consider in this study belong to the class X0 of all nitely generated groups with nite commutator subgroups. We shall eventually narrow down to the groups of the form T owZn for some n 2 N and some nite abelian group T. For a X0-group H, we study the non-cancellation set, (H), which is de ned to be the set of all isomorphism classes of groups K such that H Z = K Z. For X0-groups H, on (H) there is an abelian group structure [38], de ned in terms of embeddings of K into H, for groups K of which the isomorphism classes belong to (H). If H is a nilpotent X0-group, then the group (H) is the same as the Hilton-Mislin (see [10]) genus group G(H) of H. A number of calculations of such Hilton-Mislin genus groups can be found in the literature, and in particular there is a very nice calculation in article [11] of Hilton and Scevenels. The main aim of this thesis is to compute non-cancellation (or genus) groups of special types of X0-groups such as mentioned above. The groups in question can in fact be considered to be direct products of metacyclic groups, very much as in [11]. We shall make extensive use of the methods developed in [30] and employ computer algebra packages to compute determinants of endomorphisms of nite groups. / South Africa Automorphism Finite abelian group Finitely generated group Finite rank free group
9	Schur Rings over Infinite Groups Dexter, Cache Porter 01 February 2019 (has links) A Schur ring is a subring of the group algebra with a basis that is formed by a partition of the group. These subrings were initially used to study finite permutation groups, and classifications of Schur rings over various finite groups have been studied. Here we investigate Schur rings over various infinite groups, including free groups. We classify Schur rings over the infinite cyclic group. Schur ring permutation group free group free abelian group infinite cyclic group Mathematics
10	The non-cancellation groups of certain groups which are split extensions of a finite abelian group by a finite rank free abelian group Mkiva, Soga Loyiso Tiyo January 2008 (has links) >Magister Scientiae - MSc / The groups we consider in this study belong to the class Xo of all finitely generated groups with finite commutator subgroups. We shall eventually narrow down to the groups of the form T)<lw zn for some nE N and some finite abelian group T. For a Xo-group H, we study the non-cancellation set, X(H), which is defined to be the set of all isomorphism classes of groups K such that H x Z ~ K x Z. For Xo-groups H, on X(H) there is an abelian group structure [38], defined in terms of embeddings of K into H, for groups K of which the isomorphism classes belong to X(H). If H is a nilpotent Xo-group, then the group X(H) is the same as the Hilton-Mislin (see [10]) genus group Q(H) of H. A number of calculations of such Hilton-Mislin genus groups can be found in the literature, and in particular there is a very nice calculation in article [11] of Hilton and Scevenels. The main aim of this thesis is to compute non-cancellation (or genus) groups of special types of .Xo-groups such as mentioned above. The groups in question can in fact be considered to be direct products of metacyclic groups, very much as in [11]. We shall make extensive use of the methods developed in [30] and employ computer algebra packages to compute determinants of endomorphisms of finite groups. Automorphism Determinant of an endomorphism Finite abelian group Finitely generated group Finite rank free group Group action Matrix

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