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Embedding theorems in finite soluble groupsHughes, Peter Walter January 1971 (has links)
By a group we will mean a finite soluble group. It is an interesting fact, (Pardoe [1]), that the subgroup closure of the class of groups P[symbol omitted], those with a unique complemented chief series, is all groups. Let X be the class of groups with a complemented chief series. We investigate the action of closure operations T such that TX = X upon P[symbol omitted]. The purpose of this is to find a collection of such closure operations whose join applied to P[symbol omitted] is X . In the course of this investigation we introduce a new closure operation M defined by;
MY = { G | G = <X₁,•••,Xn>, X₁ ɛ Y,
X₁ sn G, ( |G : X₁|,•••,|G : Xn| ) = 1 } / Science, Faculty of / Mathematics, Department of / Graduate
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On the theory and examples of group extensions.Rodrigues, Bernardo Gabriel. January 1999 (has links)
The work described in this dissertation was largely motivated by the aim of producing a survey on the theory of group extensions. From the broad scope of the theory of group extensions we single out two aspects to discuss, namely the study of the split and the non-split cases and give examples of both. A great part of this dissertation is dedicated to the study of split extensions. After setting the background theory for the study of the split extensions we proceed in exploring the ramifications of this concept within the development of the group structure and consequently investigate well known products which are its derived namely the holomorph, and the wreath product. The theory of group presentations provides in principle the necessary tools that permit the description of a group by means of its generators and relators. Through this knowledge we give presentations for the groups of order pq,p2q and p3. Subsequently using a classical result of Gaschutz we investigate the split extensions of
non-abelian groups in which the normal subgroup is either a non-abelian normal nilpotent group or a non-abelian normal solvable group. We also study other cases of split extensions such as the affine subgroups of the general linear and the symplectic groups. It is expected that some of the results obtained will provide a theoretical algorithm to describe these affine subgroups. A particular case of the non-split extensions is discussed as the Frattini extensions. In fact a simplest example of a Frattini extension is a non-split extension in which the kernel of an epimorphism e is an irreducible G-module. / Thesis (M.Sc.)-University of Natal, Pietermaritzburg, 1999.
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Fischer-Clifford theory for split and non-split group extensions.January 2001 (has links)
The character table of a finite group provides considerable amount of information about the group, and hence is of great importance in Mathematics as well as in Physical Sciences. Most of the maximal subgroups of the finite simple groups and their automorphisms are of extensions of elementary abelian groups, so methods have been developed for calculating the character tables of extensions of elementary abelian groups. Character tables of finite groups can be constructed using various techniques. However Bernd Fischer presented a powerful and interesting technique for calculating the character tables of group extensions. This technique, which is known as the technique of the Fischer-Clifford matrices, derives its fundamentals from the Clifford theory. If G=N.G is an appropriate extension of N by G, the method involves the construction of a nonsingular matrix for each conjugacy class of G/N~G. The character table of G can then be determined from these Fischer-Clifford matrices and the character table of certain subgroups of G, called inertia factor groups. In this dissertation, we described the Fischer-Clifford theory and apply it to both split and non-split group extensions. First we apply the technique to the split extensions 2,7:Sp6(2) and 2,8:SP6(2) which are maximal subgroups of Sp8(2) and 2,8:08+(2) respectively. This technique has also been discussed and used by many other researchers, but applied only to split extensions or to the case when every irreducible character of N can be extended to an irreducible character of its inertia group in G. However the same method can not be used to construct character tables of certain non-split group extensions. In particular, it can not be applied to the non-split extensions of the forms 3,7.07(3) and 3,7.(0,7(3):2) which are maximal subgroups of Fischer's largest sporadic simple group Fi~24 and its automorphism group Fi24 respectively. In an attempt to generalize these methods to such type of non-split group extensions, we need to consider the projective representations and characters. We have shown that how the technique of Fischer-Clifford matrices can be applied to any such type of non-split extensions. However in order to apply this technique, the projective characters of the inertia factors must be known and these can be difficult to determine for some groups. We successfully applied the technique of Fischer-Clifford matrices and determined the Fischer-Clifford matrices and hence the character tables of the non-split extensions 3,7.0,7(3) and 3,7.(0,7(3):2). The character tables computed in this thesis have been accepted for incorporation into GAP and will be available in the latest versions. / Thesis (Ph.D)-University of Natal, Pietermaritzburg, 2001.
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Fischer-Clifford theory and character tables of group extensions.Mpono, Zwelethemba Eugene. January 1998 (has links)
The smallest Fischer sporadic simple group Fi22 is generated by a conjugacy class D of 3510 involutions called 3-transpositions such that the product of any noncommuting pair is an element of order 3. In Fi22 there are exactly three conjugacy classes of involutions denoted by D, T and N and represented in the ATLAS [26] by 2A, 2B and 2C, containing 3510, 1216215 and 36486450 elements with corresponding centralizers
2·U(6,2), (2 x 2~+8:U(4,2)):2 and 25+8:(83 X 32:4) respectively. In Fi22 , we have Npi22(26) = 26:8P(6,2), where 26 is a 2B-pure group, and thus the maximal subgroup 26:8P(6, 2) of Fi22 is a 2-local subgroup. The full automorphism group of Fi22 is denoted by Fi22 . In Fi22 , there are three involutory outer automorphisms of Fi22 which are denoted bye, f and 0 and
represented in the ATLAS [26] by 2D, 2F and 2E respectively. We obtain that Fi22 = Fi22 :(e) and it can be easily shown that Fi22 = Fi22 :(e) = Fi22 :(f) = Fi22 :(0). As e, f and 0 act on Fi22 , then we obtain the subgroups CPi22 (e) rv 0+(8,2):83, CPi22 (f) rv 8P(6,2) x 2 and CPi22 (()) rv 26:0-(6,2) of Fi22 which are generated by CD(e), Cn(f) and CD(0) respectively.
In this thesis we are concerned with the construction of the character tables of certain groups which are associated with Fi22 and its automorphism group Fi22 . We use the technique of the Fischer-Clifford matrices to construct the character tables of these groups, which are split extensions. These groups are 26:8P(6, 2), 26:0-(6,2) and 27:8P(6, 2). The study of the group 26:8P(6, 2) is essential, as the other groups studied in this thesis are related to it. The groups 8P(6,2) and 0- (6,2) of 6 x 6
matrices over GF(2), played crucial roles in our construction of the group 8P(6, 2) as a group of 7 x 7 matrices over GF(2) which would act on 27 . Also the character table of 25:86 , the affine subgroup of 8P(6, 2) fixing a nonzero vector in 26 , is constructed by using the technique of the Fischer-Clifford matrices. This character table is used in the construction of the character table 26:SP(6, 2). The character tables computed in this thesis have been accepted for incorporation into GAP and will be available in the latest version of GAP. / Thesis (Ph.D.) - University of Natal, Pietermaritzburg, 1998.
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Philanthropy, policy, and politics : power and influence of health care nonprofit interest groups on the implementation of health care policyQaddoura, Fady A. 29 March 2018 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Nonprofit organizations that “speak for, act for, and look after the interests of their
constituents when they interact with government are, by any definition of political
science, interest groups.” Indiana’s recent implementation of the Healthy Indiana
Plan 2.0 (HIP 2.0) under the Affordable Care Act (ACA) opened a window of
opportunity to closely examine the role of nonprofits in shaping the
implementation of health care policy. Existing literature on health and human
service nonprofit organizations did not examine in depth the role and influence of
nonprofits as interest groups in the implementation of public policy. This study
examines a deeper research question that was not given adequate attention
under existing studies with a special focus on the health care policy field: whose
interest do nonprofit organizations advance when they attempt to influence the
implementation of public policy? To answer this question, it is critical to
understand why nonprofits engage in the public policy process (motivation and
values), the policy actions that nonprofits make during the implementation of the
policy (how?), and the method by which nonprofits address or mitigate conflicts
and contradictions between organizational interest and constituents’ interest
(whose interest do they advance?).
The main contribution of this study is that it sheds light on the implementation of
the largest extension of domestic social welfare policy since the “War on Poverty”
using Robert Alford’s theory of interest groups to examine the role of nonprofit
organizations during the implementation of HIP 2.0 in Indiana. Given the
complexity of the policy process, this study utilizes a qualitative methods
approach to complement existing quantitative findings. Finally, this study
provides a deeper examination of the relationships between nonprofits as actors within a policy field, accounts for the complexity of the policy and political
environment, analyzes whether or not dominant interest groups truly advance the
interest of their constituents, and provides additional insights into how nonprofits
mitigate and prioritize competing interests.
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Quantum Algorithm for the Non Abelian Hidden Subgroup Problem / Algoritmos Quânticos para o Problema do Subgrupo Oculto não AbelianoCarlos Magno Martins Cosme 13 March 2008 (has links)
We present an efficient quantum algorithm for the Hidden Subgroup Problem (HSP) on the semidirect product of the cyclic groups and , where is any odd prime number, and are positives integers and the homomorphism which defines the group is given by the root such that . As a consequence we can solve efficiently de HSP on the semidirect product of the groups by , where has a special prime factorization. / Neste trabalho apresentamos um algoritmo quântico eficiente para o Problema do Subgrupos Oculto (PSO) no produto semidireto dos grupos cíclicos e , onde é qualquer número primo ímpar, e são inteiros positivos e o homomorfismo que define o grupo é dado por uma raiz para a qual . Como conseqüência, podemos resolver eficientemente o PSO também no produto semidireto dos grupos por , onde o inteiro possui uma especial fatoração prima.
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Algoritmos quânticos para o problema do subgrupo oculto não Abeliano / Quantum Algorithm for the Non Abelian Hidden Subgroup ProblemCosme, Carlos Magno Martins 13 March 2008 (has links)
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Previous issue date: 2008-03-13 / Conselho Nacional de Desenvolvimento Cientifico e Tecnologico / We present an efficient quantum algorithm for the Hidden Subgroup Problem (HSP) on the semidirect product of the cyclic groups and , where is any odd prime number, and are positives integers and the homomorphism which defines the group is given by the root such that . As a consequence we can solve efficiently de HSP on the semidirect product of the groups by , where has a special prime factorization. / Neste trabalho apresentamos um algoritmo quântico eficiente para o Problema do Subgrupos Oculto (PSO) no produto semidireto dos grupos cíclicos e , onde é qualquer número primo ímpar, e são inteiros positivos e o homomorfismo que define o grupo é dado por uma raiz para a qual . Como conseqüência, podemos resolver eficientemente o PSO também no produto semidireto dos grupos por , onde o inteiro possui uma especial fatoração prima.
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Equations de Stokes et de Navier-Stokes avec des conditions aux limites de Navier / Stokes and Navier-Stokes equations with Navier boundary conditionsRejaiba, Ahmed 11 November 2014 (has links)
Résumé : Cette thèse est consacrée à l'étude des équations de Stokes et de Navier-Stokes avec des conditions aux limites de Navier dans un ouvert borné de . Le manuscrit ici est composé de trois chapitres. Dans le premier, nous considérons les équations de Stokes stationnaires avec des conditions aux limites de Navier. Nous démontrons l'existence, l'unicité et la régularité de la solution d'abord dans un cadre hilbertien puis dans le cadre de la théorie . Nous traitons aussi le cas de solutions très faibles. Dans le deuxième chapitre, nous nous intéressons aux équations de Navier-Stokes avec la condition de Navier. Sous certaines hypothèses sur les données, nous démontrons l'existence de solution faible dans , avec en utilisant un théorème du point fixe appliqué à un problème d'Oseen. Nous démontrons examinons ensuite les questions de régularité des solutions en particulier dans . Dans le dernier chapitre, nous étudions le problème d'évolution de Stokes avec la condition de Navier. La résolution de ce problème se fait au moyen de la théorie des semi-groupes analytiques qui jouent un rôle important pour établir l'existence et l'unicité de la solution dans le cas homogène. Nous traitons le cas du problème non homogène par le biais des puissances imaginaires de l'opérateur de Stokes. / This thesis is devoted to the study of the Stokes equations and Navier-Stokes equations with Navier boundary conditions in a bounded domain of . The work contains three chapters: In the first chapter, we consider the stationary Stokes equations with Navier boundary condition. We show the existence, uniqueness and regularity of the solution in the Hilbert case and in the -theory. We prove also the case of very weak solutions. In the second chapter, we focus on the Navier-Stokes equations with the Navier boundary condition. We show the existence of the weak solution in , with by a fixed point theorem over the Oseen equation. We show also the existence of the strong solution in . In chapter three, we study the evolution Stokes problem with Navier boundary condition. For this, we apply the analytic semi-groups theory, which plays a crucial role in the study of existence and uniqueness of solution in the case of the homogeneous evolution problem. We treat the case of non-homogeneous problem through imaginary powers of the Stokes operator.
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