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Gröbner Bases Theory and The Diamond LemmaGe, Wenfeng January 2006 (has links)
Commutative Gröbner bases theory is well known and widely used. In this thesis, we will discuss thoroughly its generalization to noncommutative polynomial ring <em>k</em><<em>X</em>> which is also an associative free algebra. We introduce some results on monomial orders due to John Lawrence and the author. We show that a noncommutative monomial order is a well order while a one-sided noncommutative monomial order may not be. Then we discuss the generalization of polynomial reductions, S-polynomials and the characterizations of noncommutative Gröbner bases. Some results due to Mora are also discussed, such as the generalized Buchberger's algorithm and the solvability of ideal membership problem for homogeneous ideals. At last, we introduce Newman's diamond lemma and Bergman's diamond lemma and show their relations with Gröbner bases theory.
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Gröbner Bases Theory and The Diamond LemmaGe, Wenfeng January 2006 (has links)
Commutative Gröbner bases theory is well known and widely used. In this thesis, we will discuss thoroughly its generalization to noncommutative polynomial ring <em>k</em><<em>X</em>> which is also an associative free algebra. We introduce some results on monomial orders due to John Lawrence and the author. We show that a noncommutative monomial order is a well order while a one-sided noncommutative monomial order may not be. Then we discuss the generalization of polynomial reductions, S-polynomials and the characterizations of noncommutative Gröbner bases. Some results due to Mora are also discussed, such as the generalized Buchberger's algorithm and the solvability of ideal membership problem for homogeneous ideals. At last, we introduce Newman's diamond lemma and Bergman's diamond lemma and show their relations with Gröbner bases theory.
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A graded subring of an inverse limit of polynomial ringsSnellman, Jan January 1998 (has links)
<p>We study the power series ring R= K[[x<sub>1</sub>,x<sub>2</sub>,x<sub>3</sub>,...]]on countably infinitely many variables, over a field K, and two particular K-subalgebras of it: the ring S, which is isomorphic to an inverse limit of the polynomial rings in finitely many variables over K, and the ring R', which is the largest graded subalgebra of R.</p><p>Of particular interest are the homogeneous, finitely generated ideals in R', among them the <i>generic ideals</i>. The definition of S as an inverse limit yields a set of <i>truncation homomorphisms</i> from S to K[x<sub>1</sub>,...,x<sub>n</sub>] which restrict to R'. We have that the truncation of a generic I in R' is a generic ideal in K[x<sub>1</sub>,...,x<sub>n</sub>]. It is shown in <b>Initial ideals of Truncated Homogeneous Ideals</b> that the initial ideal of such an ideal converge to the initial ideal of the corresponding ideal in R'. This initial ideal need no longer be finitely generated, but it is always <i>locally finitely generated</i>: this is proved in <b>Gröbner Bases in R'</b>. We show in <b>Reverse lexicographic initial ideals of generic ideals are finitely generated</b> that the initial ideal of a generic ideal in R' is finitely generated. This contrast to the lexicographic term order.</p><p> If I in R' is a homogeneous, locally finitely generated ideal, and if we write the Hilbert series of the truncated algebras K[x<sub>1</sub>,...,x<sub>n</sub>] module the truncation of I as q<sub>n</sub>(t)/(1-t)<sup>n</sup>, then we show in <b>Generalized Hilbert Numerators </b>that the q<sub>n</sub>'s converge to a power series in t which we call the <i>generalized Hilbert numerator</i> of the algebra R'/I.</p><p>In <b>Gröbner bases for non-homogeneous ideals in R'</b> we show that the calculations of Gröbner bases and initial ideals in R' can be done also for some non-homogeneous ideals, namely those which have an <i>associated homogeneous ideal</i> which is locally finitely generated.</p><p>The fact that S is an inverse limit of polynomial rings, which are naturally endowed with the discrete topology, provides S with a topology which makes it into a complete Hausdorff topological ring. The ring R', with the subspace topology, is dense in R, and the latter ring is the Cauchy completion of the former. In <b>Topological properties of R'</b> we show that with respect to this topology, locally finitely generated ideals in R'are <i>closed</i>.</p>
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A graded subring of an inverse limit of polynomial ringsSnellman, Jan January 1998 (has links)
We study the power series ring R= K[[x1,x2,x3,...]]on countably infinitely many variables, over a field K, and two particular K-subalgebras of it: the ring S, which is isomorphic to an inverse limit of the polynomial rings in finitely many variables over K, and the ring R', which is the largest graded subalgebra of R. Of particular interest are the homogeneous, finitely generated ideals in R', among them the generic ideals. The definition of S as an inverse limit yields a set of truncation homomorphisms from S to K[x1,...,xn] which restrict to R'. We have that the truncation of a generic I in R' is a generic ideal in K[x1,...,xn]. It is shown in <b>Initial ideals of Truncated Homogeneous Ideals</b> that the initial ideal of such an ideal converge to the initial ideal of the corresponding ideal in R'. This initial ideal need no longer be finitely generated, but it is always locally finitely generated: this is proved in <b>Gröbner Bases in R'</b>. We show in <b>Reverse lexicographic initial ideals of generic ideals are finitely generated</b> that the initial ideal of a generic ideal in R' is finitely generated. This contrast to the lexicographic term order. If I in R' is a homogeneous, locally finitely generated ideal, and if we write the Hilbert series of the truncated algebras K[x1,...,xn] module the truncation of I as qn(t)/(1-t)n, then we show in <b>Generalized Hilbert Numerators </b>that the qn's converge to a power series in t which we call the generalized Hilbert numerator of the algebra R'/I. In <b>Gröbner bases for non-homogeneous ideals in R'</b> we show that the calculations of Gröbner bases and initial ideals in R' can be done also for some non-homogeneous ideals, namely those which have an associated homogeneous ideal which is locally finitely generated. The fact that S is an inverse limit of polynomial rings, which are naturally endowed with the discrete topology, provides S with a topology which makes it into a complete Hausdorff topological ring. The ring R', with the subspace topology, is dense in R, and the latter ring is the Cauchy completion of the former. In <b>Topological properties of R'</b> we show that with respect to this topology, locally finitely generated ideals in R'are closed.
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Bases de Grobner aplicadas à k-coloração de grafos / Application of Grobner bases in graph k-coloringStaib, Frederico Fontes 12 March 2010 (has links)
Orientador: Patrícia Helena Araújo da Silva Nogueira / Dissertação (mestrado profissional) - Universidade Estadual de Campinas, Instituto de Matemática, Estatística e Computação Científica / Made available in DSpace on 2018-08-17T08:03:36Z (GMT). No. of bitstreams: 1
Staib_FredericoFontes_M.pdf: 14016255 bytes, checksum: 4ec6112a82029b5e16c1c450779bf803 (MD5)
Previous issue date: 2010 / Resumo: Neste trabalho, estudamos a teoria das bases de Gröbner e sua aplicação ao problema da k-coloração de grafos, estabelecendo assim uma interessante conexão entre a álgebra abstrata e a matemática discreta. Fazemos também uma abordagem de caráter lúdico, traduzindo o passatempo chamado Sudoku em um problema de 9-coloração e utilizando a teoria apresentada para resolvê-lo através das bases de Gröbner / Abstract: In the present work, we study the Gröbner basis theory and its application on the graph k-coloring problem, establishing an interesting relation between abstract algebra and discrete mathematics. We make a ludic approach, translating the puzzle called Sudoku to a 9-coloring problem and using the given theory to solve it by the Gröbner basis / Mestrado / Algebra / Mestre em Matemática
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Minimal Primary Decomposition and Factorized Gröbner BasesGräbe, Hans-Gert 25 January 2019 (has links)
This paper continues our study of applications of factorized Gröbner basis computations in [8] and [9]. We describe a way to interweave factorized Gröbner bases and the ideas in [5] that
leads to a significant speed up in the computation of isolated primes for well splitting examples. Based on that observation we generalize the algorithm presented in [22] to the computation of primary decompositions for modules. It rests on an ideal separation argument. We also discuss the practically important question how to extract a minimal primary decomposition, neither addressed in [5] nor in [17]. For that purpose we outline a method to detect necessary embedded primes in the output collection of our algorithm, similar to [22, cor. 2.22]. The algorithms are partly implemented in version 2.2.1 of our REDUCE package CALI [7].
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Algorithms in Local AlgebraGräbe, Hans-Gert 25 January 2019 (has links)
Let k be a field, S = k[xv : v ϵ V] be the polynomial ring over the finite set of variables (xv : v ϵ V), and m = (xv : v ϵ V) the ideal defining the origin of Spec S.
It is theoretically known (see e.g. Alonso et el., 1991) that the algorithmic ideas for the computation of ideal (and module) intersections, quotients, deciding radical membership etc. in S may be adopted not only for computations in the local ring Sm but also for term orders of mixed type with standard bases replacing Gröbner bases. Using the generalization of Mora's tangent cone algorithm to arbitrary term orders we give a detailed description of the necessary modifications and restrictions.
In a second part we discuss a generalization of the deformation argument for standard bases and independent sets to term orders of mixed type. For local term orders these questions were investigated in Gräbe (1991).
The main algorithmic ideas described are implemented in the author's REDUCE package CALI (Gräbe, 1993a).
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Gröbner Geometry for Hessenberg VarietiesCummings, Mike January 2024 (has links)
We study Hessenberg varieties in type A via their local defining equations, called patch ideals. We focus on two main classes of Hessenberg varieties: those associated to a regular nilpotent operator and to those associated to a semisimple operator.
In the setting of regular semisimple Hessenberg varieties, which are known to be smooth and irreducible, we determine that their patch ideals are triangular complete intersections, as defined by Da Silva and Harada. For semisimple Hessenberg varieties, we give a partial positive answer to a conjecture of Insko and Precup that a given family of set-theoretic local defining ideals are radical.
A regular nilpotent Hessenberg Schubert cell is the intersection of a Schubert cell with a regular nilpotent Hessenberg variety. Following the work of the author with Da Silva, Harada, and Rajchgot, we construct an embedding of the regular nilpotent Hessenberg Schubert cells into the coordinate chart of the regular nilpotent Hessenberg variety corresponding to the longest-word permutation in Bruhat order. This allows us to use work of Da Silva and Harada to conclude that regular nilpotent Hessenberg Schubert cells are also local triangular complete intersections. / Thesis / Master of Science (MSc) / Algebraic varieties provide a generalization of curves in the plane, such as parabolas and ellipses. One such family of these varieties are called Hessenberg varieties, and they are known to have connections to other areas of pure and applied mathematics, including to numerical linear algebra, combinatorics, and geometric representation theory.
In this thesis, we view Hessenberg varieties as a collection of subvarieties, called coordinate charts, and study the computational geometry of each coordinate chart. Although this is a local approach, we recover global geometric data on Hessenberg varieties. We also provide a partial positive answer to an open question in the area.
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MULTIVARIATE LIST DECODING OF EVALUATION CODES WITH A GRÖBNER BASIS PERSPECTIVEBusse, Philip 01 January 2008 (has links)
Please download dissertation to view abstract.
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Toric Ideals, Polytopes, and Convex Neural CodesLienkaemper, Caitlin 01 January 2017 (has links)
How does the brain encode the spatial structure of the external world?
A partial answer comes through place cells, hippocampal neurons which
become associated to approximately convex regions of the world known
as their place fields. When an organism is in the place field of some place
cell, that cell will fire at an increased rate. A neural code describes the set
of firing patterns observed in a set of neurons in terms of which subsets
fire together and which do not. If the neurons the code describes are place
cells, then the neural code gives some information about the relationships
between the place fields–for instance, two place fields intersect if and only if
their associated place cells fire together. Since place fields are convex, we are
interested in determining which neural codes can be realized with convex
sets and in finding convex sets which generate a given neural code when
taken as place fields. To this end, we study algebraic invariants associated
to neural codes, such as neural ideals and toric ideals. We work with a
special class of convex codes, known as inductively pierced codes, and seek
to identify these codes through the Gröbner bases of their toric ideals.
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