Algèbres hypercomplexes pour le Calcul

Dans les domaines mathématique ou applicatif, la multiplication de nombres possède un rôle clef pour le Calcul. En Science et en Ingénierie, la nonlinéarité offre de grands défis de modélisation mais aussi de résolution. Notre approche vise, via la multiplication, l'étude de certains phénomènes non linéaires que l'on retrouve fréquemment dans le domaine de la Science et de l'Industrie. Pour cela, nous étudions dans cette thèse la multiplication de nombres multidimensionnels, associée à des structures algébriques en dimension finie appelées algèbres hypercomplexes. Nous utilisons la multiplication comme lien entre les divisions apparentes des différents domaines théorique et pratique que nous abordons par une approche transdisciplinaire. Nous effectuons une analyse comparative entre les algèbres hypercomplexes et les principaux outils de Calcul, approche qui n’est pas développée dans la littérature existante. Nous présentons une synthèse des applications existantes (par ex. robotique, modélisation 3D, électromagnétisme) et des principaux avantages des algèbres hypercomplexes, pour la Science et l’Ingénierie. A partir des conséquences de l’utilisation des structures alternatives (autres que réelles ou complexes), nous proposons une extension nouvelle de la théorie spectrale présentée sous le nom de couplage spectral. Grâce aux algèbres hypercomplexes et à la théorie du couplage spectral, nous présentons des applications inédites à la mécanique et à la chimie ainsi que des perspectives pour le domaine du calcul quantique. Pour les domaines d’applications présentés, existants ou inédits, nous étudions les aspects de modélisation théorique et aussi d’analyse numérique. Nous montrons que suivant les cas d'étude, les aspects numériques avantageux découlent d'un choix judicieux des modèles et des algèbres hypercomplexes associées. Ces avantages sont principalement dus à la manière de définir la multiplication dans les algèbres concernées. Dans les domaines applicatifs abordés, une grande partie des modèles théoriques et numériques repose actuellement sur l’utilisation des nombres réels ou complexes ainsi que sur l’algèbre linéaire. Nous montrons dans cette thèse que les algèbres hypercomplexes sont complémentaires des outils algébriques actuellement utilisés et possèdent un vaste potentiel théorique et pratique, grandement sous-exploité pour le Calcul

UNOmaha Problem of the Week (2021-2022 Edition)

The University of Omaha math department\u27s Problem of the Week was taken over in Fall 2019 from faculty by the authors. The structure: each semester (Fall and Spring), three problems are given per week for twelve weeks, with each problem worth ten points - mimicking the structure of arguably the most well-regarded university math competition around, the Putnam Competition, with prizes awarded to top-scorers at semester\u27s end. The weekly competition was halted midway through Spring 2020 due to COVID-19, but relaunched again in Fall 2021, with massive changes. Now there are three difficulty tiers to POW problems, roughly corresponding to easy/medium/hard difficulties, with each tier getting twelve problems per semester, and three problems (one of each tier) per week posted online and around campus. The tiers are named after the EPH classification of conic sections (which is connected to many other classifications in math), and in the present compilation they abide by the following color-coding: Cyan, Green, and Magenta. In practice, when creating the problem sets, we begin with a large enough pool of problem drafts and separate out the ones which are most obviously elliptic or hyperbolic, and then the remaining ones fall into parabolic. The tiers don\u27t necessarily reflect workload, though, only prerequisite mathematical background. Ideally, the solutions to elliptic problems, and any parts of solutions to parabolic and hyperbolic problems not covered in standard undergraduate courses, are meant to test participants\u27 creativity. Beware, though, many solutions also include additional commentary which varies wildly in the reader\u27s assumed mathematical maturity

Quaternion Algebras

This open access textbook presents a comprehensive treatment of the arithmetic theory of quaternion algebras and orders, a subject with applications in diverse areas of mathematics. Written to be accessible and approachable to the graduate student reader, this text collects and synthesizes results from across the literature. Numerous pathways offer explorations in many different directions, while the unified treatment makes this book an essential reference for students and researchers alike. Divided into five parts, the book begins with a basic introduction to the noncommutative algebra underlying the theory of quaternion algebras over fields, including the relationship to quadratic forms. An in-depth exploration of the arithmetic of quaternion algebras and orders follows. The third part considers analytic aspects, starting with zeta functions and then passing to an idelic approach, offering a pathway from local to global that includes strong approximation. Applications of unit groups of quaternion orders to hyperbolic geometry and low-dimensional topology follow, relating geometric and topological properties to arithmetic invariants. Arithmetic geometry completes the volume, including quaternionic aspects of modular forms, supersingular elliptic curves, and the moduli of QM abelian surfaces. Quaternion Algebras encompasses a vast wealth of knowledge at the intersection of many fields. Graduate students interested in algebra, geometry, and number theory will appreciate the many avenues and connections to be explored. Instructors will find numerous options for constructing introductory and advanced courses, while researchers will value the all-embracing treatment. Readers are assumed to have some familiarity with algebraic number theory and commutative algebra, as well as the fundamentals of linear algebra, topology, and complex analysis. More advanced topics call upon additional background, as noted, though essential concepts and motivation are recapped throughout

Notes in Pure Mathematics & Mathematical Structures in Physics

These Notes deal with various areas of mathematics, and seek reciprocal combinations, explore mutual relations, ranging from abstract objects to problems in physics.Comment: Small improvements and addition

Multicoloured Random Graphs: Constructions and Symmetry

This is a research monograph on constructions of and group actions on countable homogeneous graphs, concentrating particularly on the simple random graph and its edge-coloured variants. We study various aspects of the graphs, but the emphasis is on understanding those groups that are supported by these graphs together with links with other structures such as lattices, topologies and filters, rings and algebras, metric spaces, sets and models, Moufang loops and monoids. The large amount of background material included serves as an introduction to the theories that are used to produce the new results. The large number of references should help in making this a resource for anyone interested in beginning research in this or allied fields.Comment: Index added in v2. This is the first of 3 documents; the other 2 will appear in physic