Добірка наукової літератури з теми "Toroidal embedding"

We give a deterministic drawing algorithm to draw a graph onto a torus, which is based on the usual spectral drawing algorithm. For most of the well-known toroidal vertex-transitive graphs, the result drawings give an embedding of the graphs onto the torus.

We investigate properties of spatial graphs on the standard torus. It is known that nontrivial embeddings of planar graphs in the torus contain a nontrivial knot or a nonsplit link due to [2, 3]. Building on this and using the chirality of torus knots and links [9, 10], we prove that the nontrivial embeddings of simple 3-connected planar graphs in the standard torus are chiral. For the case that the spatial graph contains a nontrivial knot, the statement was shown by Castle et al. [5]. We give an alternative proof using minors instead of the Euler characteristic. To prove the case in which the graph embedding contains a nonsplit link, we show the chirality of Hopf ladders with at least three rungs, thus generalizing a theorem of Simon [12].

The genus graphs have been studied by many authors, but just a few results concerning in special cases: Planar, Toroidal, Complete, Bipartite and Cartesian Product of Bipartite. We present here a general lower bound for the genus of a abelian Cayley graph and construct a family of circulant graphs which reach this bound.

We proposed a scheme for the generation of multi–atom W states with two-photon Jaynes-Cummings Model in ultrahigh-Q toroidal microcavities. We consider that the two modes, clockwise (CW) and counterclockwise (CCW) modes inside the microtoroidal resonator, can be produced by embedding Bragg grating in the microtoroidal.

Fuchsian groups with a modular embedding have the richest arithmetic properties among non-arithmetic Fuchsian groups. But they are very rare, all known examples being related either to triangle groups or to Teichmüller curves. In Part I of this paper we study the arithmetic properties of the modular embedding and develop from scratch a theory of twisted modular forms for Fuchsian groups with a modular embedding, proving dimension formulas, coefficient growth estimates and differential equations. In Part II we provide a modular proof for an Apéry-like integrality statement for solutions of Picard–Fuchs equations. We illustrate the theory on a worked example, giving explicit Fourier expansions of twisted modular forms and the equation of a Teichmüller curve in a Hilbert modular surface. In Part III we show that genus two Teichmüller curves are cut out in Hilbert modular surfaces by a product of theta derivatives. We rederive most of the known properties of those Teichmüller curves from this viewpoint, without using the theory of flat surfaces. As a consequence we give the modular embeddings for all genus two Teichmüller curves and prove that the Fourier developments of their twisted modular forms are algebraic up to one transcendental scaling constant. Moreover, we prove that Bainbridge’s compactification of Hilbert modular surfaces is toroidal. The strategy to compactify can be expressed using continued fractions and resembles Hirzebruch’s in form, but every detail is different.

A flat torus E^2/Λ is the quotient of the Euclidean plane E^2 with a full rank lattice Λ generated by two linearly independent vectors v_1 and v_2. A motif-transitive tiling T of the plane whose symmetry group G contains translations with vectors v_1 and v_2 induces a tiling T^* of the flat torus. Using a sequence of injective maps, we realize T^* as a tiling T-of a round torus (the surface of a doughnut) in the Euclidean space E^3. This realization is obtained by embedding T^* into the Clifford torus S^1 × S^1 ⊆ E^4 and then stereographically projecting its image to E^3. We then associate two groups of isometries with the tiling T^* – the symmetry group G^* of T^* itself and the symmetry group G-of its Euclidean realization T-. This work provides a method to compute for G^* and G-using results from the theory of space forms, abstract polytopes, and transformation geometry. Furthermore, we present results on the color symmetry properties of the toroidal tiling T^* in relation with the color symmetry properties of the planar tiling T. As an application, we construct toroidal polyhedra from T-and use these geometric structures to model carbon nanotori and their structural analogs.

Structured population in evolutionary algorithms (EAs) is an important research track where an individual only interacts with its neighboring individuals in the breeding step. The main rationale behind this is to provide a high level of diversity to overcome the genetic drift. Cellular automata concepts have been embedded to the process of EA in order to provide a decentralized method in order to preserve the population structure. Harmony search (HS) is a recent EA that considers the whole individuals in the breeding step. In this paper, the cellular automata concepts are embedded into the HS algorithm to come up with a new version called cellular harmony search (cHS). In cHS, the population is arranged as a two-dimensional toroidal grid, where each individual in the grid is a cell and only interacts with its neighbors. The memory consideration and population update are modified according to cellular EA theory. The experimental results using benchmark functions show that embedding the cellular automata concepts with HS processes directly affects the performance. Finally, a parameter sensitivity analysis of the cHS variation is analyzed and a comparative evaluation shows the success of cHS.

The objective of the proposed research is to design, fabricate, characterize and test silicon-embedded magnetic components for on-chip integrated power applications. Driven by the trend towards continued system multi-functionality and miniaturization, MEMS technology can be used to enable fabrication of three-dimensional (3-D) functional devices into the silicon bulk, taking advantage of the 'dead volume' in the substrate and achieving a greater level of miniaturization and integration. As an example, one of the challenges in realizing ultra-compact high-frequency power converters lies in the integration of magnetic components due to their relatively large volume. Embedding 3-D magnetic components within the wafer volume and implementing high-power, through-wafer interconnect for connection to circuitry on the wafer surface is a promising solution for achieving ultra-compact power converters, in which digital control circuitry and power switches are located on the wafer surface, and suitable magnetic components are embedded within the silicon substrate. In order to do this, key tasks in the following areas have been accomplished: development of new fabrication technologies for silicon embedding and 3-D structure realization; creation of high-current, through-wafer interconnects for connection of the device to circuitry; ability to incorporate a variety of magnetic materials when performance enhancement of the device is needed; exploration of a new design space for the devices due to ultra-compactness and silicon interaction; understanding of the complicated loss mechanisms in the embedded devices; and demonstration of device performance and in-circuit operation.

Algebraic geometry is the study of solutions in polynomial equations using objects and shapes. Differential geometry is based on surfaces, curves, and dimensions of shapes and applying calculus and algebra. Desingularizing the singularities of a variety plays an important role in research in algebraic and differential geometry. Toroidal Embedding is one of the tools used in desingularization. Therefore, Toroidal Embedding and desingularization will be the main focus of my project. In this paper, we first provide a brief introduction on Toroidal Embedding, then show an explicit construction on how to smooth a variety with singularity through Toroidal Embeddings.

In dieser Dissertation entwickeln wir eine Schnittheorie von torischen bzw. toroidalen b-Divisoren auf torischen bzw. toroidalen Einbettungen. Motiviert wird dies durch das Ziel, eine arithmetische Schnittheorie auf gemischten Shimura- Varietäten von nicht-kompaktem Typ zu begründen. Die bisher zur Verfügung stehenden Werkzeuge definieren keine numerischen Invarianten, die birational invariant sind. Zuerst definieren wir torische b-Divisoren auf torischen Varietäten und einen Integrabilitätsbegriff für solche Divisoren. Wir zeigen, dass torische b-Divisoren unter geeigneten Annahmen an die Positivität integrierbar sind und dass ihr Grad als das Volumen einer konvexen Menge gegeben ist. Außerdem zeigen wir, dass die Dimension des Vektorraums der globalen Schnitte eines torischen b-Divisors, der nef ist, gleich der Anzahl der Gitterpunkte in besagter konvexer Menge ist und wir geben eine Hilbert–Samuel-Formel für das asymptotische Wachstum dieser Dimension. Dies verallgemeinert klassische Resultate für klassische torische Divisoren auf torischen Varietäten. Als ein zusätzliches Resultat setzen wir konvexe Mengen, die von torischen b-Divisoren kommen, mit Newton–Okounkov- Körpern in Beziehung. Anschließend definieren wir toroidale b-Divisoren auf toroidalen Varietäten und einen Integrierbarkeitsbegriff für solche Divisoren. Wir zeigen, dass unter geeigneten Positivitätsannahmen toroidale b-Divisoren integrierbar sind und ihr Grad als ein Integral bezüglich eines Grenzmaßes aufgefasst werden kann. Dieses Grenzmaß ist ein schwacher Grenzwert von diskreten Maßen, deren Gewichte über tropische Schnittheorie auf rationalen konischen polyedrischen Komplexen definiert sind, welche zu der toroidalen Varietät gehören. Wir setzen dieses Grenzmaß ebenfalls in Beziehung zum zu einem konvexen Körper assoziierten Flächeninhaltsmaß. Diese Beziehung erlaubt es uns, Integrale bezüglich des Grenzmaßes explizit auszurechnen. Zusätzlich erhalten wir eine kanonische Zerlegung der Differenz zweier konvexer Mengen und eine Beziehung zwischen das Volumen von den Teilen und tropische Schnittheoretische Mengen. Schließlich berechnen wir als Anwendung den Grad des b-Divisors von Jacobiformen vom Gewicht k und Index m bezüglich der Hauptkongruenzuntergruppe zum Level N >= 3 auf der verallgemeinerten universellen elliptischen Kurve und wir zeigen, dass der b-divisoriale Ansatz gegenüber lediglich einer kanonischen Kompaktifizierung Vorteile bietet.
In this thesis we develop an intersection theory of toric and toroidal b-divisors on toric and toroidal embeddings, respectively. Our motivation comes from wanting to establish an arithmetic intersection theory on mixed Shimura varieties of non- compact type. The tools available until now do not define numerical invariants which are birationally invariant. First, we define toric b-divisors on toric varieties and an integrability notion of such divisors. We show that under suitable positivity assumptions toric b- divisors are integrable and that their degree is given as the volume of a convex set. Moreover, we show that the dimension of the space of global sections of a nef toric b-divisor is equal to the number of lattice points in this convex set and we give a Hilbert-Samuel type formula for its asymptotic growth. This generalizes classical results for classical toric divisors on toric varieties. As a by-product, we relate convex sets arising from toric b-divisors with Newton-Okounkov bodies. Then, we define toroidal b-divisors on toroidal varieties and an integrability notion of such divisors. We show that under suitable positivity assumptions toroidal b-divisors are integrable and that their degree is given as an integral with respect to a limit measure, which is a weak limit of discrete measures whose weights are defined via tropical intersection theory on the rational con- ical polyhedral complex attached to the toroidal variety. We also relate this limit measure with the surface area measure associated to a convex body. This relation enables us to compute integrals with respect to these limit measures ex- plicitly. Additionally, we give a canonical decomposition of the difference of two convex sets and we relate the volume of the pieces to tropical top intersection numbers. Finally, as an application, we compute the degree of the b-divisor of Jacobi forms of weight k and index m with respect to the principal congruence subgroup of level N >= 3 on the generalized universal elliptic curve and we show that it is meaningful to consider the b-divisorial approach instead of just fixing one canonical compactification.

In the chemical world, as well as the physical, strands get tangled. When those strands form loops, the mathematical discipline of ‘knot theory’ can be used to analyse and describe the resultant tangles. However less has been studied about the situation when the strands branch and form entangled loops in either finite structures or infinite periodic structures. The branches and loops within the structure form a ‘graph’, and can be described by mathematical ‘graph theory’, but when graph theory concerns itself with the way that a graph can fit in space, it typically focuses on the simplest ways of doing so. Graph theory thus provides few tools for understanding graphs that are entangled beyond their simplest spatial configurations. This thesis explores this gap between knot theory and graph theory. It is focussed on the introduction of small amounts of entanglement into finite graphs embedded in space. These graphs are located on surfaces in space, and the surface is chosen to allow a limited amount of complexity. As well as limiting the types of entanglement possible, the surface simplifies the analysis of the problem – reducing a three-dimensional problem to a two-dimensional one. Through much of this thesis, the embedding surface is a torus (the surface of a doughnut) and the graph embedded on the surface is the graph of a polyhedron. Polyhedral graphs can be embedded on a sphere, but the addition of the central hole of the torus allows a certain amount of freedom for the entanglement of the edges of the graph. Entanglements of the five Platonic polyhedra (tetrahedron, octahedron, cube, dodecahedron, icosahedron) are studied in depth through their embeddings on the torus. The structures that are produced in this way are analysed in terms of their component knots and links, as well as their symmetry and energy. It is then shown that all toroidally embedded tangled polyhedral graphs are necessarily chiral, which is an important property in biochemical and other systems. These finite tangled structures can also be used to make tangled infinite periodic nets; planar repeating subgraphs within the net can be systematically replaced with a tangled version, introducing a controlled level of entanglement into the net. Finally, the analysis of entangled structures simply in terms of knots and links is shown to be deficient, as a novel form of tangling can exist which involves neither knots nor links. This new form of entanglement is known as a ravel. Different types of ravels can be localised to the immediate vicinity of a vertex, or can be spread over an arbitrarily large scope within a finite graph or periodic net. These different forms of entanglement are relevant to chemical and biochemical self-assembly, including DNA nanotechnology and metal-ligand complex crystallisation.

碩士
國立臺灣大學
數學研究所
102
In this thesis, we will assume basic facts about toric varieties and commutative algebra, and give a survey of [3], chapter II, with detailed proofs of all the theorems. First of all, the idea of equivariant torus embeddings will be generalized to that of so-called toroidal embeddings, which means intuitively "locally similar to some torus embeddings". More precisely, a toroidal embedding is a smooth variety $X$ containing a smooth open subset $U$, such that for every closed point $x in X$, there exists an $T$-equivariant embedding $X_{sigma}$ of some torus $T$, a closed point $t in X_{sigma}$, and an $k$-local algebra isomorphism:[ widehat{mathcal{O}}_{X,x} simeq widehat{mathcal{O}}_{X_{sigma},t}] and the ideal in $widehat{mathcal{O}}_{X,x} $ generated by the ideal of $Xsetminus U$ corresponds to the ideal in $widehat{mathcal{O}}_{X_{sigma},t}$ generated by the ideal of $X_{sigma}setminus T$. Next, we can stratify a toroidal embedding into different components which generalize the idea of orbits. And then we can analyze a toroidal embedding as toric cases and obtain many similar results. The main goal of this generalization is to apply those developed theorems to reduce the proof of semi-stable reduction theorem to a specific combinatorial construction. Section 1 gives the definition of toroidal embeddings and the stratification of a toroidal embedding, and then consider the two crucial parts: $M^Y$ and $S^U({ m star}! Y)$ for a stratum $Y$ (Lemma 1.1.7 and Definition 1.1.11), which generalize the idea of $T$-invariant Cartier divisors and 1-parameter subgroup of a $T$-equivariant embedding, and we can also define a cone $sigma^Y$ in some euclidean space relative to the stratum $Y$. At the end of this section, we show that a toroidal embedding can be associated to a "polyhedral complex", which is a collection of cones patched together similar to a fan. Section 2 introduces "canonical morphism" to a fixed toroidal embedding, and shows that this is equivalent to give a sub-polyhedral complex (Theorem 1.2.2). With this theorem, we then generalize theorems of toric varieties by using polyhedral complices instead of fans, including the existence of morphisms, non-singularity of such varieties and blowing-ups (Theorem 1.2.8, Theorem 1.2.9 and Theorem 1.2.16), and eventually show that there exists a non-singular blowing-up. Section 3 provides concrete methods that we can convert the semi-stable reduction theorem to the construction of some toroidal embeddings, and then use the theorem in cite{Tor}, chapter III to show the semi-stable reduction theorem.

Mixed Bing–Whitehead decompositions are a special class of toroidal decompositions of the 3-sphere, defined as the intersection of infinite nested sequences of solid tori. The Bing decomposition and the Whitehead decomposition from previous chapters are both examples of mixed Bing–Whitehead decompositions. In this chapter a precise criterion for when toroidal decompositions shrink is given, in terms of a ‘disc replicating function’. In the case of mixed Bing–Whitehead decomposition, this measures the relative numbers of Bing and Whitehead doubling in the sequence of solid tori in the definition. Mixed Bing–Whitehead decompositions are related to the boundaries of skyscrapers, and the shrinking theorem proved in this chapter will be key to the eventual proof of the disc embedding theorem.

This chapter explains the algebraic construction of toroidal compactifications. For this purpose the chapter utilizes the theory of toroidal embeddings for torsors under groups of multiplicative type. Based on this theory, the chapter begins the general construction of local charts on which degeneration data for PEL structures are tautologically associated. The next important step is the description of good formal models, and good algebraic models approximating them. The correct formulation of necessary properties and the actual construction of these good algebraic models are the key to the gluing process in the étale topology. In particular, this includes the comparison of local structures using certain Kodaira–Spencer morphisms. As a result of gluing, this chapter obtains the arithmetic toroidal compactifications in the category of algebraic stacks. The chapter is concluded by a study of Hecke actions on towers of arithmetic toroidal compactifications.