Simulation of dynamic pinion course using Runge-Kutta's method and impact modeling

Once defined the relationship between the Starter Motor components and their functions, it is possible to develop a mathematical model capable to predict the Starter behavior during operation. One important aspect is the engagement system behavior. The development of a mathematical tool capable of predicting it is a valuable step in order to reduce the design time, cost and engineering efforts. A mathematical model, represented by differential equations, can be developed using physics laws, evaluating force balance and energy flow through the systems degrees of freedom. Another important physical aspect to be considered in this modeling is the impact conditions (particularly on the pinion and ring-gear contact). This work is a report of those equations application on available mathematical software and the resolution of those equations by Runge-Kutta's numerical integration method, in order to build an accessible engineering tool. Copyright © 2011 SAE International.

O ensino de trigonometria: perspectivas do ensino fundamental ao médio

Pós-graduação em Matemática em Rede Nacional - IBILCE

Poliedros e Teorema de Euler

Pós-graduação em Matemática em Rede Nacional - IBILCE

Métodos numéricos para encontrar zeros de funções: aplicações para o Ensino Médio

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

El crescimiento poblacional: una propuesta pedagógica para abordar biologia, matemáticas y TICs

In this paper we propose the achievement of an interdisciplinary activity evolving biology and mathematics knowledge with students of the third grade of high school about the population growth theme. The goal of this activity is to offer to the students a wider perception about the ways of population growth of different organisms from their home region, helping them to represent it through mathematics models. The formulation of the research problem is done from the theoretical and empirical data and the student is encouraged to behave in a participative and dialogic way in all stages of the activity. The mathematical modeling and the graphic representation of the population growth are made through the mathematical software Geogebra and we emphasize the qualitative analysis of the data from the biological and environmental education point of view.

Permanent deformation estimates of dynamic equipment foundations: Application to a gas turbine in granular soils

Permanent displacements of a gas turbine founded on a fine, poorly graded, and medium density sand are studied. The amplitudes and modes of vibration are computed using Barkan´s formulation, and the “High-Cycle Accumulation” (HCA) model is employed to account for accumulated deformations due to the high number of cycles. The methodology is simple: it can be easily incorporated into standard mathematical software, and HCA model parameters can be estimated based on granulometry and index properties. Special attention is devoted to ‘transient’ situations at equipment´s start-up, during which a range of frequencies – including frequencies that could be similar to the natural frequencies of the ground – is traversed. Results show that such transient situations could be more restrictive than stationary situations corresponding to normal operation. Therefore, checking the stationary situation only might not be enough, and studying the influence of transient situations on computed permanent displacements is needed to produce a proper foundation design

Análisis de reflectores en MatLab

Sabor, Software de Análisis de BOcinas y Reflectores, es una herramienta didáctica la cual es utilizada en los laboratorios de la escuela para realizar prácticas de la asignatura Antenas y Compatibilidad Electromagnética, esta herramienta da a los alumnos una visión gráfica de lo que se enseña en clase de teoría de lo que son los campos en las aperturas de los reflectores. El proyector pretende sustituir al primer Sabor , ya que se queda obsoleto debido al sistema operativo, ya que funciona solo para Windows XP y con ordenadores de 32 bits, y también realizar mejoras y corregir errores de la versión anterior. El proyecto se ha desarrollado en Matlab que es un software matemático con grandes ventajas en cuanto a cálculo, desarrollo gráfico, y a la creación de nuevos algoritmos en su propio lenguaje y además está disponible para las plataformas Unix, Windows, Mac OSX y GNU/Linux. El objetivo del proyecto ha sido implementar, al igual que las versiones anteriores, cinco tipos de reflectores, como son: Parabólico, Offset, Cassegrain y los dos Dobles Offset, Cassegrain y Gregorian, y han sido analizados con un alimentador ideal ,cos-q, y por último los resultados obtenidos se han comparado con las versiones anteriores de Sabor, como son Sabor 3.0 y el primer Sabor. El proyecto consta de partes muy bien diferencias como son :  La interpretación correctas de las formulas que se han utilizado para la realización de este proyecto ,dichas formulas han sido las dadas por el proyecto fin de carrera titulado Sabor3.0 de Francisco Egea Castejón.  GUIDE, the graphical user interface development environment, con el que se creó: GUI, graphical user interface, que es la parte de Matlab dedicada a crear interfaces de usuario , herramienta utilizada para crear nuestras distintas ventanas dedicadas para la obtención de datos para analizar los distintos reflectores y para mostrar por pantalla los distintos resultados.  Programación Orientada a Objetos de Matlab y sus distintas propiedades como son la herencia lo cual es muy útil para ocupar menos memoria ya que con un único método podemos realizar distintos cálculos con los distintos reflectores, objetos, solo cambiando las propiedades de cada objeto  Y por último ha sido la realización de validación de los resultados con la ayuda de las versiones anteriores de Sabor, que están detallados en el capítulo 5 y la unión con bocinas del proyecto fin de carrera Análisis de Bocinas en Matlab de Javier Montero. Por otra parte tenemos las mejoras realizadas a las antiguas versiones como son: realización de registros que el usuario puede guardar y cargar con las distintas variables, también se ha realizado un fichero .txt en el que consta la amplitud del campo con su respectiva theta para que el usuario pueda visualizarlo en cualquier plataforma gráfica de datos como por ejemplo exel. ABSTRACT. Sabor, Software de Análisis de BOcinas y Reflectores, is a teaching tool, which is used to do laboratory practice in the subject of Antennas y Compatibilidad Electromagnética, this tool gives students a graphic view of the knowledge that are given in theory class in regard to aperture field of reflectors. This project intend to replace the first Sabor, because it is outdated, due to the operating system, because Sabor works only with Widows XP and computer with 32 bits, and to make improves and correct errors that were detected in the last version of Sabor too. This project has been carried out in Matlab, which is a mathematical software with high-level language for numerical computation, visualization and application development, and furthermore it is available to different platforms such as Unix, Windows ,Mac OSX and GNU/Linux This project has focused on implementing, the same as last versions, five kind of reflectors, such as : Parabolic, Offset, Cassegrain and two offset dual reflector Cassegrain y Gregorian ,and these were analysed with a cos-q ideal feed, and finally the results were checked with the versions of Sabor, as well as Sabor 3.0 and the first Sabor. This project consist of four parts:  The correct interpretation of the formulas , which were used to do this project, from the final project Sabor3.0 by Francisco Egea Castejón.  GUIDE, the graphical user interface development environment, tool that was used to create : GUI, graphical user interface, part of Matlab dedicated to create user interface.  Object Oriented Programming of Matlab and different properties like inheritance, that is very useful for saving memory space because with only one method we can analyse different kind of reflectors, object, only change the properties of the object.  At finally, the results were contrasted with the results from the previous versions and the link reflectors with horns from the final project Análisis de Bocinas en Matlab by Javier Montero. On the other hand, we have the improvements such as: registers and .txt file. The registers are used by user to save and load different variables and .txt file is useful because it allows to the user plotting in different platforms for example exel.

Análisis de la modulación de voz ocasionada por el temblor vocal

La realización de este proyecto está basado en el estudio realizado por Jean Schoentgen en el cual el autor caracterizó el micro temblor vocal por medio del índice y la frecuencia de modulación. En este proyecto se utilizará la herramienta Matlab para el cálculo de estos parámetros y al finalizar se analizarán los datos obtenidos. El proyecto se ha dividido en tres grandes partes. En la primera de ellas se ha explicado brevemente los conceptos básicos de la voz y conceptos importantes tales como el temblor fisiológico, el patológico y el Jitter vocal entre otros, también se han detallado conceptos matemáticos utilizados en el desarrollo del código. Esto se realizó con el fin que el lector tenga claros algunos conceptos importantes antes del desarrollo del código y así pueda entender con más facilidad el estudio realizado en este proyecto, en esta parte no se ha realizado una explicación muy extensa de cada concepto, entendiendo que el lector posee unos conocimientos básicos de ingeniería, por otra parte existen innumerables libros que explican de una manera más precisa cada uno de estos conceptos. En la segunda parte se llevó a cabo el desarrollo del código. Como se mencionó anteriormente se ha utilizado la herramienta Matlab que es muy utilizada en la mayoría de las asignaturas de la carrera obteniendo así un buen dominio de esta, además posee unos toolbox muy útiles que facilitan los cálculos matemáticos. En esta parte se ilustra paso a paso cada etapa de elaboración del código y algunas graficas de la señal de voz a medida que pasa por cada etapa del código. En la última parte se obtienen los datos de todos los cálculos de los registros de voz y se analiza cada uno de ellos a la vez que se comparan con los del estudio de Jean Schoentgen y se analizan las posibles diferencias. ABSTRACT. The Project is based on the search made by Jean Schoentgen, whose research the micro tremor vocal can be established by frequency modulation and modulation index. This project has been carried out in Matlab to calculate the aforementioned parameters and finally, the results were contrasted with the results from Jean Shoetngen’s research. This project consists of three parts: The first of all, to be able to understand this project to future readers .It was explained different basic concepts about the voice such as physiologic tremor, pathological tremor and Jitter. Furthermore, mathematical concepts were explained in detail, due to these were used in the software development. Then, it was focused on software development such as the elaboration of code and different voice signals that were processed. This part was made with Matlab, which is mathematical software with high-level language for numerical computation, visualization, collaborate across disciplines including signal and image processing and application development. At finally, the acquired calculations were contrasted with the results from Jean Schoentgen’s research.

Towards a Modeling Environment for Earth Systems Simulations

The developments of models in Earth Sciences, e.g. for earthquake prediction and for the simulation of mantel convection, are fare from being finalized. Therefore there is a need for a modelling environment that allows scientist to implement and test new models in an easy but flexible way. After been verified, the models should be easy to apply within its scope, typically by setting input parameters through a GUI or web services. It should be possible to link certain parameters to external data sources, such as databases and other simulation codes. Moreover, as typically large-scale meshes have to be used to achieve appropriate resolutions, the computational efficiency of the underlying numerical methods is important. Conceptional this leads to a software system with three major layers: the application layer, the mathematical layer, and the numerical algorithm layer. The latter is implemented as a C/C++ library to solve a basic, computational intensive linear problem, such as a linear partial differential equation. The mathematical layer allows the model developer to define his model and to implement high level solution algorithms (e.g. Newton-Raphson scheme, Crank-Nicholson scheme) or choose these algorithms form an algorithm library. The kernels of the model are generic, typically linear, solvers provided through the numerical algorithm layer. Finally, to provide an easy-to-use application environment, a web interface is (semi-automatically) built to edit the XML input file for the modelling code. In the talk, we will discuss the advantages and disadvantages of this concept in more details. We will also present the modelling environment escript which is a prototype implementation toward such a software system in Python (see www.python.org). Key components of escript are the Data class and the PDE class. Objects of the Data class allow generating, holding, accessing, and manipulating data, in such a way that the actual, in the particular context best, representation is transparent to the user. They are also the key to establish connections with external data sources. PDE class objects are describing (linear) partial differential equation objects to be solved by a numerical library. The current implementation of escript has been linked to the finite element code Finley to solve general linear partial differential equations. We will give a few simple examples which will illustrate the usage escript. Moreover, we show the usage of escript together with Finley for the modelling of interacting fault systems and for the simulation of mantel convection.

Function interval arithmetic

We propose an arithmetic of function intervals as a basis for convenient rigorous numerical computation. Function intervals can be used as mathematical objects in their own right or as enclosures of functions over the reals. We present two areas of application of function interval arithmetic and associated software that implements the arithmetic: (1) Validated ordinary differential equation solving using the AERN library and within the Acumen hybrid system modeling tool. (2) Numerical theorem proving using the PolyPaver prover. © 2014 Springer-Verlag.

Computer-Assisted Proofs and Symbolic Computations

We discuss some main points of computer-assisted proofs based on reliable numerical computations. Such so-called self-validating numerical methods in combination with exact symbolic manipulations result in very powerful mathematical software tools. These tools allow proving mathematical statements (existence of a fixed point, of a solution of an ODE, of a zero of a continuous function, of a global minimum within a given range, etc.) using a digital computer. To validate the assertions of the underlying theorems fast finite precision arithmetic is used. The results are absolutely rigorous. To demonstrate the power of reliable symbolic-numeric computations we investigate in some details the verification of very long periodic orbits of chaotic dynamical systems. The verification is done directly in Maple, e.g. using the Maple Power Tool intpakX or, more efficiently, using the C++ class library C-XSC.

Principles and Practice of Fire Modelling: A Collection of Lecture Notes for a Short Course

Once the preserve of university academics and research laboratories with high-powered and expensive computers, the power of sophisticated mathematical fire models has now arrived on the desk top of the fire safety engineer. It is a revolution made possible by parallel advances in PC technology and fire modelling software. But while the tools have proliferated, there has not been a corresponding transfer of knowledge and understanding of the discipline from expert to general user. It is a serious shortfall of which the lack of suitable engineering courses dealing with the subject is symptomatic, if not the cause. The computational vehicles to run the models and an understanding of fire dynamics are not enough to exploit these sophisticated tools. Too often, they become 'black boxes' producing magic answers in exciting three-dimensional colour graphics and client-satisfying 'virtual reality' imagery. As well as a fundamental understanding of the physics and chemistry of fire, the fire safety engineer must have at least a rudimentary understanding of the theoretical basis supporting fire models to appreciate their limitations and capabilities. The five day short course, "Principles and Practice of Fire Modelling" run by the University of Greenwich attempt to bridge the divide between the expert and the general user, providing them with the expertise they need to understand the results of mathematical fire modelling. The course and associated text book, "Mathematical Modelling of Fire Phenomena" are aimed at students and professionals with a wide and varied background, they offer a friendly guide through the unfamiliar terrain of mathematical modelling. These concepts and techniques are introduced and demonstrated in seminars. Those attending also gain experience in using the methods during "hands-on" tutorial and workshop sessions. On completion of this short course, those participating should: - be familiar with the concept of zone and field modelling; - be familiar with zone and field model assumptions; - have an understanding of the capabilities and limitations of modelling software packages for zone and field modelling; - be able to select and use the most appropriate mathematical software and demonstrate their use in compartment fire applications; and - be able to interpret model predictions. The result is that the fire safety engineer is empowered to realise the full value of mathematical models to help in the prediction of fire development, and to determine the consequences of fire under a variety of conditions. This in turn enables him or her to design and implement safety measures which can potentially control, or at the very least reduce the impact of fire.

Uma experiência de ensino integrado dos fundamentos matemáticos da ciência da computação

Este trabalho tem por objetivo relatar os resultados preliminares de uma experiência de integração curricular, em andamento na Escola de Informática da UCPel, na área de fundamentos matemáticos da Ciência da Computação. A concepção curricular da experiência está baseada nas idéias de Basil Bernstein sobre currículos de coleção e/ou integração, na idéia de desenvolvimento autônomo do aluno e na organização do ensino em forma semi-presencial (com apoio da Internet) e cooperativa (com apoio de softwares matemáticos).