The multilevel structures of NURBs and NURBlets on intervals

Zhu, Weiwei,

January 2009

Title from title page of PDF (University of Missouri--St. Louis, viewed April 5, 2010). Includes bibliographical references (p. 84-89).

[Part] I. Beta-spectroscopic studies in the promethium region.

Marshall, Thomas V.

January 1960

Thesis--University of California, Berkeley, 1960. / "Chemistry General" -t.p. Includes bibliographical references (p. 70-73).

[en] SEATTERING OF PLANE WAVES BY PERFECT-CONDUCTING TRIDIMENSIONAL BODIES WITH ARBITRARY SHAPES / [pt] ESPALHAMENTO DE ONDAS PLANAS POR OBJETOS CONDUTORES TRIDIMENSIONAIS DE FORMAS ARBITRÁRIAS

ALEXANDRE REGIS NOBREGA

14 August 2006

[pt] O presente trabalho estuda a interação entre objetos condutores perfeitos tridimensionais, de formas arbitrárias e campos eletromagnéticos harmônicos no tempo incidentes sobre os mesmos. Pretende-se determinar os campos espalhados pelos objetos, caracterizados por uma malha de elementos de contorno planos e triangulares. Através de um tratamento numérico aproximado da Equação Integral do Campo Magnético, a densidade de corrente induzida na superfície do condutor perfeito é obtida. De posse deste resultado, determina-se o campo magnético espalhado (campo distante) e calcula-se a seção reta radar em várias direções. As vantagens e desvantagens da utilização do Método dos Momentos serão apontadas. Os resultados obtidos pelos mesmos serão comparados entre si e com aqueles disponíveis na literatura. / [en] This work studies the interaction between tridimensional perfect conducting objects of arbitrary shapes and incident time-harmonic electromagnetic fields. The fields, scattered by these objects, are determined using a finite number of plane and triangular boundary elements. The induced current density on the boundary is obtained using the Magnetic Field Integral Equation, applied approximately in a numerical approach. With the result mentioned above, the scattered magnetic field (far-field) is determined and the Radar Cross Section is calculated. The advantages and disadvantages of the use of a numerical method (moment method) are pointed out and the results compared. With those in literature.

[pt] CONDUTORES PERFEITOS

[en] PERFECT CONDUCTING

[pt] FORMAS ARBITRARIAS

[en] ARBITRARY SHAPES

Harmoni - more than just a lamp

Valdivia, Sharon

January 2017

In this thesis, I wanted to design a lamp in collaboration with the lighting company Örsjö Belysning AB, that would contribute to stress-reduction and calmness both through visual and functional aspects. My focus in the study and the design process was on the lamps shape and light, where my primary inspiration was taken from the qualities of water. My lamp also had to fit into Örsjö Belysnings current assortment. My research showed that rounded shapes and adjustable light are two important factors for producing calmness and well-being for the user. The result of my work was a lamp with the name Harmoni. A LED floor lamp made of brass metal and acrylic plastic, with focus on rounded shapes, lightness, flexibility and symmetry. The lamp has a unique and adjustable light emission, that gives two different kinds of light from the same source. It functions both as a floor and a wall lamp in one.

lighting

design

calmness

stress-reducing

rounded shapes

Design

Design

Protein Structure Prediction Based on Neural Networks

Zhao, Jing

January 2013

Proteins are the basic building blocks of biological organisms, and are responsible for a variety of functions within them. Proteins are composed of unique amino acid sequences. Some has only one sequence, while others contain several sequences that are combined together. These combined amino acid sequences fold to form a unique three-dimensional (3D) shape. Although the sequences may fold proteins into different 3D shapes in diverse environments, proteins with similar amino acid sequences typically have similar 3D shapes and functions. Knowledge of the 3D shape of a protein is important in both protein function analysis and drug design, for example when assessing the toxicity reduction associated with a given drug. Due to the complexity of protein 3D shapes and the close relationship between shapes and functions, the prediction of protein 3D shapes has become an important topic in bioinformatics. This research introduces a new approach to predict proteins’ 3D shapes, utilizing a multilayer artificial neural network. Our novel solution allows one to learn and predict the representations of the 3D shape associated with a protein by starting directly from its amino acid sequence descriptors. The input of the artificial neural network is a set of amino acid sequence descriptors we created based on a set of probability density functions. In our algorithm, the probability density functions are calculated by the correlation between the constituent amino acids, according to the substitution matrix. The output layer of the network is formed by 3D shape descriptors provided by an information retrieval system, called CAPRI. This system contains the pose invariant 3D shape descriptors, and retrieves proteins having the closest structures. The network is trained by proteins with known amino acid sequences and 3D shapes. Once the network has been trained, it is able to predict the 3D shape descriptors of the query protein. Based on the predicted 3D shape descriptors, the CAPRI system allows the retrieval of known proteins with 3D shapes closest to the query protein. These retrieved proteins may be verified as to whether they are in the same family as the query protein, since proteins in the same family generally have similar 3D shapes. The search for similar 3D shapes is done against a database of more than 45,000 known proteins. We present the results when evaluating our approach against a number of protein families of various sizes. Further, we consider a number of different neural network architectures and optimization algorithms. When the neural network is trained with proteins that are from large families where the proteins in the same family have similar amino acid sequences, the accuracy for finding proteins from the same family is 100%. When we employ proteins whose family members have dissimilar amino acid sequences, or those from a small protein family, in which case, neural networks with one hidden layer produce more promising results than networks with two hidden layers, and the performance may be improved by increasing the number of hidden nodes when the networks have one hidden layer.

Protein 3D shapes

Amino acid sequence

Neural Networks

Systematic Traverse

Esposito, Sarah Raeann

17 June 2022

No description available.

Fine Arts

Art

Abstract

Landscape

Paintings

Shapes

Collage

Color

The Implementation of kinesthetic learning activities to identify geometric shapes with preschool students

Batt, Kathleen J.

January 2009

No description available.

Preschool Education

kinesthetic learning

preschool children

geometric shapes

geometry

Vibration Analysis of Anisotropic plates, Special Case: Violin

Lomte, Chaitanya J.

January 2013

No description available.

Mechanical Engineering

Vibration analysis

3D modelling

frequency

mode shapes

Normalization of Complex Mode Shapes by Truncation of the Alpha-Polynomial

Niranjan, Adityanarayan C.

January 2015

No description available.

Mechanics

Normalization

Truncation of the alpha-polynomial

Complex mode shapes

Damping distribution

Low temperature helium pressure broadening of HCN

Ronningen, Theodore J.

14 July 2005

No description available.

pressure broadening

molecular spectroscopy

millimeter-wave spectroscopy

spectroscopic line shapes