Holografická anténa / Holographic antenna

Klečka, Tomáš

January 2011

This master’s thesis deals with principle of microwave holography, methods of microwave hologram recording and analyzes some types of holographic antennas from structural and functional point of view. It also includes simulations of selected holographic antennas and their modi?cations, applies optimization on three types of antennas. Finally it reviews measured results of three costructed antennas.

Optogenetic Stimulation of Human Neural Networks Using Fast Ferroelectric Spatial Light Modulator—Based Holographic Illumination

Schmieder, Felix, Klapper, Simon D., Koukourakis, Nektarios, Busskamp, Volker, Czarske, Jürgen W.

28 December 2018

The generation and application of human stem-cell-derived functional neural circuits promises novel insights into neurodegenerative diseases. These networks are often studied using stem-cell derived random neural networks in vitro, with electrical stimulation and recording using multielectrode arrays. However, the impulse response function of networks is best obtained with spatiotemporally well-defined stimuli, which electrical stimulation does not provide. Optogenetics allows for the functional control of genetically altered cells with light stimuli at high spatiotemporal resolution. Current optogenetic investigations of neural networks are often conducted using full field illumination, potentially masking important functional information. This can be avoided using holographically shaped illumination. In this article, we present a digital holographic illumination setup with a spatial resolution of about 8 µm, which suffices for the stimulation of single neurons, and offers a temporal resolution of less than 0.6 ms. With this setup, we present preliminary single-cell stimulation recording of stem-cell derived induced human neurons in a random neural network. This will offer the opportunity for further studies on connectivity in such networks.

info:eu-repo/classification/ddc/600

ddc:600

IT IS MORE THAN WHAT MEETS THE EYE : Exploring Immersion & Co-Experience in Holographic Art

Andersson, Johannes, Pettersson, Matilda

January 2021

With the growing interest in digital ways to experience art exhibitions, HCI and especially experience-centred design research have in recent years begun to show promising results when implementing holograms into the social dynamics found in art exhibitions. However, as to why holograms can enhance engagement and immersion, more research can be done. This thesis seeks to explore holograms' unique characteristics through an iterative experience-centred approach through the theoretical lens of Flow and its ability to prompt for co-experience. In two studies with eight participants, a design workshop and a mini-exhibition, we uncovered four unique characteristics and two takeaways regarding its potential to design for co-experience. The results indicated that holograms were perceived as immersive and presented properties related not only to the hologram but also the environment, as to why. It was concluded that even though holograms can benefit art exhibitions, the social aspects could be explored further.

Human Aspects of ICT

Mänsklig interaktion med IKT

Моделирование процесса обработки сигналов в космических РСА высокого разрешения : магистерская диссертация / Modeling of signal processing in high resolution synthetic aperture radar

Курганский, А. А., Kurganski, A. A.

January 2015

В работе актуализируется цель создания учебного программного приложения, позволяющего моделировать процесс формирования и обработки сигналов в космических РСА высокого разрешения. В ходе работы разработано программное приложение, которое позволяет создать облучаемую сцену земной поверхности и сформировать в зависимости от сцены отраженный сигнал с пользовательскими характеристиками РСА, провести его обработку с целью получения радиоголограмм и радиолокационных изображений. Результатом разработки стало учебное программное приложение, которое позволит магистрам направления «Радиотехника» понять принцип формирования и обработки сигналов в космических РСА высокого разрешения и провести ряд исследований, направленных на изучения особенностей формирования радиолокационных изображений. / Problem of development of educational software application that allows to simulate the process of forming and signal processing in space high-resolution SAR is disclosed. In result software application that allows to create an irradiated scene of earth's surface and to form depending on the scene reflected signal with custom features SAR in order to obtain RF holograms and radar images was developed. The achievement is the educational software application that allows magisters of speciality «Radiotechnics» to understand the principle of formation and signal processing in high-resolution SAR and to perform a series of test aimed at studying the characteristics of radar image .

MASTER'S THESIS

RADAR

SYNTHETIC APERTURE

REFLECTED SIGNAL

SATELLITE

RF HOLOGRAM

RADAR IMAGE

РАДИОЛОКАТОР

ОТРАЖЕННЫЙ СИГНАЛ

КОСМИЧЕСКИЙ АППАРАТ

РАДИОГОЛОГРАММА

The specter of sentimentality

Delaney, Jacci Marie

29 October 2014

No description available.

Fine Arts

Dynamics of Multi-functional Acoustic Holograms in Contactless Ultrasonic Energy Transfer Systems

Bakhtiari Nejad, Marjan

28 August 2020

Contactless ultrasonic power transfer (UPT), using piezoelectric transducers, is based on transferring energy using acoustic waves, in which the waves are generated by an acoustic source or transmitter and then transferred through an acoustic medium such as water or human tissue to a sensor or receiver. The receiver then converts the mechanical strain induced by the incident acoustic waves to electricity and delivers to an electrical load, in which the electrical power output of the system can be determined. The execution and efficiency of this technology can be significantly enhanced through patterning, focusing, and localization of the transmitted acoustic energy in space to simultaneously power pre-determined distributed sensors or devices. A passive 3D-printed acoustic hologram plate alongside a single transducer can generate arbitrary and pre-designed ultrasound fields in a particular distance from the hologram mounted on the transmitter, i.e., a target plane. This dissertation presents the use of these simple, cost-effective, and high-fidelity acoustic holograms in UPT systems to selectively enhance and pattern the electrical power output from the receivers. Different holograms are numerically designed to create single and multi-focal pressure patterns in a target plane where an array of receivers are placed. The incident sound wave from a transmitter, after passing through the hologram, is manipulated, hence, the output field is the desired pressure field, which excites the receivers located at the pre-determined focal points more significantly. Furthermore, multi-functional holograms are designed to generate multiple images at different target planes and driving frequencies, called, respectively, multi-image-plane and multi-frequency patterning holograms. The multiple desired pressure distributions are encoded on the single hologram plate and each is reconstructed by changing the axial distance and by switching the frequency. Several proof-of-concept experiments are performed to verify the functionality of the computationally designed holograms, which are fabricated using modern 3D-printers, i.e., the desired wavefronts are encoded in the hologram plates' thickness profile, being input to the 3D-printer. The experiments include measurement of output pressure fields in water using needle hydrophones and acquisition of receivers' voltage output in UPT systems. Another technique investigated in this dissertation is the implementation of acoustic impedance matching layers deposited on the front leading surface of the transmitter and receiver transducers. Current UPT systems suffer from significant acoustic losses through the transmission line from a piezoelectric transmitter to an acoustic medium and then to a piezoelectric receiver. This is due to the unfavorable acoustic impedance mismatch between the transducers and the medium, which causes a narrow transducer bandwidth and a considerable reflection of the acoustic pressure waves at the boundary layers. Using matching layers enhance the acoustic power transmission into the medium and then reinforce the input as an excitation into the receiver. Experiments are performed to identify the input acoustic pressure from a cylindrical transmitter to a receiver disk operating in the 33-mode of piezoelectricity. Significant enhancements are obtained in terms of the receiver's electrical power output when implementing a two-layer matching structure. A design platform is also developed that can facilitate the construction of high-fidelity acoustically matched transducers, that is, the material layers' selection and determination of their thicknesses. Furthermore, this dissertation presents a numerical analysis for the dynamical motions of a high-intensity focused ultrasound (HIFU)-excited microbubble or stable acoustic cavitation, which includes the effects of acoustic nonlinearity, diffraction, and absorption of the medium, and entails the problem of several biomedical ultrasound applications. Finally, the design and use of acoustic holograms in microfluidic channels are addressed which opens the door of acoustic patterning in particle and cell sorting for medical ultrasound systems. / Doctor of Philosophy / This dissertation presents several techniques to enhance the wireless transfer of ultrasonic energy in which the sound wave is generated by an acoustic source or transmitter, transferred through an acoustic medium such as water or human tissue to a sensor or receiver. The receiver transducer then converts the vibrational energy into electricity and delivers to an electrical load in which the electrical power output from the system can be determined. The first enhancement technique presented in this dissertation is using a pre-designed and simple structured plate called an acoustic hologram in conjunction with a transmitter transducer to arbitrarily pattern and shape ultrasound fields at a particular distance from the hologram mounted on the transmitter. The desired wavefront such as single or multi-focal pressure fields or an arbitrary image such as a VT image pattern can simply be encoded in the thickness profile of this hologram plate by removing some of the hologram material based on the desired shape. When the sound wave from the transmitter passes this structured plate, it is locally delayed in proportion to the hologram thickness due to the different speed of sound in the hologram material compared to water. In this dissertation, various hologram types are designed numerically to implement in the ultrasonic power transfer (UPT) systems for powering receivers located at the predetermined focal points more significantly and finally, their functionality and performances are verified in several experiments. Current UPT systems suffer from significant acoustic losses through the transmission from a transmitter to an acoustic medium and then to a receiver due to the different acoustic impedance (defined as the product of density and sound speed) between the medium and transducers material, which reflects most of the incident pressure wave at the boundary layers. The second enhancement technology addressed in this dissertation is using intermediate materials, called acoustic impedance matching layers, bonded to the front side of the transmitter and receiver face to alleviate the acoustic impedance mismatch. Experiments are performed to identify the input acoustic pressure from a transmitter to a receiver. Using a two-layer matching structure, significant enhancements are observed in terms of the receiver's electrical power output. A design platform is also developed that can facilitate the construction of high-fidelity acoustically matched transducers, that is, the material layers' selection and determination of their thicknesses. Furthermore, this dissertation presents a numerical analysis for the dynamical motions of a microbubble exposed to a high-intensity focused ultrasound (HIFU) field, which entails the problem of several biomedical ultrasound applications such as microbubble-mediated ultrasound therapy or targeted drug delivery. Finally, an enhancement technique involving the design and use of acoustic holograms in microfluidic channels is addressed which opens the door of acoustic patterning in particle and cell sorting for medical ultrasound systems.

acoustic hologram

acoustic patterning

ultrasonic power transfer

acoustic impedance matching layers

high-intensity focused ultrasound

nonlinear acoustics

piezoelectric transducers

stable cavitation

ultrasound microbubble dynamics

Transcranial Ultrasound Holograms for the Blood-Brain Barrier Opening

Jiménez Gambín, Sergio

02 September 2021

[ES] El tratamiento de enfermedades neurológicas está muy limitado por la ineficiente penetración de los fármacos en el tejido cerebral dañado debido a la barrera hematoencefálica (BHE), lo que imposibilita mejorar la salud del paciente. La BHE es un mecanismo de protección natural para evitar la difusión de agentes potencialmente peligrosas para el sistema nervioso central. No obstante, la BHE se puede inhibir mediante ultrasonidos focalizados e inyección de microburbujas de forma segura, localizada y transitoria, una tecnología empleada mundialmente. La principal ventaja es su carácter no invasivo, siendo así muy atractiva y cómoda para el paciente. Normalmente, la zona cerebral enferma se trata en su parte central empleando un único foco. Sin embargo, enfermedades como el Alzheimer o el Parkinson requieren un tratamiento sobre estructuras de geometría compleja y tamaño elevado, situadas en ambos hemisferios cerebrales. Por tanto, la tecnología actual está muy limitada al no cumplir dichos requisitos. Esta tesis doctoral tiene como objetivo el desarrollo de una técnica novedosa, basada en hologramas acústicos, para resolver las limitaciones presentes en los tratamientos neurológicos empleando ultrasonidos. Se estudian las lentes acústicas holográficas impresas en 3D, que acopladas a un transductor mono-elemento, permiten el control preciso del frente de onda ultrasónico tanto para (1) compensar las distorsiones que sufre el haz hasta alcanzar el cerebro, como (2) focalizarlo simultáneamente en regiones múltiples y de geometría compleja o formando de vórtices acústicos, proporcionando así efectividad en tiempo y coste. Por ello, la investigación desarrollada en esta tesis abre un camino prometedor en el campo de la biomedicina que permitirá mejorar los tratamientos neurológicos, además de aplicaciones en neuroestimulación o ablación térmica del tejido. / [CA] El tractament de malalties neurològiques està molt limitat per la ineficient penetració del fàrmac en el teixit cerebral danyat a causa de la barrera hematoencefàlica (BHE), i així no és possible una millora de salut del pacient. La BHE és un mecanisme de protecció natural per a evitar la difusió d'agents potencialment perillosos per al Sistema Nervios Central. No obstant això, aquesta barrera es pot inhibir mitjancant una tecnologia emprada mundialment basada en ultrasons focalitzats i injeccio de microbombolles. El principal avantatge és el seu caràcter no invasiu, sent així molt atractiva i còmoda per al pacient, i permet obrir la BHE de manera segura, localitzada i transitòria. Normalment, la zona cerebral malalta es tracta en la seua part central, emprant un unic focus. No obstant això, malalties com l'Alzheimer o el Parkinson requereixen un tractament al llarg d'estructures de geometria complexa i grandària elevada, situades en tots dos hemisferis cerebrals. Per tant, la tecnologia actual està fortament limitada al no complir amb aquests requeriments. Aquesta tesi doctoral està enfocada a investigar i desenvolupar una tècnica nova, basada en hologrames acústics, per a solucionar les limitacions presents en els tractaments neurològics. Una lent acústica holograca de baix cost impresa en 3D acoblada a un transductor d'element simple permet el control precs del front d'ona ultrasònic punt per a (1) compensar les distorsions que pateix el feix en el seu camí cap al cervell, i (2) focalització simultània del feix en regions multiples i de geometria complexa, proporcionant aix un tractament efectiu en temps i cost. Per això, la investigació desenvolupada en aquesta tesi demostra la possibilitat de realitzar qualsevol tractament neurològic, a més d'aplicacions en la neuroestimulació o l'ablació tèrmica dins del camp biomèdic. / [EN] Treatments for neurological diseases are strongly limited by the inefficient penetration of therapeutic drugs into the diseased brain due to the blood-brain barrier (BBB), and therefore no health improvement can be achieved. In fact, the BBB is a protection mechanism of the human body to avoid the diffusion of potentially dangerous agents into the central nervous system. Nevertheless, this barrier can be successfully inhibited by using a worldwide spread technology based on microbubble-enhanced focused ultrasound. Its main advantage is its non-invasive nature, thus defining a patient-friendly clinical procedure that allows to disrupt the BBB in a safe, local and transient manner. Conventionally, the diseased brain structure has been targeted in its center, with a single focus. However, Alzheimer's or Parkinson's Diseases do require that ultrasound is delivered to entire, complex-geometry and large-volume structures located at both hemispheres of the brain. Therefore, current technology presents several limitations as it does not fulfill these requirements. This doctoral thesis aims to develop a novel technique based on using focused ultrasound acoustic holograms to solve the existing limitations to treat neurological diseases. In this dissertation, we study 3D-printed holographic acoustic lenses coupled to a single-element transducer that allow to accurately control the acoustic wavefront to both (1) compensate distortions suffered by the beam in its path to the brain, and (2) simultaneous focusing in multiple and complex-geometry structures or acoustic vortex generation, providing a time- and cost- efficient procedure. Therefore, the research carried out throughout this thesis opens a promising path in the biomedical field to improve the treatment for neurological diseases, neurostimulation or tissue ablation applications. / Acknowledgments to the Spanish institution Generalitat Valenciana, which funding grant allowed me to develop this doctoral thesis, and as well funded my research stay at Columbia University. The development of the entire thesis was supported through grant Nª. ACIF/2017/045. Particularly, the research carried out in Chapter 3 and Chapter 4 was possible thanks to and supported through grant BEFPI/2019/075. Action co-financied by the Agència Valenciana de la Innovació through grant INNVAL10/19/016 and by the European Union through the Programa Operativo del Fondo Europeo de Desarrollo Regional (FEDER) of the Comunitat Valenciana 2014-2020 (IDIFEDER/2018/022). / Jiménez Gambín, S. (2021). Transcranial Ultrasound Holograms for the Blood-Brain Barrier Opening [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/171373

Aplicaciones biomédicas

Barrera hematoencefálica (BHE)

FUS transcraneales

Ultrasonidos focalizados

Hologramas acústicos

Acoustic hologram

Focused ultrasound

Transcranial FUS

Blood-brain barrier opening

Biomedical applications

FISICA APLICADA

Towards Navigational Aids using Augmented Reality for People with Alzheimer’s Disease in Outdoor Environments : A user study using HoloLens 2 around a University campus

Prémont, Léa

January 2023

This paper investigates the potential of augmented reality (AR) as a navigational aid for individuals with Alzheimer’s disease (AD), offering innovative solutions to the evolving challenges of AD care. As the disease progresses, patients often require more assistance and may transition to care centers, resulting in reduced independence. Prior to this, home-based care aims to stimulate cognitive functions and preserve autonomy. To enhance their freedom and mobility, it is proposed to leverage AR technology to create a first-person navigational aid addressing the unique needs of AD patients. The research confronts two primary challenges: firstly, exploring the design of AR navigational aids customized for individuals with Alzheimer’s disease adapted to outdoor use. Then, it aims to develop an outdoor localization system for the HoloLens 2 and evaluate its performance. Despite limitations induced by the approximate positioning, various types of aids compatible with the technical constraints faced have been envisioned. A set of features was implemented using the optical see-through AR headset HoloLens 2. These features included two distinct types of holograms (Arrow and Wind) and the ability to catch user attention prior to turns, allowing us to explore the effectiveness of these design choices. They were evaluated through a user study involving 15 healthy participants. Usability and task load were measured with Nasa-TLX and SUS questionnaires. An approximate positioning for outdoor use of the HoloLens 2 was elaborated using a smartphone as a GPS receiver, and a Kalman filter for filtering and fusion with IMU data. This enables to reach positioning accuracy at the meter level. This research demonstrates the promising utility of AR in assisting navigation in outdoor environments. Despite few significant results, the Arrow hologram appears to be a better fit for usability and users’ personal preferences. Further research is needed to get significant results on the impact of adaptive aids. The outdoor use of AR navigational aids is still limited by the poor visibility of holograms outdoors and low positioning accuracy. / Denna artikel utforskar potentialen hos förstärkt verklighet (AR) som navigationshjälpmedel för personer med Alzheimers sjukdom (AD) och erbjuder innovativa lösningar inom AD-vård. När sjukdomen fortskrider behöver patienterna mer hjälp och kan övergå till vårdcentraler, vilket minskar deras självständighet. Hemvård strävar efter att stimulera kognitiva funktioner och bevara autonomi. Vi föreslår utnyttja AR-teknologi för en skräddarsydd navigeringshjälp i första person för AD-patienters behov. Forskningen möter två utmaningar: att utforska AR-navigeringshjälpmedel för personer med Alzheimers sjukdom och anpassade för utomhusanvändning. Vi strävar efter att utveckla utomhuslokaliseringssystem för HoloLens 2 och utvärdera prestanda. Trots begränsningar på grund av ungefärlig positionering kan vi föreställa oss hjälpmedel som är kompatibla med tekniska begränsningar. Vi använde HoloLens 2 med funktioner som två hologramtyper och användaruppmärksamhetsfångst före svängar, utvärderat med 15 deltagare. Vi skapade ungefärlig positionering för HoloLens 2 utomhus med en smartphone som GPS-mottagare, med Kalman-filtrering och IMU-fusion för meter-noggrannhet. Forskningen visar AR:s lovande nytta i utomhusnavigering. Trots få signifikanta resultat verkar pilhologrammet passa användbarhet och preferenser bättre. Mer forskning behövs för att bedöma adaptiva hjälpmedels effekter. Användningen av AR-navigeringshjälpmedel utomhus begränsas av dålig synlighet och låg positionsnoggrannhet. / Cet article explore le potentiel de la réalité augmentée (RA) comme aide à la navigation pour les personnes atteintes de la maladie d’Alzheimer (MA), offrant une solution novatrice aux défis en constante évolution des soins liés à la MA. À mesure que la maladie progresse, les patients ont souvent besoin d’une assistance accrue et sont transférés dans des centres de soins, ce qui diminue leur indépendance. Avant cela, les soins à domicile visent à stimuler leurs fonctions cognitives et à préserver leur autonomie. Dans cette optique, nous proposons d’utiliser la RA pour créer une aide à la navigation à la première personne adaptée aux besoins spécifiques des patients atteints de la MA. La recherche aborde deux défis principaux : la conception d’aides à la navigation en RA pour les personnes atteintes de la MA, adaptées à une utilisation en extérieur, et le développement d’un système de localisation en extérieur pour HoloLens 2, suivi de son évaluation. Malgré les limitations liées au positionnement approximatif, nous avons envisagé différents types d’aides compatibles avec ces contraintes techniques. Nous avons mis en place un ensemble de fonctionnalités en utilisant le casque de RA HoloLens 2. Ces fonctionnalités incluent deux types d’hologrammes (Flèche et Vent) et la capacité à attirer l’attention de l’utilisateur avant les virages, nous permettant d’explorer l’efficacité de ces choix de conception. Ils ont été évalués lors d’une étude avec 15 participants en bonne santé. Nous avons élaboré une méthode de positionnement approximatif pour une utilisation en extérieur de l’HoloLens 2 en utilisant un smartphone comme récepteur GPS, avec un filtre de Kalman pour le filtrage et la fusion avec des données inertielles, permettant d’atteindre une précision de positionnement au mètre. Cette recherche démontre l’utilité prometteuse de la RA dans l’assistance à la navigation en extérieur, bien que des recherches supplémentaires soient nécessaires pour obtenir des résultats significatifs sur l’impact des aides adaptatives. L’utilisation des aides à la navigation en RA en extérieur est encore limitée par la visibilité réduite des hologrammes en extérieur et la faible précision du positionnement.

Augmented reality

Alzheimer’s disease

Navigation

Assistive technology

HoloLens 2

Optical See-Through

Localization

Kalman filter

Hologram

TLX

SUS

Réalité augmentée

Alzheimer

Navigation

Technologie d’assistance

HoloLens 2

Optical See-Through

Localisation

Filtre de Kalman

Hologramme

TLX

SUS

Förstärkt verklighet

Alzheimers sjukdom

Navigering

Tekniska hjälpmedel

HoloLens 2

Optisk genomskinlighet

Lokalisering

Kalman-filter

Hologram

TLX

SUS

Computer and Information Sciences

Data- och informationsvetenskap

Estudos de HQSAR, acoplamento molecular e cálculos de propriedades eletrônicas de compostos com atividade biológica frente aos alvos DPP-IV e FAPa

Martins, Michelle Cristiane Melo Reis

January 2018

Orientadora: Profa. Dra. Káthia Maria Honório / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Ciência e Tecnologia/Química, Santo André, 2018. / Um dos alvos biologicos relacionado ao controle da glicemia e a enzima dipeptidil peptidase-IV (DPP-IV); ela esta associada com a estimulacao do pancreas na producao de insulina, sendo, portanto, um alvo de interesse da pesquisa e da industria farmaceutica para o tratamento do diabetes tipo 2. O diabetes e uma doenca cronica que se caracteriza por um aumento da glicemia causando uma serie de complicacoes fisiologicas com destaque para as doencas cardiacas como a aterosclerose; estima-se que 425 milhoes de pessoas sejam portadoras da doenca. Estudos indicam que inibidores da DPP-IV tambem podem apresentar acao sobre a FAP¿¿, uma enzima que esta relacionada com reparacao de tecidos e crescimento de tumores. Este trabalho consiste em utilizar metodos de modelagem molecular, como a construcao e analise de modelos de HQSAR (Hologram Quantitative Structure-Activity) e de CoMFA (analise comparativa de campos de interacao molecular); acoplamento molecular (docking), analise de propriedades eletronicas e deteccao e caracterizacao de sitios de ligacao da enzima FAP¿¿, com intuito de compreender as principais caracteristicas de ambas as enzimas, assim como a interacao das mesmas com uma serie de compostos bioativos. Os modelos CoMFA construidos apresentaram significativos valores de validacao interna (0,768) e externa (0,986); o alinhamento obtido utilizando a tecnica de acoplamento molecular e complementada com o uso da tecnica BINANA delineou as principais interacoes das enzimas com o conjunto de ligantes; identificou-se tres sitios de ligacao da enzima FAP¿¿ utilizando os servidores FTSite e FTMap. Desta forma, com informacoes sobre ambos os alvos e as interacoes estabelecidas com os ligantes, sera possivel propor com maior seguranca modificacoes moleculares para tais compostos candidatos a farmacos mais seguros para o tratamento do diabetes tipo 2. / One of the biological targets related to glycemic control is the dipeptidyl peptidase IV (DPP-IV) enzyme; it is associated with stimulation of the pancreas in insulin production and it is a target of interest for the researches related to the treatment of type 2 diabetes. Diabetes is a chronic disease characterized by an increase in blood glucose causing a series of physiological complications such as atherosclerosis, it is estimated that 425 million people have this disease. Studies have indicated that DPP-IV inhibitors may also have action on FAPá, an enzyme that is related to tissue repair and tumor growth. This work consists of using molecular modeling methods, such as the construction and analysis of HQSAR (Hologram Quantitative Structure-Activity) and CoMFA (comparative analysis of molecular interaction fields) models; molecular docking, analysis of electronic properties, detection and characterization of FAPá enzyme binding sites, and pharmacokinetic and pharmacodynamic properties studies; in order to understand the main characteristics of both enzymes, as well as their interaction with a series of bioactive compounds. The CoMFA models presented significant values of internal validation (0,768) and external (0,986) and the alignment obtained using the molecular docking technique outlined the main interactions of the enzymes with the set of ligands. With information on both targets and the interactions established with the ligands, it will be possible to more safely propose molecular modifications for such safer drug candidates for the treatment of type 2 diabetes.

DIABETES

DIPEPTIDIL PEPTIDASE-IV

FAPa

INTERAÇÕES

MODELAGEM MOLECULAR

HOLOGRAM QUANTITATIVE STRUCTURE-ACTIVITY

INTERACTIONS

MOLECULAR MODELING

Akcelerace algoritmů na architektuře Larrabee / Algorithm Acceleration on Larrabee Platform

Veselý, Ivo

January 2010

Intel Larrabee is one of the first of fully programmable graphical architectures. Thesis describes this many-core architecture by hardware implementation and programmer's model point of view. Larrabee bets on many complete in-order cores, built over x86 instruction set. Cores contains four hardware threads, each with it's own register file, and new vector processing unit. Vector processing unit together with instruction set extension rapidly increases system performance. New cache modes helps to increase throughput even when irregular data structures. This architecture is not focused only on computer graphics nor image processing, but all parallel tasks. Second part of this text deals with hologram synthesis. Specifically, it brings two new methods for patch of point light sources generation with concrete radiation.