Numerical Simulations of Magnetohydrodynamic Flow and Heat Transfer

KC, Amar

January 2014

No description available.

Mechanical Engineering

Characterization of an Adaptive Optics System for Vision Studies

Bai, Yu

23 May 2016

No description available.

Electrical Engineering

Optics

Medical Imaging

adaptive optics

deformable mirror

Shack-Hartmann wavefront sensor

Phase Transform Time Delay Estimation to Counteract Spectral Haystacking Effects in Jet Exhaust Flow Measurements

Silas, Kevin Alexander

01 September 2021

This study determined a superior data processing technique for correlating an acoustic signal passing through a subsonic jet engine exhaust in order to estimate the traversal time of the signal. Thrust measurement is possible with enough time delay estimates across different portions of the exhaust. This preliminary study did not take the full array of data necessary to measure thrust, but did validate key aspects of the measurement process. The turbulent shear layers of the exhaust spectrally broaden the signal, creating the appearance of spectral "haystacks", making traditional correlation methods unworkable. An experiment was performed to evaluate the ability of a novel sound source to produce a signal from which a reliable and precise time delay estimate could be found. The test apparatus was installed on either side of a Honeywell TFE731-2 turbofan research engine exhaust cone, with the source and receivers placed near the jet exit plane. The signal was then directed across the jet exhaust. This flow environment is considered an extreme challenge for accurate acoustic signal propagation. A key contribution of this paper is the determination that the Phase Transform processor of the Generalized Cross-Correlation (GCC) method produces the most reliable time delay estimates, for the given signal and flow conditions. Several alternative time delay estimators and GCC processors were examined and evaluated on this data. A proposed explanation is provided for why this time delay estimation technique produces the most accurate results, as well as explanations for why the technique became less reliable as the flow environment became more challenging, with an observed 22% anomalous TDE selection rate for the N1Corr = 60% and N1Corr = 70% conditions combined, versus only 6% for the idle and N1Corr = 50% conditions combined. This paper also details the development and first use of a novel acoustic source that produces a two-tone narrowband signal emanating from a single point – the dual Hartmann generator. / Master of Science / This study builds on a Computational Tomography (CT) technique that uses an acoustic signal and an array of receivers to measure the velocity and temperature of a gas flow field. In particular, the velocity and temperature field tested involves multiple turbulent and disruptive elements, requiring a loud and specifically designed signal. As such, a novel acoustic signal generator, the dual Hartmann generator, was designed that is both loud and produces a specific two-toned signal. The key contribution of the study was to process the data, comparing the sets of transmitted and received signals, in order to estimate the time delay amongst receiver pairs – a key input in the CT method. Traditional cross-correlation methods were inadequate, and multiple alternatives were evaluated. The Phase Transform (PHAT) technique showed the most promise, and an explanation is given for why this technique is most suitable for this type of signal.

PHAT

Signal Processing

Acoustics

Hartmann

Maximum Likelihood

phase transform

coaxial bypass

shear layer

haystacking

Sensor de frente de onda para uso oftalmológico / Wavefront sensor for ophthalmological use

Santos, Jesulino Bispo dos

16 April 2004

Este trabalho descreve os passos envolvidos no desenvolvimento de um protótipo de aberroscópio para uso oftalmológico. Este instrumento faz incidir no fundo do olho humano um feixe luminoso de baixa potência e amostra, por meio do método de Hartmann, as frentes de onda da luz espalhada. A partir dos dados coletados, a forma das frentes de onda são reconstituídas e as aberrações eventualmente existentes no olho são calculadas e representadas por intermédio dos polinômios de Zernike. Aqui são expostos os fundamentos deste método, algumas das suas propriedades e limitações. Também é mostrada a caracterização funcional do protótipo desenvolvido, testando-o com elementos ópticos de propriedades conhecidas / This work describes the steps involved in the aberroscope prototype development for ophthalmological use. This instrument injects inside the human eye a low power light beam and sample, by Hartmann method, the wavefronts produced by ocular fundus light scattering. From collected data, the wavefront shape is reconstructed and the eye aberrations that eventually existent are calculated and adjusted by Zernike polynomials. Are discussed the method foundations, some of properties and limitations. Also the functional characterization of the developed prototype is shown, by testing it with optical elements of known properties

aberroscope

aberroscópio

applied optics

biomedical engineering

engenharia biomédica

frente de onda

Hartmann-Shack sensor

instrumentação médica

instrumentação oftalmológica

medical instrumentation

ophthalmological instrumentation

óptica aplicada

phase sensor

sensor de fase

sensor Hartmann-Shack

wavefront

Sensor de frente de onda para uso oftalmológico / Wavefront sensor for ophthalmological use

Jesulino Bispo dos Santos

16 April 2004

Este trabalho descreve os passos envolvidos no desenvolvimento de um protótipo de aberroscópio para uso oftalmológico. Este instrumento faz incidir no fundo do olho humano um feixe luminoso de baixa potência e amostra, por meio do método de Hartmann, as frentes de onda da luz espalhada. A partir dos dados coletados, a forma das frentes de onda são reconstituídas e as aberrações eventualmente existentes no olho são calculadas e representadas por intermédio dos polinômios de Zernike. Aqui são expostos os fundamentos deste método, algumas das suas propriedades e limitações. Também é mostrada a caracterização funcional do protótipo desenvolvido, testando-o com elementos ópticos de propriedades conhecidas / This work describes the steps involved in the aberroscope prototype development for ophthalmological use. This instrument injects inside the human eye a low power light beam and sample, by Hartmann method, the wavefronts produced by ocular fundus light scattering. From collected data, the wavefront shape is reconstructed and the eye aberrations that eventually existent are calculated and adjusted by Zernike polynomials. Are discussed the method foundations, some of properties and limitations. Also the functional characterization of the developed prototype is shown, by testing it with optical elements of known properties

aberroscópio

engenharia biomédica

frente de onda

instrumentação médica

instrumentação oftalmológica

óptica aplicada

sensor de fase

sensor Hartmann-Shack

aberroscope

applied optics

biomedical engineering

Hartmann-Shack sensor

medical instrumentation

ophthalmological instrumentation

phase sensor

wavefront

Charaktere und Hauptideen in 'Der arme Heinrich' Hartmanns von Aue und Gerhart Hauptmanns

Pluddemann, Ulrich Richard Reinold

12 1900

Thesis (MA) -- Stellenbosch University, 1961. / No Abstract Available

Dissertations -- German literature

Theses -- German literature

Charaktere und Hauptideen in den Gregoriusgestaltungen Hartmanns von Aue und Thomas Manns

Kucharzik, Arno

12 1900

Thesis (MLitt.) -- Stellenbosch University, 1964. / No Abstract Available

Mann, Thomas, -- 1875-1955 -- Erwahlte

Dissertations -- German literature

Theses -- German literature

Application and System Design of Elastomer Based Optofluidic Lenses

Savidis, Nickolaos

January 2012

Adaptive optic technology has revolutionized real time correction of wavefront aberrations. Optofluidic based applied optic devices have offered an opportunity to produce flexible refractive lenses in the correction of wavefronts. Fluidic lenses have superiority relative to their solid lens counterparts in their capabilities of producing tunable optical systems, that when synchronized, can produce real time variable systems with no moving parts. We have developed optofluidic fluidic lenses for applications of applied optical devices, as well as ophthalmic optic devices. The first half of this dissertation discusses the production of fluidic lenses as optical devices. In addition, the design and testing of various fluidic systems made with these components are evaluated. We begin with the creation of spherical or defocus singlet fluidic lenses. We then produced zoom optical systems with no moving parts by synchronizing combinations of these fluidic spherical lenses. The variable power zoom system incorporates two singlet fluidic lenses that are synchronized. The coupled device has no moving parts and has produced a magnification range of 0.1 x to 10 x or a 20 x magnification range. The chapter after fluidic zoom technology focuses on producing achromatic lens designs. We offer an analysis of a hybrid diffractive and refractive achromat that offers discrete achromatized variable focal lengths. In addition, we offer a design of a fully optofluidic based achromatic lens. By synchronizing the two membrane surfaces of the fluidic achromat we develop a design for a fluidic achromatic lens.The second half of this dissertation discusses the production of optofluidic technology in ophthalmic applications. We begin with an introduction to an optofluidic phoropter system. A fluidic phoropter is designed through the combination of a defocus lens with two cylindrical fluidic lenses that are orientated 45° relative to each other. Here we discuss the designs of the fluidic cylindrical lens coupled with a previously discussed defocus singlet lens. We then couple this optofluidic phoropter with relay optics and Shack-Hartmann wavefront sensing technology to produce an auto-phoropter device. The auto-phoropter system combines a refractometer designed Shack-Hartmann wavefront sensor with the compact refractive fluidic lens phoropter. This combination allows for the identification and control of ophthalmic cylinder, cylinder axis, as well as refractive error. The closed loop system of the fluidic phoropter with refractometer enables for the creation of our see-through auto-phoropter system. The design and testing of several generations of transmissive see-through auto-phoropter devices are presented in this section.

Auto-Phoropter

Fluidic Zoom Imaging

Optofluidics

Shack-Hartmann Wavefront Sensing

Optical Sciences

Accomodating Achromat

Adaptive Optic Lenses

Erzählstruktur und Hofkultur weibliches Agieren in den europäischen Iweinstoff-Bearbeitungen des 12. bis 14. Jahrhunderts

Breulmann, Julia

January 2007

Zugl.: Münster (Westfalen), Univ., Diss., 2007

Design and characterization of an optical tweezers system with adaptive optic control

Bowman, Shaun

23 December 2009

The thesis details the design and characterization of an innovative optical tweezer system. Optical tweezers provide a relatively new technique for non-contact manipulation of micron-scale particles. They employ a laser beam to hold such particles at the laser’s focus. Optical tweezers are used for many scientific purposes, such as: measuring the mechanical properties of bio-molecules, cell and molecule sorting, stiction-less micro-manipulators, and fundamental research in physics. Typically, trap location has been controlled using steer-mirrors or spatial light modulators, operating without beam quality feedback. Here, an innovative trap control system has been developed, featuring a closed-loop adaptive optics system. The prototype system employs a deformable mirror and wavefront sensor to control trap position in three dimensions, while simultaneously removing beam aberrations. The performance of this system is investigated in terms of controllable range of trap motion, trap stiffness, and trap position stability.

Adaptive Optics

Optical tweezers

Hartmann

Mirror

Singlular value decomposition

DMM

trapping

laser

wavefront

phase

aberrations