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21	Preliminary Design of an Autonomous Underwater Vehicle Using a Multiple-Objective Genetic Optimizer Martz, Matthew 26 June 2008 (has links) The process developed herein uses a Multiple Objective Genetic Optimization (MOGO) algorithm. The optimization is implemented in ModelCenter (MC) from Phoenix Integration. It uses a genetic algorithm that searches the design space for optimal, feasible designs by considering three Measures of Performance (MOPs): Cost, Effectiveness, and Risk. The complete synthesis model is comprised of an input module, the three primary AUV synthesis modules, a constraint module, three objective modules, and a genetic algorithm. The effectiveness rating determined by the synthesis model is based on nine attributes identified in the US Navy's UUV Master Plan and four performance-based attributes calculated by the synthesis model. To solve multi-attribute decision problems the Analytical Hierarchy Process (AHP) is used. Once the MOGO has generated a final generation of optimal, feasible designs the decision-maker(s) can choose candidate designs for further analysis. A sample AUV Synthesis was performed and five candidate AUVs were analyzed. / Master of Science MDO Optimization Genetic Genetic Algorithm AUV Autonomous Underwater Vehicle
22	Design of a Low Reynolds Number Propulsion System for an Autonomous Underwater Vehicle Portner, Stephen Michael 20 August 2014 (has links) A methodology for the design of small autonomous underwater vehicle propulsion systems has been developed and applied to the Virginia Tech 690 AUV. The methodology is novel in that it incorporates fast design level codes capable of predicting the viscous effects of low Reynolds number flow that is experienced by small, slow turning propellers. The methodology consists of determining the minimum induced loss lift distribution for the propeller via lifting line theory, efficient airfoil sections for the propeller via a coupled viscous-inviscid flow solver and optimization, brushless DC motor identification via ideal motor theory and total system efficiency estimates. The coupled viscous-inviscid flow solver showed low Reynolds number flow effects to be of critical importance in the propeller design. The original Virginia Tech 690 AUV propulsion system was analyzed yielding an experimental efficiency of 26.5%. A new propeller was designed based on low Reynolds number airfoil section data yielding an experimental efficiency of 42.7%. Finally, an entirely new propulsion system was designed using the methodology developed herein yielding a predicted efficiency of 57-60%. / Master of Science Autonomous Underwater Vehicle Low Reynolds Number Propeller Propulsion
23	Mechanical Design of a Trawl-Resistant Self-Mooring Autonomous Underwater Vehicle Wilson, Taylor Boyde 27 January 2016 (has links) The Virginia Tech Trawl-Resistant Self-Mooring Autonomous Underwater Vehicle (TRSMAUV) is designed to reside on the seafloor for extended periods of time. The TRSMAUV shape allows for deployment in areas where trawl fisheries are conducted. TRSMAUV is a two stage vehicle. The ingress vehicle is the delivery device, and it is constructed from two symmetric halves. The top half contains the ingress vehicle propulsion system and control surfaces. The bottom half is the trawl-resistant mooring package. A smaller vehicle, the egress vehicle, is housed within the bottom ingress half and provides the guidance, navigation and control algorithms for the TRSMAUV. This report covers the general design elements of the TRSMAUV, the detail design of several prototypes, the results of the field trials, and the next steps that will be taken to build the final vehicle. / Master of Science Autonomous Underwater Vehicle Self-Mooring Trawl-Resistant AUV TRSMAUV
24	Input of Factor Graphs into the Detection, Classification, and Localization Chain and Continuous Active SONAR in Undersea Vehicles Gross, Brandi Nicole 10 September 2015 (has links) The focus of this thesis is to implement factor graphs into the problem of detection, classification, and localization (DCL) of underwater objects using active SOund Navigation And Ranging (SONAR). A factor graph is a bipartite graphical representation of the decomposition of a particular function. Messages are passed along the edges connecting factor and variable nodes, on which, a message passing algorithm is applied to compute the posterior probabilities at a particular node. This thesis addresses two issues. In the first section, the formulation of factor graphs for each section of the DCL chain required followed by their closed-form solutions. For the detector, the factor graph determines if the signal is a detection or simply noise. In the classifier, it outputs the probability for the elements in the class. Last, when using a factor graph for the tracker, it gives the estimated state of the object being tracked. The second part concentrates on the application to Continuous Active SONAR (CAS). When using CAS, a bistatic configuration is used allowing for a more rapid update rate where two unmanned underwater vehicles (UUVs) are used as the receiver and transmitter. The goal is to evaluate CAS's effectiveness to determine if the tracking accuracy improves as the transmit interval decreases. If CAS proves to be more efficient in target tracking, the next objective is to determine which messages sent between the two UUVs are most beneficial. To test this, a particle filter simulation is used. / Master of Science continuous active SONAR unmanned underwater vehicle factor graph particle filter
25	Movement control and guidance of an automated underwater vehicle Pauck, Simon James 03 1900 (has links) Thesis (MScEng (Electrical and Electronic Engineering))--University of Stellenbosch, 2010. / ENGLISH ABSTRACT: This thesis presents the design process of the movement control and guidance systems for an automated underwater vehicle (AUV) constructed by the Institute of Maritime Technology in Simon’s Town. The full non-linear mathematical model and simulation environment for the AUV were previously developed in [1]. The design process in this thesis covers an analysis of existing test data and the performance of the current systems in place on the AUV, derivation and analysis of the linear model for the AUV, design of upgraded control and guidance systems, analysis of the new designs including simulation results, practical implementation of the new designs and the results thereof. Over the course of this project a number of flaws were identified in the original control designs and other aspects of the AUV. Most notably, the capability of the AUV is limited owing to its construction, and the current control and guidance methods result in poor movement characteristics. The new control designs are executed through multiple SISO feedback loops, with the most complicated controllers consisting of proportional and integral control. A completely new guidance method was designed which grants theAUVthe ability to track both straight line and circular path segments with no steady state error. These designs were tested in simulation, with results showing good tracking performance, even in the presence of output disturbances. The new designs were implemented on the physical AUV, but testing was limited, with poor results being obtained. The poor test results were caused primarily by the construction of the AUV. / AFRIKAANSE OPSOMMING: Hierdie tesis stel die ontwerpsproses voor vir die bewegingsbeheer- en navigasiestelsels vir ’n outonome duikboot wat gebou is deur die Instituut vir Maritieme Tegnologie in Simonstad. Die volle nie-lineˆere wiskundige model en simulasieomgewing vir die duikboot is voorheen ontwikkel in [1]. Die ontwerpsproses in hierdie tesis behels ’n analise van bestaande toetsdata en van die werksverrigting van die stelsels wat tans op die duikboot ge¨ınstalleer is, die afleiding en analise van ’n lineˆere model vir die duikboot, die ontwerp van verbeterde beheer- en navigasiestelsels, die analise van die nuwe ontwerpe, wat simulasieresultate insluit, die praktiese implementering van die nuwe ontwerpe, en die resultate daarvan. Deur die loop van die projek is ’n aantal tekortkominge ge¨ıdentifiseer in die oorspronklike beheerstelselontwerpe en ander aspekte van die duikboot. Die mees beduidende tekortkominge is dat die vermo¨e van die duikboot beperk word deur die konstruksie daarvan, en dat die huidige beheer- en navigasietegnieke swak bewegingseienskappe lewer. Die nuwe beheerstelselontwerpe is uitgevoer deur ’n aantal enkelintree, enkeluittree terugvoerlusse, waar die mees komplekse beheerders bestaan uit proporsionele en integraalbeheer. ’n Heeltemal nuwe navigasiemetode is ontwerp, wat die duikboot in staat stel om beide reguit lyne en sirkulˆere padsegmente te volg sonder ’n stasionˆere volgfout. Hierdie ontwerpe is getoets in simulasie, waar die resultate goeie volging getoon het, selfs in die teenwoordigheid van uittreeversteurings. Die nuwe ontwerpe is ge¨ımplementeer op die fisiese duikboot, maar beperkte toetse is gedoen, en het swak resultate gelewer. Die swak toetsresultate was hoofsaaklik as gevolg van die konstruksie van die duikboot. Automated underwater vehicle (AUV) Remote submersibles -- Control Automated underwater vehicle -- Buoyancy Dissertations -- Electronic engineering Theses -- Electronic engineering Remote submersibles Remote submersibles -- Guidance systems
26	Automatic Tuning of Motion Control System for an Autonomous Underwater Vehicle Andersson, Markus January 2019 (has links) The interest for marine research and exploration has increased rapidly during the past decades and autonomous underwater vehicles (AUV) have been found useful in an increased amount of applications. The demand for versatile platform AUVs, able to perform a wide range of tasks, has become apparent. A vital part of an AUV is its motion control system, and an emerging problem for multipurpose AUVs is that the control performance is affected when the vehicle is configured with different payloads for each mission. Instead of having to manually re-tune the control system between missions, a method for automatic tuning of the control system has been developed in this master’s thesis. A model-based approach was implemented, where the current vehicle dynamics are identified by performing a sequence of excitation maneuvers, generating informative data. The data is used to estimate model parameters in predetermined model structures, and model-based control design is then used to determine an appropriate tuning of the control system. The performance and potential of the suggested approach were evaluated in simulation examples which show that improved control can be obtained by using the developed auto-tuning method. The results are considered to be sufficiently promising to justify implementation and further testing on a real AUV. The automatic tuning process is performed prior to a mission and is meant to compensate for dynamic changes introduced between separate missions. However, the AUV dynamics might also change during a mission which requires an adaptive control system. By using the developed automatic tuning process as foundation, the first steps towards an indirect adaptive control approach have been suggested. Also, the AUV which was studied in the thesis composed another interesting control problem by being overactuated in yaw control, this because yawing could be achieved by using rudders but also by differential drive of the propellers. As an additional and separate part of the thesis, an approach for using both techniques simultaneously have been proposed. Automatic Control Automatic Tuning Control Motion Control Modelling System Identification Online Identification Underwater Vehicle Autonomous Underwater Vehicle AUV SMaRC Maribot LoLo Differential drive Control Engineering Reglerteknik
27	Experiments with the REMUS AUV Phaneuf, Matthew D. 06 1900 (has links) Approved for public release; distribution is unlimited / This thesis centers around actual field operations and post-mission analysis of data acquired using a REMUS AUV operated by the Naval Postgraduate School Center for Autonomous Underwater Vehicle Research. It was one of many platforms that were utilized for data collection during AOSN II, (Autonomous Oceanographic Sampling Network II), an ONR sponsored exercise for dynamic oceanographic data taking and model based analysis using adaptive sampling. The vehicle's ability to collect oceanographic data consisting of conductivity, temperature, and salinity during this experiment is assessed and problem areas investigated. Of particular interest are the temperature and salinity profiles measured fromlong transect runs of 18 Km. length into the southern parts of Monterey Bay. Experimentation with the REMUS as a mine detection asset was also performed. The design and development of the mine hunting experiment is discussed as well as its results and their analysis. Of particular interest in this portion of the work is the issue relating to repeatability and precision of contact localization, obtained from vehicle position and sidescan sonar measurements. / Lieutenant, United States Navy Remote submersibles Mines (Military explosives) Detection Submarine mines REMUS AUV Autonomous underwater vehicle Mine hunting AOSN
28	Modelagem e identificação de parâmetros hidrodinâmicos de um veículo robótico submarino. / Modelling and Identification of hydrodynamic parameters of an underwater robotic vehicle. Julca Avila, Juan Pablo 17 October 2008 (has links) Esta tese apresenta um procedimento de identificação experimental de coeficientes hidrodinâmicos de veículos submarinos não tripulados. Apresenta-se o desenvolvimento de uma plataforma experimental para pesquisas em dinâmica, controle e navegação de veículos submarinos. A plataforma experimental inclui: 1) um veículo submarino não tripulado semi-autônomo do tipo estrutura-aberta chamado de LAURS, 2) um sistema multissensorial e multipropulsores para o controle de movimento, e 3) software e arquitetura de controle para a aquisição de dados dos sensores e o controle de movimento. A fim de deduzir as equações do movimento dinâmico do LAURS, apresenta-se a formulação geral das equações hidrodinâmicas não lineares de um veículo submarino com seis graus de liberdade. A partir destas equações gerais acopladas, são deduzidos modelos mais simples para um grau de liberdade (movimento unidirecional) e três graus de liberdade (movimento planar) do veículo. O método de estimação de parâmetros utilizado neste trabalho não requer medidas de aceleração e é baseado na aplicação da técnica dos mínimos quadrados à forma integral das equações dinâmicas do sistema. O procedimento de identificação proposto é baseado na informação dos sensores embarcados. Primeiramente, os coeficientes de arrasto são obtidos a partir de testes de velocidade constante e depois, fixando os coeficientes de arrasto do modelo matemático com estes valores obtidos, são identificados a inércia virtual e os coeficientes de acoplamento a partir de testes de velocidade variável. Nos testes de velocidade variável são aplicadas entradas de força do tipo senoidal. Apresentam-se os valores dos coeficientes hidrodinâmicos para os movimentos de avanço, deriva, arfagem, guinada e caturro do veículo, os quais foram obtidos usando o procedimento de identificação proposto. O desempenho dos modelos dinâmicos identificados é quantitativamente comparado ao movimento do veículo observado experimentalmente. Para o caso dos testes de velocidade constante em avanço e arfagem, foi feita uma comparação dos valores dos coeficientes obtidos usando a abordagem de identificação de sistemas com os dados obtidos a partir dos ensaios de reboque em tanque de provas. Os resultados obtidos validam o procedimento de identificação proposto. Além disso, são apresentados os resultados experimentais obtidos a partir de manobras do tipo zig-zag e é feita uma discussão da identificabilidade de coeficientes de modelos acoplados. Conclui-se que o procedimento de identificação proposto é eficaz na obtenção de valores reais (consistentes com a concepção física do veículo) para os coeficientes hidrodinâmicos de veículos submarinos. A fim de modelar a força hidrodinâmica que atua no veículo em avanço com movimento oscilatório e amplitudes menores do que um comprimento característico, são apresentados os resultados dos ensaios de oscilação forçada usando um mecanismo de movimento planar (MMP). Apresentam-se os valores dos coeficientes de arrasto e de inércia obtidos a partir dos ensaios em avanço no MMP para diferentes números de Keulegan-Carpenter. Os resultados mostram que os coeficientes de arrasto e de inércia para a faixa de velocidades de 0,1 até 0,8m/s dependem fortemente do número de Keulegan-Carpenter e não do número de Reynolds. A partir destes resultados, conclui-se que a amplitude da oscilação do veículo é o principal fator que causa a variação dos coeficientes hidrodinâmicos e não a velocidade do veículo. / In this work, a procedure for experimental identification of hydrodynamic coefficients of unmanned underwater vehicles is presented. At first, the development of a testbed for research on dynamics, control, and navigation of underwater vehicles is presented. This experimental platform includes: 1) a open-frame semi-autonomous unmanned underwater vehicle named LAURS, 2) a multi-sensorial and multi-thruster system for motion control, and 3) software and control architecture for sensor data logging and motion control. In order to derive the LAURS dynamic motion equations, the general formulation of the nonlinear hydrodynamic equations of motion of an underwater vehicle with six degree of freedom is initially presented. From these general coupled equations, simpler formulations with one (unidirectional movement) and three degrees of freedom (planar movement) are derived. The parameter estimation method does not require acceleration measurements and is based on the application of the least squares technique to the integral form of the system dynamic equations. The identification procedure is based on on-board sensor data. First the drag coefficients are obtained from constant velocity tests and afterwards, fixing the drag coefficients in the mathematical model with the obtained values, virtual inertia and coupling coefficients of the vehicle are identified from variable velocity tests. In the tests of variable velocity, sinusoidal force inputs are applied. Values of hydrodynamic coefficients for surge, sway, heave, yaw, and pitch motions are estimated using the proposed identification procedure. Performance of the identified dynamic models is quantitatively compared to the experimentally observed vehicle motion. In the case of constant velocity tests, for the surge and heave motions, comparisons of the hydrodynamic drag coefficient values obtained using the system identification method with data obtained from towing tank tests are presented. Obtained results corroborate for the feasibility of the proposed identification method. Moreover, experimental results obtained from zig-zag maneuvers are presented and the identifiability of coupled dynamic models is discussed. It is possible to conclude that using the proposed method actual hydrodynamic parameters might be estimated. In order to model the hydrodynamic force that acts on the vehicle, in surge motion, with oscillatory movements and with amplitudes that are smaller than or equal to the characteristic length of the LAURS, results of forced oscillation tests in a planar motion mechanism (PMM) are presented. The drag and inertia coefficient values obtained from surge motion tests in the PMM for different Keulegan-Carpenter numbers are presented and discussed. Results illustrates that drag and inertia coefficients, when the vehicle velocity is in the range of 0,1 and 0,8m/s, do not strongly depend on the Reynolds number, however, they are strongly dependent on the Keulegan-Carpenter number. In this context, we can conclude that the oscillation amplitude is the main factor that causes the variation of hydrodynamic coefficients and not the vehicle velocity. Hydrodynamic modelling Identificação de parâmetros Modelagem hidrodinâmica Parameter identification Underwater vehicle Veículo submarino
29	Análise estrutural e de estabilidade do vaso de pressão de um AUV. / Structural and stability analysis of a pressure vessel of an AUV. Freitas, Artur Siqueira Nobrega de 26 June 2017 (has links) O planeta Terra tem aproximadamente três quartos submersos em água, ainda assim, estima-se que somente são conhecidos 5% dos mares e oceanos. Nas últimas décadas, os AUVs (Autonomous Underwater Vehicles) se converteram em uma ferramenta útil para a exploração dos oceanos por levar a bordo vários equipamentos com um relativo baixo custo de operação. A parte estrutural dos AUVs, usualmente cascas cilíndricas, tem sido estudada. De modo geral, os objetivos desses estudos visam a manter a rigidez e deixar a estrutura mais leve, sob o critério de resistência a flambagem. A falha por flambagem, normalmente, ocorre antes da falha por resistência do material em cascas devido à sua geometria e à influência de imperfeições iniciais. Uma forma de aumentar a rigidez das cascas é o uso de enrijecedores, os quais geralmente são soldados à casca. No entanto, o uso desses enrijecedores em um veículo de pequeno porte diminui o espaço utilizados por diferentes dispositivos e instrumentos do veículo, além de resultar em possíveis inconvenientes na fabricação, tais como aumento do custo e produção de tensões residuais relativas aos processos de soldagem. Portanto, alternativas ao enrijecedor convencional devem ser buscadas para esse tipo de veículo. É possível substituir os enrijecedores convencionais por uma estrutura interna ao vaso de pressão e comum em submersíveis, a prateleira de acomodação da eletrônica. Essa estrutura, chamada aqui de enrijecedores deslizantes, possui cavernas circunferenciais que podem fornecer rigidez à casca e evitar os inconvenientes de redução de volume e de fabricação que os enrijecedores convencionais trazem. No entanto, tal substituição para o aumento de rigidez ainda não foi analisada. Portanto, neste trabalho se propõe analisar o comportamento do enrijecedor deslizante quando utilizado em substituição ao enrijecedor convencional, considerando que ambos fornecem resistência à compressão embora não apresentem as mesmas restrições de graus de liberdade. A análise é feita através de métodos analíticos e numéricos, tipicamente utilizados no estudo de enrijecedores convencionais. / The planet Earth has about three quarters of water, yet it is estimated that only 5% of the seas and oceans are known. In the last decades, the AUVs have become useful tools for the exploration of the oceans by carrying on board several equipment with a relative low cost of operation. The structural part of the AUV\'s, usually cylindrical shells, has been studied as well. In general, the objectives of these studies are to maintain rigidity and to leave the structure lighter, under the criterion of buckling resistance. The buckling failure occurs prior to failure by yielding due to its geometry and the influence of initial shell imperfections. One way to increase the stiffness of the shells is to use stiffeners, which are usually welded to the shell. However, the use of these stiffeners in a small vehicle reduces the space used for different devices and instruments of the vehicle, in addition there are manufacturing drawbacks as residual stresses related to the welding processes. Therefore, alternatives to the conventional stiffener should be sought for this type of vehicle. It is possible to replace conventional stiffeners by an internal structure to the pressure vessel and common in submersibles, the shelf of accommodation of the electronics. This structure, referred to here as sliding stiffeners, has circumferential frame bulkheads that can provide stiffness to the shell and avoid the drawbacks of volume reduction and fabrication that conventional stiffeners bring. However, such substitution for increased rigidity has not yet been analyzed. Therefore, in this work it is proposed to analyze the behavior of the sliding stiffeners when used in substitution of the conventional stiffeners, considering that both provide compressive strength although they do not present the same restrictions of degrees of freedom. The analysis is done by analytical and numerical methods, typical of conventional stiffeners. Buckling Estabilidade estrutural External pressure vessel Flambagem Submersíveis não tripulados Unmanned underwater vehicle Vasos de pressão
30	Controle robusto multivariável para um veículo submersível autônomo. / Multivariable robust control for an autonomous underwater vehicle. Cutipa Luque, Juan Carlos 02 March 2007 (has links) Este trabalho trata do controle dos movimentos de um Veículo Submersível Autônomo (VSA). Veículos submersíveis são difíceis de controlar devido à alta não linearidade de seus modelos, ao forte acoplamento de movimentos, ao desconhecimento de certas dinâmicas, às incertezas do próprio modelo, devido a distúrbios externos impostos pelo ambiente e devido ao ruído de sensores. A dificuldade de controle pode ser exacerbada quando o veículo é subatuado. Para realização deste trabalho foi escolhido um VSA do tipo torpedo, cujo modelo matemático disponível na literatura foi devidamente modificado para garantir uma melhor descrição de seus movimentos em seis graus de liberdade (6-GL). O modelo foi então validado através de simulações numéricas. Para a síntese dos controladores utilizou-se uma técnica de controle avançada. Mais especificamente, utilizou-se a abordagem do controle H1 para sistemas multivariáveis. Assim foram obtidos controladores centralizados capazes de superar o problema do forte acoplamento de movimentos. Técnicas de controle avançado permitem também considerar as informações disponíveis sobre perturbações, incertezas, ruídos e diferentes tipos de entrada já na fase de síntese, o que permite obter controladores com desempenho adequado numa ampla faixa de operação. Neste trabalho, em particular, a técnica da Sensibilidade Mista foi escolhida para a síntese de controladores robustos. Nesta abordagem, formatam-se algumas funções de malha fechada ligadas a sensibilidade do sistema buscando garantir estabilidade e desempenho robusto para o sistema controlado. Usando a mesma técnica de controle desenvolveu-se ainda um controlador de dois graus de liberdade (2-GL), apropriado para aplicação no problema de guiagem, onde procura-se seguir trajetórias tridimensionais. Os controladores desenvolvidos foram testados em simulações numéricas, produzindo-se uma grande quantidade de resultados. A análise destes resultados revela o poder e flexibilidade das técnicas escolhidas. / This work focuses the motion control of an Autonomous Underwater Vehicle (AUV). Underwater vehicles are difficult to control due to high non-linearities of its model, coupling between dynamics, unknown dynamics, model uncertainties, disturbances and sensor noises. Difficulty is greater, when the system is subactuated. In this work, a mathematical model of a torpedo-like AUV available in the bibliography was chosen and refined, leading to a six degree of freedom (6-DOF) model. The model was further analyzed and validated by a number of numerical simulations. Advanced approaches were used for the synthesis of controllers. Speciffically, a H1 approach for multivariable systems was used. Thus, a centralized controller was developed, able to avoid the problem of high coupling between the variables. This advanced approach is also able to use informations about perturbations, uncertainties, noises and different types of input signals in the synthesis stage, leading to controllers with better performance in a large operation bandwidth. In this work, a Mixed Sensitivity approach was employed. This control approach is based on the shapping of well known closed-loop sensitivity functions, seeking to achieve stability and performance robustness. Using a similar technique, a controller with two degree of freedom (2-DOF) was also synthesised, to tackle the guidance problem tracking of 3-D trajectories was then fully achieved. The controllers developed were tested in a number of numerical simulations. Analyses of results reveals the power and flexibility of the employed techniques. Autonomous underwater vehicle Control systems Controle ótimo Optimal control Sistemas de controle Veículos submersíveis não tripulados

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