Development of an Underwater Vehicle Simulation Platform

Du, Jiun-Hua

15 November 2011

In the development of underwater vehicles, it is necessary to conduct performance test in the water tank. However, different factors need to be considered depending on different cases. The purpose of this paper is to construct a simulation platform in the air to study the scenarios like side current or constant height profiling. Although these tests are difficult to be performed in the water tank, we can get some solutions from observing the dynamics of simulation platform. The simulation platform we used consists of three links to constraint the motion in a polar coordinate system. It carries a wireless micro-camera, and two DC motor-driven propellers. At the end of the distal link and metal disk is attached on the other side of the pivot of the last link to provide counter-weight which can simulate different status of the "buoyancy" of the platform. The encoder which is uses to trace the motion of the simulation platform, is mounted at each join between two links. The control program has two parts: servo control of propellers and target tracking. In order to approach to the real-time searching, we derived image with gray scale instead of color form to increase image refreshing rate during the tracking process. For the current experiment, the target is at dot generated by an LED. The location of the bright dot is detected by a histogram-based threshold, and the actual location is further refined with intensity-weighted algorithm. The offset between of the target and the center of the image is used as the feedback to command the propellers to drive the platform. The goal is to keep the target at the center of the image as close as possible. A linear PD control (proportional - derivative) is implemented to drive the propellers. Preliminary experiments show that the simulation platform can track a target with about 15 frames per second refreshing rate under the condition that the target does not move too fast and vanishes in the image. When ROV with laser scanner syetem, seafloor away from ROV's accuracy is necessary. In this eassay, we use tracking angle and tracking bright dot to qualify and quantify the influence of buoyancy and propeller on the altitude control in different cases.

Underwater vehicle

altitude control

propeller

PD controller

Design of Mission Controller for Autonomous Underwater Vehicle

Lin, Yu-Ren

04 December 2012

The different between Remotely Operated Vehicle (ROV) and Autonomous Underwater Vehicle (AUV) is that ROV is connected with the main computer by the electronic cable, so the operator can control the vehicle depending on the environment showing on the monitor; However, AUV is dependent on the received data to autonomously respond the condition via controlling program. In our research, we wanted to use the General Purpose Controller, which had been developed in the previous experiment, in the mission-mode to construct our AUV system for remaining the original ROV controlling system and switching mode between AUV system and ROV system. The mission was divided into primary and secondary mission written by the txt file which is known as mission script, including execute time, target, and mission type etc. In addition, we used the Watch Dog Timer (WDT) in our AUV for the security procedure. When the mission is failed or over the setting time, the AUV will change to the security mode and go forward to the water surface. The other topic in this research wanted to use the Seafloor Laser Scanner (SLS), which was mounted on the AUV, to improve the scanning efficiency. However, when the scanner was working, the AUV had to maintain the stable altitude to the sea floor, so the accurately output power of thruster is needed to be considered and tested. In this part, we found out the properly controlling way in the small water tank first, and then checked the attitude and scanning system in the swimmer pool and towing tank in NCKU respectively, to prove the ability of SLS of AUV system.

Seafloor Laser Scanner

Altitude Control

Mission Mode

Controller

AUV

Aerial Sensing Platform for Greenhouses

Raj, Aditya

January 2021

No description available.

Agricultural Engineering

Controle de atitude e altitude para um ve?culo a?reo n?o tripulado do tipo quadrirrotor

Guimar?es, Jo?o Paulo Ferreira

19 December 2012

Made available in DSpace on 2014-12-17T14:55:09Z (GMT). No. of bitstreams: 1 JoaoPFG_DISSERT.pdf: 1458535 bytes, checksum: fae41c0cfc4b0b09e65c1f69ec230a28 (MD5) Previous issue date: 2012-12-19 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior / A Quadrotor is an Unmanned Aerial Vehicle (UAV) equipped with four rotors distributed on a simple mechanical "X"form structure. The aim of this work is to build and stabilize a Quadrotor aircraft in the roll, pitch and yaw angles at a certain altitude. The stabilization control approach is based on a transformation in the input variables in order to perform a decoupled control. The proposed strategy is based on breaking the control problem into two hierarchical levels: A lower level, object of this work, maintains the desired altitude an angles of the vehicle while the higher level establishes appropriate references to the lower level, performing the desired movements. A hardware and software architecture was specially developed and implemented for an experimental prototype used to test and validate the proposed control approach / Um Quadrirrotor ? um Ve?culo A?reo N?o Tripulado (VANT) dotado de quatro rotores distribu?dos nas extremidades de uma estrutura mec?nica simples em forma de "X". O objetivo desse trabalho ? construir e estabilizar uma aeronave desse tipo, com alta capacidade de carga, em uma determinada altitude, sob ?ngulos de rolagem, guinada e arfagem pr?-definidos. A abordagem de controle de estabiliza??o baseia-se numa transforma??o das vari?veis de entrada do sistema a fim de realizar o controle de forma desacoplada. A estrat?gia proposta se baseia na divis?o do problema de controle em dois n?veis hier?rquicos: o n?vel inferior, objeto deste trabalho, mant?m os ?ngulos e a altitude do ve?culo em valores desejados, enquanto o n?vel superior estabelece refer?ncias adequadas para o n?vel inferior, de forma a executar os movimentos desejados Uma arquitetura de hardware e software foi especialmente desenvolvida e implementada para um prot?tipo experimental usado para testar e validar a abordagem de controle proposta

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

Aplikace geodetických metod sběru dat při zaměřování polohopisných a výškopisných prvků krjiny v povodí Jenína. / Application of geodetic methods for data collection by surveying of situation and higth elements of the landscape.

KREJČÍKOVÁ, Zuzana

January 2010

The topic of this Dissertation is ``Application of geodetic methods of data collection to horizontal and vertical surveys of elements of the landscape in the Jenín water catchment area{\crqq}. Its aim was to make a detailed horizontal as well as vertical surveys of the site in question. The survey was carried out with the use of the tachymetric method. The coordinates of the points were specified in the S-JTSK system and in the Bpv altitude system. The entire site features a surface area of approximately 40 hectares. At first the reconnaissance of the terrain and of the existing point array was carried out in the entire area, the site was subsequently subjected to a detailed survey. The measurements were carried out with the use of the Leica TCR 407 power total station. The data was processed in the Groma, Atlas and MicroStation software. The result of the present Dissertation is the original document of the map at a scale of 1:1000.

Gps Based Altitude Control Of An Unmanned Air Vehicle Using Digital Terrain Elevation Data

Atac, Selcuk

01 June 2006

In this thesis, an unmanned air vehicle (UAV) is used to develop a prototype base test platform for flight testing of new control algorithms and avionics for advanced UAV system development applications. A control system that holds the UAV at a fixed altitude above the ground is designed and flight tested. Only the longitudinal motion of the UAV is considered during the controller design, hence its lateral motions are controlled manually by a remote control unit from the ground. UAV&amp / #8217 / s altitude with respect to the mean sea level and position are obtained by an onboard global positioning system (GPS) and this information is transmitted to the ground computer via radio frequency (RF) communication modules. The altitude of the UAV above the ground is calculated by using the digital terrain elevation data (DTED). A controller is designed and its gains are tuned to maintain this flight altitude at a desired value by using the mathematical model developed to represent the longitudinal dynamics of the UAV. Input signals generated by the controller for elevator deflections are transmitted back to the UAV via RF communication modules to drive onboard servomotors to generate desired elevator deflections. All controller computations and RF communications are handled by a MATLAB&reg / based platform on a ground computer. UAV flight tests are carried out at two different autopilot modes / namely, mean sea level (MSL) altitude hold mode and above ground level (AGL) altitude hold mode. The developed platform worked properly during flight tests and proved to be reliable in almost every condition. Moreover, the designed controller system is demonstrated to be effective and it fulfills the requirements.

Adaptive Quaternion Control for a Miniature Tailsitter UAV

Knoebel, Nathan B.

30 August 2007

The miniature tailsitter is a unique aircraft with inherent advantages over typical unmanned aerial vehicles. With the capabilities of both hover and level flight, these small, portable systems can produce efficient maneuvers for enhanced surveillance and autonomy with little threat to surroundings and the system itself. Such vehicles are accompanied with control challenges due to the two different flight regimes. Problems with the conventional attitude representation arise in estimation and control as the system departs from level flight conditions. Furthermore, changing dynamics and limitations in modeling and sensing give rise to significant attitude control design challenges. Restrictions in computation also result from the limited size and weight capacity of the miniature airframe. In this research, the inherent control challenges discussed above are addressed with a computationally efficient adaptive quaternion control algorithm. A backstepping method for model cancellation and consistent tracking of reference model attitude dynamics is derived. This is used in conjunction with two different algorithms designed for the identification of system parameters. For a metric of baseline performance, gain-scheduled quaternion feedback control is developed. With a regularized data-weighting recursive least-squares parameter estimation algorithm, the adaptive quaternion controller is shown to be better than the baseline method in simulation and hardware results. This method is also shown to produce universal performance for all aircraft with the three conventional control surface actuators (aileron, elevator, and rudder) barring saturation and assuming accurate system identification. Testing of attitude control algorithms requires development in quaternion-based navigational control and attitude estimation. A novel technique for hover north/east position control is derived. Also, altitude tracking in hover, given an inconsistent thrust system, is addressed with an original method of on-line throttle system identification. Means for quaternion-based level flight control are produced from adaptations made to existing techniques employed in the Brigham Young University Multi-Agent Coordination and Control Lab. Also generated are simple trajectories for transitions between flight modes. A method for the estimation of quaternion attitude is developed, which uses multiple sensors combined in a filtering technique similar to the fixed-gain Kalman filter. Simulation and hardware results of these methods are presented for concept validation. A discussion of the development and production of these testing means (a simulation environment and hardware flight test system) is provided. In culmination, a fully autonomous miniature tailsitter system is produced with results demonstrating its various capabilities.

tailsitter

autopilot

adaptive quaternion control

quaternion estimation

quaternion navigation

UAV

MAV

tailsitter simulation

tailsitter autopilot design

tailsitter adaptive control

quaternion backstepping control

least-squares parameter estimation

tailsitter adaptive altitude control

tailsitter path following

tailsitter transition maneuvers

tailsitter position control

Mechanical Engineering