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Quadrokopter sind Helikopter mit vier in einer Ebene angeordneten Rotoren. Kleine unbemannte Modelle, die oft nur eine Schubkraft von wenigen Newton erzeugen können, sind im Spielzeug- und Modellbaubereich beliebt, werden aber auch von Militär und Polizei als Drohne für Aufklärungs- und Überwachungsaufgaben eingesetzt. Diese Diplomarbeit befasst sich mit den theoretischen Grundlagen der Steuerung eines Quadrokopters und entwickelt darauf aufbauend eine kostengünstige Steuerplatine für einen Modellquadrokopter.
Die theoretischen Grundlagen enthalten eine Untersuchung der Dynamik eines frei fliegenden Quadrokopters, bei der Bewegungsgleichungen hergeleitet und mit den Ergebnissen verglichen werden, die in "Design and control of quadrotors with application to autonomous flying" ([Bou07]) vorgestellt wurden. Weiterhin wird die Funktionsweise verschiedener Sensoren beschrieben, die zur Bestimmung der aktuellen räumlichen Ausrichtung geeignet sind, und es werden Verfahren besprochen, mit denen die Ausrichtung aus den Messwerten dieser Sensoren abgeschätzt werden kann. Zusätzlich wird in den Schiefkörper der Quaternionen eingeführt, in dem dreidimensionale Rotationen kompakt dargestellt und effizient verkettet werden können.
Daran anschließend wird die Entwicklung einer einfachen Steuerplatine beschrieben, die sowohl einen autonomen Schwebeflug als auch Fernsteuerung ermöglicht. Die Platine wurde auf einem X-Ufo-Quadrokopter der Firma Silverlit entwickelt und getestet, der daher ebenfalls vorgestellt wird. Die eingesetzten Bauteile und deren Zusammenspiel werden besprochen. Dabei ist insbesondere die WiiMotionPlus hervorzuheben, die als kostengünstiges Gyrosensormodul verwendet wird. Daneben werden verschiedene Aspekte der Steuersoftware erläutert: die Auswertung der Sensordaten, die Zustandsschätzung mit Hilfe des expliziten komplementären Filters nach Mahony et al. ([MHP08]), die Umsetzung des Ausrichtungsreglers sowie die Erzeugung der Steuersignale für die Motoren. Sowohl die Steuersoftware als auch Schaltplan und Platinenlayout der Steuerplatine liegen dieser Arbeit auf einer CD bei. Schaltplan und Platinenlayout sind zusätzlich im Anhang der Arbeit abgedruckt.
Particle swarm optimization is an optimization technique based on simulation of the social behavior of swarms.
The goal of this thesis is to solve 6DOF local pose estimation using a modified particle swarm technique introduced by Khan et al. in 2010. Local pose estimation is achieved by using continuous depth and color data from a RGB-D sensor. Datasets are aquired from different camera poses and registered into a common model. Accuracy and computation time of the implementation is compared to state of the art algorithms and evaluated in different configurations.
3D-Curve-Skeletons are often used, because the object surface repesentation is less complex and also needs less computing power in further processing, compared to the representation created by the Medial Axis Transformation introduced 1967 by Harry Blum.
This theses aims at developing a 3D curve skelton approximation algorithm that keeps these advantages and is also able to handle different scenarios of the object surface input data.
The purpose of this master thesis is to enable the Robot Lisa to process complex commands and extract the necessary information in order to perform a complex task as a sequence of smaller tasks. This is intended to be achieved by the improvement of the understanding that Lisa has of her environment by adding semantics to the maps that she builds. The complex command itself will be expected to be already parsed. Therefore the way the input is processed to become a parsed command is out of the scope of this work. Maps that Lisa builds will be improved by the addition of semantic annotations that can include any kind of information that might be useful for the performance of generic tasks. This can include (but not necessarily limited to) hierarchical classifications of locations, objects and surfaces. The processing of the command in addition to some information of the environment shall trigger the performance of a sequence of actions. These actions are expected to be included in Lisa- currently implemented tasks and will rely on the currently existing modules that perform them.
Nevertheless the aim of this work is not only to be able to use currently implemented tasks in a more complex sequence of actions but also make it easier to add new tasks to the complex commands that Lisa can perform.
Autonomous systems such as robots already are part of our daily life. In contrast to these machines, humans an react appropriately to their counterparts. People can hear and interpret human speech, and interpret facial expressions of other people.
This thesis presents a system for automatic facial expression recognition with emotion mapping. The system is image-based and employs feature-based feature extraction. This thesis analyzes the common steps of an emotion recognition system and presents state-of-the-art methods. The approach presented is based on 2D features. These features are detected in the face. No neutral face is needed as reference. The system extracts two types of facial parameters. The first type consists of distances between the feature points. The second type comprises angles between lines connecting the feature points. Both types of parameters are implemented and tested. The parameters which provide the best results for expression recognition are used to compare the system with state-of-the-art approaches. A multiclass Support Vector Machine classifies the parameters.
The results are codes of Action Units of the Facial Action Coding System. These codes are mapped to a facial emotion. This thesis addresses the six basic emotions (happy, surprised, sad, fearful, angry, and disgusted) plus the neutral facial expression. The system presented is implemented in C++ and is provided with an interface to the Robot Operating System (ROS).
The purpose of this bachelor- thesis is to teach Lisa - a robot of the university of Koblenz- AGAS department developed for participation in the @home league of the RoboCup - to draw. This requires the expansion of the robbie software framework and the operation of the robot- hardware components. Under consideration of a possible entry in the Open Challenge of the @home RoboCup, the goals are to detect a sheet of paper using Lisa- visual sensor, a Microsoft Kinect and draw on it using her Neuronics Katana robot arm. In addition, a pen mounting for the arm- gripper has to be constructed.
Outlined within this thesis are the procedures utilized to convert an image template into movement of the robotic arm, which in turn leads to drawing of a painting by the pen attached to the arm on a piece of paper detected by the visual sensor through image processing. Achieved were the parsing and drawing of an object made up of an indefinite amount of straight lines from a SVG-file onto a white sheet of paper, detected on a slightly darker surface and surrounded by various background objects or textures.
Pedestrian Detection in digital images is a task of huge importance for the development of automaticsystems and in improving the interaction of computer systems with their environment. The challenges such a system has to overcome are the high variance of the pedestrians to be recognized and the unstructured environment. For this thesis, a complete system for pedestrian detection was implemented according to a state of the art technique. A novel insight about precomputing the Color Self-Similarity accelerates the computations by a factor of four. The complete detection system is described and evaluated, and was published under an open source license.
The goal of this Bachelor thesis was programming an existig six-legged robot, which should be able to explore any environment and create a map of it autonomous. A laser scanner is to be integrated for cognition of this environment. To build the map and locate the robot a suitable SLAM(Simultaneous Localization and Mapping) technique will be connected to the sensor data. The map is reported to be the robots base of path planning and obstancle avoiding, what will be developed in the scope of the bachelor thesis, too. Therefore both GMapping and Hector SLAM will be implemented and tested.
An exploration algorithm is described in this bachelor thesis for exploring the robots environment. The implementation on the robot takes place in the space of ROS(Robot Operating System) framework on a "Raspberry Pi" miniature PC.