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Návrh autonomní robotické kolové platformy
LARVA, Jaroslav
The diploma thesis represents the project of design and implementation of an autonomous robotic platform, which is built on the basis of a modified children's buggy, enabling its remote control. The entire project is systematically divided into two basic parts: theoretical and practical. In the theoretical part, the components and software tools used during the project are analyzed in detail. This section provides an overview of current trends in robotics and autonomous systems and highlights the importance of each selected element to the success of the overall design. In the practical part, the work focuses on the development process itself. From the first steps in construction, through the programming of the purchased platform, to a detailed description of the connection and integration of electronic components. Specific attention is paid to technical solutions that overcome the challenges associated with adapting a children's buggy to an autonomous robotic platform. In the final part, the project is evaluated as a whole. It includes an analysis of the achieved results, reflection on possible areas of improvement and discussion of future directions of development.
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Control Unit for Autonomous Vacuum Cleaner
Matějů, Jan ; Kopečný, Lukáš (referee) ; Žalud, Luděk (advisor)
This paper is in introduction focused on review of robotic vacuum cleaning and evaluation of available products qualities. However the main focus of this paper is system design of all subsystems, control systems and PCD design of robot electronics. In this paper is also described a method for evaluating approximate distance of robot from the obstacle. There are also described problems of system design of IR proximity sensors. The last part of this work is development of control software for robot and its testing.
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Visual Navigation of the Vehicle
Jaššo, Kamil ; Richter, Miloslav (referee) ; Horák, Karel (advisor)
The thesis consists of retrieval of known solutions of autonomous vehicle navigation. Thesis further describes options for controling autonomous vehicle, and using of sensors in autonomous vehicles. From different types of sensors are selected two types, that are most suitable for visual navigation of the vehicle. Thesis describes the function and way of using these two types of sensors in the visual navigation of the vehicle. The program for obtaining and saving data from selected sensors is also part of the thesis.
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Docking Station for Automatic Charging of Batteries of Robot
Beran, Jan ; Janoušek, Vladimír (referee) ; Rozman, Jaroslav (advisor)
The aim of this thesis is to create a functional docking and charging system for the Trilobot robot, which is improved and modified for use in future projects as a part of this thesis. The theoretical part discusses the path planning methods, battery types and charging methods, types of docking stations and the charging method itself. Also, a robot refurbishment design is presented, which is then implemented, along with the docking station. The refurbished robot has functional control software in the ROS framework, which allows it to perform not only the task of autonomous battery charging. In this thesis, a test of the whole system is also performed and the results are evaluated.
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Control software for autonomous mobile robot
Vojta, Jakub ; Marada, Tomáš (referee) ; Věchet, Stanislav (advisor)
Bachelor thesis focuses on software development for mobile autonomous robot with a microcontroller control unit. It provides an overview to sensors for mobile ground robots on a level necessary for control software programmer. It further analyzes microcontrollers and their architecture and programming. At the end of the thesis is theoretical description of deployed navigational software and communication protocol between control unit and computer.
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Control of underwater exploring robot
Válek, Zdeněk ; Hadaš, Zdeněk (referee) ; Houška, Pavel (advisor)
This diploma thesis is dealing with design of explorative robot named Gloin, which is designed especially for the exploration and mapping of the underwater part of Hranická propast, which is the second deepest fresh-water abbys in the world. This thesis is concentrating on design of algorithms needed for control and navigation of robot in the abyss. The designed algorithms are verified by simulation.
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Unconventional Signals Oscillators
Hruboš, Zdeněk ; Galajda, Pavol (referee) ; Štork, Milan (referee) ; Petržela, Jiří (advisor)
Dizertační práce se zabývá elektronicky nastavitelnými oscilátory, studiem nelineárních vlastností spojených s použitými aktivními prvky a posouzením možnosti vzniku chaotického signálu v harmonických oscilátorech. Jednotlivé příklady vzniku podivných atraktorů jsou detailně diskutovány. V doktorské práci je dále prezentováno modelování reálných fyzikálních a biologických systémů vykazujících chaotické chování pomocí analogových elektronických obvodů a moderních aktivních prvků (OTA, MO-OTA, CCII ±, DVCC ±, atd.), včetně experimentálního ověření navržených struktur. Další část práce se zabývá možnostmi v oblasti analogově – digitální syntézy nelineárních dynamických systémů, studiem změny matematických modelů a odpovídajícím řešením. Na závěr je uvedena analýza vlivu a dopadu parazitních vlastností aktivních prvků z hlediska kvalitativních změn v globálním dynamickém chování jednotlivých systémů s možností zániku chaosu v důsledku parazitních vlastností použitých aktivních prvků.
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System for Autonomous Navigation of Toy Car on a Race Track
Katrušák, Jaroslav ; Bidlo, Michal (referee) ; Šimek, Václav (advisor)
The goal of this project is the implementation of a system for autonomous control of a toy car model on a racetrack. First part of this project is a study of typical ways of laying out a racetrack for the movement of a model car and a follow-up study of possible ways of implementing the autonomous movement of the model on the racetrack. The next part is devoted to the hardware and software side of the implementation of the proposed system. The penultimate part presents the proposed system for obstacle detection, it's implementation and resulting properties. The last part of the project presents the final implementation of an autonomous model capable of independent driving on a set racetrack, reading signs and reaction to obstacle located on the track.
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Telepresence Autonomous Robot for Exploration of Unapproachable Areas
Krkavec, Martin ; Janoušek, Vladimír (referee) ; Rozman, Jaroslav (advisor)
The subject of this master's thesis was to get familiar with a robot developed at the Department of Intelligent Systems of FIT VUT Brno. The goal of this work was to design and then implement hardware and software improvements of the robot so it could be capable of telepresence exploration of a narrow cave using remote control, including autonomous return back to the entrance. Also suggest possible extensions for a further improvement of the robot.
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Floating Robot KAMBoat II
Beneš, Jiří ; Žalud, Luděk (referee) ; Kopečný, Lukáš (advisor)
Objective of this thesis is to design and create second generation of KAMboat type robotic ship. Main tasks are to test abilities and performance of the ship alone and in comparison with the previous model. This thesis is divided into subparts which compare the differences between the two prototypes. First chapter focuses on analyzing selected parts of ship’s physical model, especially the hydrodynamics, which is then used to define construction limits. Following chapters KAMboat 1 and Construction analysis describe the first version of ship and reasons of making new version. Chapter KAMboat 2 refines the theoretical knowledge gained in previous chapter into tangible form. Chapter Electronics describes selected electronic equipment of the ship and mounted circuitry. The Control chapter is focused on combining theoretical and practical aspects of driving a small BLDC engine. Controls and Communications chapter describes how to secure and maintain data flow between operator and the robot. Chapter Missions is selection of tasks that are supported on KAMboat 2 type robotic ship.
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