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Design and realization of odometry sensors for mobile robot with Ackermann steering
Porteš, Petr ; Věchet, Stanislav (referee) ; Hrbáček, Jan (advisor)
Aim of this thesis is to design and construct odometric sensors for a mobile robot with Ackermann steering Bender 2 and to design a mathematical model which would evaluate the the trajectory of the robot using measured data of these sensors. The first part summarizes theoretical knowledge, while the second, the practical part, describes the design of the front axle, the design and the operating software of the front encoders and the odometric models. The last part deals with the processing and evaluation of the measured data.
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Robotic Vehicle Using RC Components
Deingruber, Ondřej ; Beran, Vítězslav (referee) ; Zemčík, Pavel (advisor)
This thesis covers the topic of controlling RC servos and constructions of robotic vehicles. The goal is to propose a model of robotic vehicle with RC components and other off the shelf components, 3D printing and demonstrate its capabilities. In the thesis, a mobile robot platform was proposed. It uses a single-board computer together with readily available parts and does not require complicated assembly. An optimization algorithm was used for the design of rack and pinion steering. The result of the thesis is the implementation of a robotic vehicle.
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The front axle of the three-wheel hobby vehicle
Mlynár, Adam ; Brandejs, Jan (referee) ; Mazůrek, Ivan (advisor)
This bachelor's thesis deals with design of front double wishbone suspension adaptable to reverse trike vehicle. The first chapter is devoted to the overview of three-wheel vehicles, the basic geometrical parameters of the axles and the introduction of the modified vehicle. The next chapter contains a suggestion of suitable geometry and kinematics of the axle and is inspected in program Lotus Suspension Analysis. The conclusion is devoted to conceptual design and structural design in program SolidWorks 2016. A suitable stiffness of the suspension is also proposed, and the factor of safety of the arms and the steering knuckle is checked by finite element analysis.
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Controlling of Robot with Ackermann Steering
Fryč, Martin ; Žák, Marek (referee) ; Rozman, Jaroslav (advisor)
In this paper is described creation of a robot in Robot Operating system (ROS) withAckermann steering. It contains the principle of Ackermann steering geometry, search ofcontroller boards and basics of ROS structure. A RC car with connected PixHawk controlleris used as a basis of the robot. On the robot is placed an onboard computer Raspberry Pi3 with running ROS. This computer is connected to a laptop through Wi-Fi network. Theprocedure of starting up the robot and ROS is also described in this paper, as well asdesign of the graphical user interface (GUI) that will display sensory data and allow otherfunctionality. Another part of thesis explains principle of an optical encoder and how tocreate your own encoder which can detect rotation of a wheel. This is used to implementrobot odometry. The structure of ROS navigation library is analyzed with regards to itscommissioning. Implementation of the GUI and navigation library will follow in the masterthesis.
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Robotic Vehicle Using RC Components
Deingruber, Ondřej ; Beran, Vítězslav (referee) ; Zemčík, Pavel (advisor)
This thesis covers the topic of controlling RC servos and constructions of robotic vehicles. The goal is to propose a model of robotic vehicle with RC components and other off the shelf components, 3D printing and demonstrate its capabilities. In the thesis, a mobile robot platform was proposed. It uses a single-board computer together with readily available parts and does not require complicated assembly. An optimization algorithm was used for the design of rack and pinion steering. The result of the thesis is the implementation of a robotic vehicle.
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The front axle of the three-wheel hobby vehicle
Mlynár, Adam ; Brandejs, Jan (referee) ; Mazůrek, Ivan (advisor)
This bachelor's thesis deals with design of front double wishbone suspension adaptable to reverse trike vehicle. The first chapter is devoted to the overview of three-wheel vehicles, the basic geometrical parameters of the axles and the introduction of the modified vehicle. The next chapter contains a suggestion of suitable geometry and kinematics of the axle and is inspected in program Lotus Suspension Analysis. The conclusion is devoted to conceptual design and structural design in program SolidWorks 2016. A suitable stiffness of the suspension is also proposed, and the factor of safety of the arms and the steering knuckle is checked by finite element analysis.
|
|
|
Controlling of Robot with Ackermann Steering
Fryč, Martin ; Žák, Marek (referee) ; Rozman, Jaroslav (advisor)
In this paper is described creation of a robot in Robot Operating system (ROS) withAckermann steering. It contains the principle of Ackermann steering geometry, search ofcontroller boards and basics of ROS structure. A RC car with connected PixHawk controlleris used as a basis of the robot. On the robot is placed an onboard computer Raspberry Pi3 with running ROS. This computer is connected to a laptop through Wi-Fi network. Theprocedure of starting up the robot and ROS is also described in this paper, as well asdesign of the graphical user interface (GUI) that will display sensory data and allow otherfunctionality. Another part of thesis explains principle of an optical encoder and how tocreate your own encoder which can detect rotation of a wheel. This is used to implementrobot odometry. The structure of ROS navigation library is analyzed with regards to itscommissioning. Implementation of the GUI and navigation library will follow in the masterthesis.
|
|
|
Design and realization of odometry sensors for mobile robot with Ackermann steering
Porteš, Petr ; Věchet, Stanislav (referee) ; Hrbáček, Jan (advisor)
Aim of this thesis is to design and construct odometric sensors for a mobile robot with Ackermann steering Bender 2 and to design a mathematical model which would evaluate the the trajectory of the robot using measured data of these sensors. The first part summarizes theoretical knowledge, while the second, the practical part, describes the design of the front axle, the design and the operating software of the front encoders and the odometric models. The last part deals with the processing and evaluation of the measured data.
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