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Dynamics of four-wheeled mobile robots on uneven surface applicationsAyalew, Assefa January 2001 (has links)
No description available.
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Traction Control for KTH Formula StudentCollin, Felix January 2020 (has links)
When accelerating, traction from the tyres is necessary to move the vehicle forward. If too much torque is applied to the wheels of the vehicle, the tyres will start to spin and thereby the traction will decrease. This can occur when the driver of the vehicle applies to much throttle, but can be controlled with a traction control system that prevent the tyres from spinning and keeps the tyres at maximum traction to increase acceleration. In Formula Student competitions, every tenths of a second gained is vital and a traction control could help the driver to find these tenths of a second during acceleration. The purpose of this bachelor thesis was to design a slip ratio based traction control for the KTH Formula Student car DeV17 with focus on the acceleration event from standing start. A problem with standing start is the launch of the acceleration which were investigated along with a PID-controller. The model was developed in MATLAB's SIMULINK and simulated with IPG CarMaker. Small improvements in acceleration time were seen with the PID-controller but the launch did not see any improvements.
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Powertrain modelling and control algorithms for traction controlZetterqvist, Carin January 2007 (has links)
<p>För att ett fordon ska kunna bromsa, accelerera och svänga är friktion mellan däcken och vägen ett måste. Vid för mycket gaspådrag under en acceleration kan det hända att hjulen förlorar fäste och börjar spinna loss, något som leder till både försämrad kontroll över fordonet och att däcken slits ut i förtid. Traction controlsystemet förhindrar hjulen från att spinna loss och försöker maximera friktionen.</p><p>Målet med detta examensarbete är att utvärdera olika reglerprinciper samt att undersöka olika möjligheter för att reglera friktionen mellan däck och väg. Det är ett svårt reglerproblem, dels på grund av dess olinjäritet, dels på grund av det faktum att friktionen är en okänd parameter.</p><p>För att kunna undersöka olika reglermöjligheter har en modell över hjuldynamiken och en modell över drivlinan tagits fram i Matlabs simuleringsprogram Simulink. Därutöver har tre regulatorer designats: en fuzzy-regulator, en fuzzy-P-regulator och en PI-regulator. Regulatorerna utvärderades i tre tester som bland annat testade deras robusthet.</p><p>Fuzzy-regulatorn och fuzzy-P-regulatorn lyckades reglera systemet bra. PI-regulatorn gjorde däremot inte ett tillfredsställande jobb, mest på grund av dess behov av ett börvärde.</p> / <p>Traction is necessary for a vehicle to be able to brake, accelerate and turn. When pushing the accelerator pedal too hard during an acceleration, the wheel can loose traction and start spinning, which leads to a worsen vehicle control and also wears out the tyres faster. The traction control system prevents the wheels from spinning and tries to make the tyres maintain maximum traction.</p><p>The purpose of this master’s thesis is to evaluate different control methods and to investigate possible ways to control the traction. This is a difficult control problem due to its nonlinearity and the fact that the friction is an unknown parameter.</p><p>For the investigation, a model of the wheel dynamics and a model of the powertrain have been developed in Matlab’s simulation program Simulink. Furthermore, three different controllers have been designed; a fuzzy controller, a fuzzy-P controller and a PI controller. The controllers were evaluated in three test cycles that among others tested their robustness.</p><p>The fuzzy controller and the fuzzy-P controller managed to control the system very well. The PI controller, however, did not work satisfactory, mainly because of its need of a desired value.</p>
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Control system integration in ADAMS : With emphasis on hauler Automatic Traction Control systemFurmanik, Olga, Famili, Alireza January 2015 (has links)
The thesis investigates control system integration in ADAMS and the thesis presents appropriate knowledge related to the topic as multi body system, acting forces between road and wheels, equation of motion regarding to the haulers, traction control system and differential locks. The emphasis of the thesis is to implement and test the automatic traction control (ATC) for the hauler into ADAMS and Simulink models. The ATC models are based on certain requirements provided by Volvo Construction Equipment. As expected, results indicate that the ATC model operates during simulation for various road conditions. Nevertheless, the ATC model includes a few defects which are observed in results. The significant achievement of the thesis is a great collaboration between ADAMS and Simulink model.
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Powertrain modelling and control algorithms for traction controlZetterqvist, Carin January 2007 (has links)
För att ett fordon ska kunna bromsa, accelerera och svänga är friktion mellan däcken och vägen ett måste. Vid för mycket gaspådrag under en acceleration kan det hända att hjulen förlorar fäste och börjar spinna loss, något som leder till både försämrad kontroll över fordonet och att däcken slits ut i förtid. Traction controlsystemet förhindrar hjulen från att spinna loss och försöker maximera friktionen. Målet med detta examensarbete är att utvärdera olika reglerprinciper samt att undersöka olika möjligheter för att reglera friktionen mellan däck och väg. Det är ett svårt reglerproblem, dels på grund av dess olinjäritet, dels på grund av det faktum att friktionen är en okänd parameter. För att kunna undersöka olika reglermöjligheter har en modell över hjuldynamiken och en modell över drivlinan tagits fram i Matlabs simuleringsprogram Simulink. Därutöver har tre regulatorer designats: en fuzzy-regulator, en fuzzy-P-regulator och en PI-regulator. Regulatorerna utvärderades i tre tester som bland annat testade deras robusthet. Fuzzy-regulatorn och fuzzy-P-regulatorn lyckades reglera systemet bra. PI-regulatorn gjorde däremot inte ett tillfredsställande jobb, mest på grund av dess behov av ett börvärde. / Traction is necessary for a vehicle to be able to brake, accelerate and turn. When pushing the accelerator pedal too hard during an acceleration, the wheel can loose traction and start spinning, which leads to a worsen vehicle control and also wears out the tyres faster. The traction control system prevents the wheels from spinning and tries to make the tyres maintain maximum traction. The purpose of this master’s thesis is to evaluate different control methods and to investigate possible ways to control the traction. This is a difficult control problem due to its nonlinearity and the fact that the friction is an unknown parameter. For the investigation, a model of the wheel dynamics and a model of the powertrain have been developed in Matlab’s simulation program Simulink. Furthermore, three different controllers have been designed; a fuzzy controller, a fuzzy-P controller and a PI controller. The controllers were evaluated in three test cycles that among others tested their robustness. The fuzzy controller and the fuzzy-P controller managed to control the system very well. The PI controller, however, did not work satisfactory, mainly because of its need of a desired value.
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Traction control of an electric vehicle with four in-wheel motorsHajihosseinlu, Amin January 2015 (has links)
This thesis evaluates an electric vehicle with four independently-controlled in-wheel
electric motors. The electric vehicle investigated in this work requires a main con-
troller that not only coordinates with each individual motor drive controller, but is
also needed to distribute torque and power to each in-wheel motor. The controller
adjusts the speed of each motor to the driving conditions according to the require-
ments and emulates the behavior of a mechanical di erential. Then, in addition to
the electronic di erential controller, a simple yet robust control strategy for maximiz-
ing traction force between tire and road is developed and presented. Moreover, the
controller continuously senses the yaw rate and prevents over- and under-steering by
adjusting the torque on the right or left wheels. Simulation and experimental results
validate the proposed strategy.
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Adaptive Traction, Torque, and Power Control Strategies for Extended-Range Electric VehiclesBenoy, Brian Patrick 11 August 2012 (has links)
Modern hybrid electric and pure electric vehicles are highly dependent on control algorithms to provide seamless safe and reliable operation under any driving condition, regardless of driver behavior. Three unique and independently operating supervisory control algorithms are introduced to improve reliability and vehicle performance on a series-hybrid electric vehicle with an all-wheel drive all-electric drivetrain. All three algorithms dynamically control or limit the amount of torque that can be delivered to the wheels through an all-electric drivetrain, consisting of two independently controlled brushless-direct current (BLDC) electric machines. Each algorithm was developed and validated following a standard iterative engineering development process which places a heavy emphasis on modeling and simulation to validate the algorithms before they are tested on the physical system. A comparison of simulated and in-vehicle test results is presented, emphasizing the importance of modeling and simulation in the design process.
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Development of a Traction Control System for a Parallel-Series PHEVHyde, Amanda N. 01 August 2014 (has links)
No description available.
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[en] TRACTION CONTROL TO MOBILE ROBOTIC SYSTEMS IN ROUGH TERRAIN / [pt] MODELAGEM DE SISTEMAS ROBÓTICOS MÓVEIS PARA CONTROLE DE TRAÇÃO EM TERRENOS ACIDENTADOSALEXANDRE FRANCISCO BARRAL SILVA 13 December 2007 (has links)
[pt] Em terrenos acidentados é crítico para robôs móveis manter
uma adequada
tração nas rodas, pois um excessivo deslizamento das
mesmas pode fazer o robô
capotar ou desviar da rota desejada. Também, se uma força
excessiva é aplicada
sobre uma região do terreno, pode levar o mesmo a ceder
deixando as rodas
presas. Para se evitar os problemas acima citados e ainda
otimizar o consumo de
energia em terrenos planos, a presente dissertação
desenvolveu um controle de
tração para terrenos acidentados com o intuito de aplicá-
lo ao Robô Ambiental
Híbrido (RAH) da Petrobrás. O RAH é um robô móvel anfíbio
que está em fase
de desenvolvimento no Laboratório de Robótica do CENPES
(Petrobras), que
poderá ser comandado por um operador ou se deslocar
autonomamente. Esse robô
faz parte do projeto Cognitus, braço tecnológico do
projeto Piatam (Potenciais
Impactos e Riscos Ambientais da Indústria de Óleo e Gás na
Amazônia), e será
aplicado na monitoração e coleta de dados do meio ambiente
de dois gasodutos da
Petrobrás na região Amazônica, o gasoduto Urucu (AM)-
Porto Velho (RO) e o
gasoduto Coari (AM) - Manaus (AM). A técnica de controle
de tração de veículos
robóticos em terrenos acidentados desenvolvida visa
controlar a velocidade ao
mesmo tempo em que garante a estabilidade dinâmica, não
deslizamento das
rodas, evita a saturação dos motores, e em certas
condições ainda permite
minimizar a potência requerida através do conhecimento dos
ângulos de contato
entre as rodas e o terreno. Foram feitas duas modelagens
independentes, uma
considerando a suspensão do robô flexível e a outra
considerando o veículo
robótico como um corpo rígido, sendo ambas para o caso
plano (2D).Foram
realizadas simulações em terrenos suaves e acidentados, as
quais comprovaram a
eficácia das técnicas de controle propostas. / [en] Abstract
Silva, Alexandre F. Barral Silva; Meggiolaro, Marco
Antonio. Traction
Control to Mobile Robotic Systems in Rough Terrain. Rio de
Janeiro,
2004. 194 p. MSc. Thesis - Departamento de Engenharia
Mecânica,
Pontifícia Universidade Católica do Rio de Janeiro.
In rough terrain it is critical for mobile robots to
maintain adequate wheel
traction, because excessive sliding could cause the robot
to roll over or deviate
from its intended path. Also, if an excessive force is
applied onto the terrain, the
soil may fail and trap the robot wheels. To avoid these
problems, and also
minimize the power consumption on even terrain, the
present work develops a
rough terrain traction control to be applied to the Hybrid
Environmental Robot
(HER) from Petrobras. The HER is an amphibious mobile
robot developed by the
Robotics Laboratory from CENPES (Petrobras). It can be
commanded by an
operator or autonomously. This robot is part of the
Cognitus Project,
technological branch of the Piatam project (Potential
Impacts and Environmental
Risks of the Oil and Gas Industry in the Amazon). It will
be used for monitoring
and environmental data collecting along two gas pipelines
in the Amazon region,
the Urucu (AM) - Porto Velho (RO) and the Coari (AM) -
Manaus (AM). The
developed traction control of robotic vehicles in rough
terrain aims to control the
speed at the same time that it guarantees dynamic
stability, no slip of the wheels,
prevents motor saturation, and under certain conditions it
may also allow for the
minimization of the required power. This control needs the
knowledge of the
current state of the robot, including the contact angles
between its wheels and the
terrain. Two independent 2D models have been proposed, one
including the
suspension compliance and one considering the robotic
vehicle as a rigid body.
Simulations have been performed in even and rough
terrains, proving the
effectiveness of the proposed control techniques.
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The Drawbar Pull Test Performance and Scalability of a Collaborative Multi-Robot Traction Control SystemBrandstaetter, Jackson Eli 15 September 2022 (has links)
No description available.
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