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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
221

Optimal Coordination of Chassis Systems for Vehicle Motion Control / Coordination Optimale des Systèmes Châssis pour le Contrôle du Mouvement des Voitures

Kissai, Moad 17 June 2019 (has links)
Le contrôle global du châssis a fait récemment l'objet d'une attention particulière. Cela serait motivé surtout par l’approche des véhicules entièrement autonomes. Ces véhicules, en particulier le niveau 5 d’automatisation SAE (J3016), devraient remplacer le conducteur humain dans presque toutes les situations. Le véhicule automatisé devrait être capable de gérer en harmonie des situations couplées où sont intégrés le contrôle longitudinal, latéral et éventuellement vertical. Pour ce faire, le véhicule dispose de plusieurs systèmes intégrés par axe de contrôle. En effet, les équipementiers automobiles et les nouveaux acteurs de l'industrie automobile proposent continuellement de nouvelles solutions pour satisfaire des performances bien spécifiques. Le constructeur automobile doit quant à lui coordonner différents sous-systèmes provenant de différentes parties prenantes afin de garantir une expérience de conduite fiable et confortable. Jusqu'à présent, les constructeurs automobiles privilégiaient des solutions simples consistant à ajouter une couche de coordination en aval des sous-systèmes concurrents afin de limiter les potentiels conflits. La plupart des stratégies adoptées consistent à prioriser un système par rapport à un autre en fonction de certains scénarios conflictuels prévisibles. Les véhicules autonomes ont besoin de sous-systèmes supplémentaires pour fonctionner en toute sécurité. Ainsi, les interactions entre les sous-systèmes s'amplifieront au point de devenir imprévisibles. Cette thèse met l'accent sur l'approche de coordination qui devrait être adoptée par les véhicules du futur. En particulier, la couche de coordination est déplacée en amont des sous-systèmes autonomes pour assurer une distribution de commande optimale. Cette couche agit comme un superviseur basé sur des algorithmes d'allocation optimale du contrôle. La synthèse des correcteurs repose sur les théories du contrôle robuste permettant de faire face aux changements environnementaux et aux incertitudes paramétriques et dynamiques du véhicule. Les résultats ont d’abord montré que même en ce qui concerne les véhicules actuels, l’approche en amont peut offrir des avantages supplémentaires pour ce qui est de la résolution de problèmes à objectifs multiples. En outre, l’approche en amont permet de coordonner les sous-systèmes des véhicules présentant une sur-actionnement plus élevé. La tolérance aux pannes peut être assurée entre des systèmes de châssis complètement différents, et des objectifs qualitatifs, s'ils sont rigoureusement formalisés, peuvent être satisfaits. Plus les sous-systèmes seront nombreux à l'avenir, plus l'approche en amont deviendrait pertinente pour le contrôle du mouvement des véhicules. Nous espérons que les avantages conséquents présentés dans cette thèse grâce à une approche de coordination en amont optimale encourageraient les constructeurs automobiles et leurs équipementiers à opter pour des solutions plus ouvertes, à proposer ensemble les normalisations nécessaires et accélérer ainsi le développement des véhicules autonomes. / A large interest has been given recently to global chassis control. One of the main reasons for this would be the approach of fully autonomous vehicles. These vehicles, especially the SAE (J3016) level 5 of automation, are expected to replace the human driver in all situations. The automated vehicle should be able to manage coupled situations in harmony where longitudinal control, lateral control, and eventually vertical control are involved. To do so, the vehicle has more than one embedded system per control axis. Equipment suppliers and new entering automotive actors are continually proposing new solutions to satisfy a specific performance required from future passenger cars. Consequently, the car manufacturer has to coordinate different subsystems coming from different stakeholders to ensure a safe and comfortable driving experience. Until these days, car manufactures favoured simple solutions consisting on adding a coordination layer downstream the competing subsystems in order to mitigate eventual conflicts. Most of strategies adopted consist on prioritizing one system over another depending on predictable conflicting scenarios. Autonomous vehicles need additional subsystems to operate safely. Interactions between these subsystems will increase to the point of becoming unpredictable. This thesis focus on the coordination approach that should be adopted by future vehicles. Particularly, the coordination layer is moved upstream the standalone subsystems to ensure an optimal control distribution. This layer acts as a supervisor depending on optimization-based control allocation algorithms. The control synthesis is based on robust control theories to face environmental changes and the vehicle’s parameters and dynamics uncertainties. Results showed first that even regarding today’s vehicles, the upstream approach can offer additional advantages when it comes to multiple objectives problems solving. In addition, the upstream approach is able to coordinate subsystems of vehicles with a higher over-actuation. Fault-tolerance can be ensured between completely different chassis systems, and qualitative objectives, if rigorously formalized, can be satisfied. The more numerous subsystems will get in the future, the more relevant the upstream approach would become to vehicle motion control. We expect that the important benefits shown in this thesis thanks to an optimal upstream coordination approach would encourage car manufacturers and equipment to switch towards more open solutions, propose together the necessary standardizations, and accelerate the autonomous vehicles development.
222

Analytické metody v motorsportu / Analytical Methods in Motorsport

Růžička, Bronislav January 2013 (has links)
This dissertation is focused on proposal for simplified data analyze approach for sport-car vehicle dynamic evaluation with relationship to possibility for qualified estimation of set-up parameters influence for overall vehicle performance. In common practice can be usual overlapping effect caused by concurrent changes of car setup elements if performed in the same moment with resulting in not correct or hardly definable process determination for evaluation and decision about next steps in car development. For analyze of these multidimensional data is then chosen process with approach by Linear Regression Model (LRM). In dissertation is proposed basic philosophy with concern on specificity of car vehicle dynamics, performed experiment with defined inputs including analyze and interpretation method of obtained outputs. This methodic take into account also possibility for general application of multidimensional data analyses not only in motorsport, but as well for dynamic behavior diagnostics of technical systems where finding of optimal running condition depends on multi-parametric setup whose combination must reflect often changes of outer conditions too.
223

Analysis of Torque Vectoring Systems through Tire and Vehicle Model Simulation

Chatfield, Christopher 08 August 2023 (has links)
No description available.
224

Integrated Estimation and Motion Control for Electric Vehicles

Yu, Zitian 08 October 2018 (has links)
No description available.
225

Investigation of active anti-roll bars and development of control algorithm

Agrawal, Harshit, Gustafsson, Jacob January 2017 (has links)
Active anti-roll bars have recently found greater acceptance among premium car manufacturers and optimal application of this technology has emerged as an important field of research. This thesis investigates the potential of implementing active anti-roll bars in a passenger vehicle with the purpose of increasing customer value. For active anti-roll bars, customer value is defined in terms of vehicle’s ride comfort and handling performance. The objective with this thesis is to demonstrate this value through development of a control algorithm that can reflect the potential improvement in ride comfort and handling. A vehicle with passive anti-roll bars is simulated for different manoeuvres to identify the potential and establish a reference for the development of a control algorithm and for the performance of active anti-roll bars. While ride is evaluated using single-sided cosine wave and single-sided ramps, handling is evaluated using standardized constant radius, frequency response and sine with dwell manoeuvres.The control strategy developed implements a combination of sliding mode control, feed forward and PI-controllers. Simulations with active anti-roll bars showed significant improvement in ride and handling performance in comparison to passive anti-roll bars. In ride comfort, the biggest benefit was seen in the ability to increase roll damping and isolating low frequency road excitations. For handling, most significant benefits are through the system’s ability of changing the understeer behaviour of the vehicle and improving the handling stability in transient manoeuvres. Improvement in the roll reduction capability during steady state cornering is also substantial. In conclusion, active anti-roll bars are undoubtedly capable of improving both ride comfort and handling performance of a vehicle. Although the trade-off between ride and handling performance is significantly less, balance in requirements is critical to utilise the full potential of active anti-roll bars. With a more comprehensive control strategy, they also enable the vehicle to exhibit different driving characteristics without the need for changing any additional hardware.
226

Limit Handling Vehicle Control for Improving Automated Vehicle Safety

Zhao, Tong January 2022 (has links)
No description available.
227

Multibody simulations of vibrations in a truck’s steering system / Flerkroppssimuleringar av vibrationer i en lastbils styrsystem

Didenbäck, Marcus January 2023 (has links)
This thesis aims to explore if multibody simulations is a suitable method to investigate vibrations in the steering system of trucks. Vibrations in the steering system and subsequently in the steering wheel is a common issue that automotive manufacturers face. The vibration levels in the steering wheel are in some countries regulated and some vibration phenomena can even cause issues with the handling properties of the whole vehicle. Therefore being able to predict and reduce these with the help of multibody simulations would be of great value. The thesis does this by comparing the simulations to measurements. It investigates what parts can be approximated as rigid, what the effects different numerical solvers have and compares different driving scenarios. This can however be quite challenging, one reason being that the differential equations arising when performing multibody simulations of trucks are very stiff. The numerical challenges of this must be overcome while still keeping the resolution of the accelerations in the solution high enough to still be representative of reality. The thesis also explains how to mathematically model a physical system such that the numerical analysis of it can be efficient. The results show that the success of multibody simulations is very dependent on the test case. However, they also show that together with physical measurements multibody simulations can be a powerful complementary tool. The thesis also presents improvements that could be made to the model as well as certain key areas that need to be studied more in order to align the multibody simulations results with measurements. The multibody simulations software used to perform the calculations and the modelling in the report is Adams developed by Hexagon AB. / Den här rapporten syftar till att ge inblick i om flerkroppssimuleringar kan vara ett användbart verktyg för att undersöka styrsystemsvibrationer i lastbilar. Dessa vibrationer är orsaken till en mängd styrningsproblem samt att rattvibrationer har lagkrav att inte vara för stora. Att kunna förutspå och efterlikna dessa vibrationer med flerkroppssimulering skulle därmed vara till stor fördel. Detta undersöks genom att jämföra simuleringarna med mätdata. Det undersöks vilken påverkan stelkroppsapproximationer av vissa komponenter har, påverkan av olika numeriska integrationmetoder samt steglängder och även olika körningslastfall. Att genomföra flerkroppssimuleringar av lastbilar är dock inte alltid helt enkelt, på grund av differentialekvationernas styva karaktär uppstår ofta konvergensproblem. Ska man sedan använda resultaten för att undersöka styrsystemsvibrationer måste man överkomma dessa konvergensproblem men bibehålla en tillräckligt fin upplösning av resultatet för att resultatet fortfarande ska vara representativt av den fysiska lastbilens dynamiska egenskaper. Rapporten beskriver även hur man kan gå tillväga för att matematiskt modellera ett fysisk system så att det effektivt går att utföra dynamisk analys av det. Resultaten visar att flerkroppssimulering kan vara väldigt beroende på vad körfallet är, med vissa körfall där simuleringar och mätningar stämmer väl överens och andra där detta inte är fallet. På grund av detta kan det vara otillräckligt att endast använda flerkroppssimulering för att utvärdera styrsystemsvibrationer, men resultaten visar att tillsammans med mätdata kan flerkroppssimulering vara ett kraftfullt komplement. I rapporten presenteras även exempel av viktiga komponenter att ta hänsyn till för att bättre kunna simulera styrsystemsvibrationer samt områden där mer forskning har potential att förbättra flerkroppssimuleringar i hänsyn till styrsystemsvibrationer. Mjukvaran som används för att utföra flerkroppssimulering är Adams som utvecklas av Hexagon AB.
228

Dynamic axel load estimation for an electrified vehicle : Normalkraftestimering på drivaxeln

Barakat, Majd January 2023 (has links)
The brake system is critical for ensuring safe driving and has been the focus of development for many years. Pneumatic braking technology is commonly used in heavy vehicles,but it results in energy wastage and high service costs. Some countries mandate auxiliarybraking systems to assist in stopping the vehicle in addition to service brakes. One suchsystem is the regenerative braking system, which captures kinetic energy from braking andconverts it into electrical energy. Retarders are another commonly used auxiliary brakingsystem. These systems are essential due to heavy vehicle weight, which can weaken servicebrake performance.This thesis focuses on estimating net forces on the truck’s driven axle to understandhow auxiliary braking systems and vehicle traction affect the normal force on the drivenwheel axle. The expected result can assist in maintaining the slip ratio and increasing thelife span and performance of brakes.Scania uses a function to estimate forces on the driven axle and drive wheel slip. Theyneed to determine the normal force on the axle to improve performance of auxiliary brakingsystems, but tests showed that for the same specified slip ratio, the auxiliary braking forcerequired was smaller than that in an acceleration state. Scania believe that dynamic axleload transfer may be the cause, so a 6x2 electrified truck will be investigated in this thesis.The obtained results show the driven wheel axle’s behavior during different dynamicalscenarios.This research aimed to develop a model that can accurately simulate a truck’s movement and estimate the ground reaction force in response to variations in the scenario of thecontrol signal. By studying the quarter car model, bounce-pitch and half car model, theresearchers were able to obtain a model represented by 5 ODEs, which predicts the wheelaxle normal force. To verify the model, data from the CAN bus and measurements using ascale were collected and compared with the model’s output. The Mean Squared Error canbe used to evaluate and compare the model’s performance, and the results showed that themodel provides a reasonable estimate of the normal force on all axles. The study also analyzed the factors that contributed to the errors in the results. The behavior of the normalforce for each wheel axle during acceleration and braking was illustrated, explaining howthe normal force distribution becomes mirrored compared to the acceleration state duringbraking. The study’s discussions enhance the validity of the observed behavior and thereliability of the results.
229

Modeling, Control and State Estimation of a Roll Simulator

Zagorski, Scott B. 17 December 2012 (has links)
No description available.
230

Autonomous Landing of an Unmanned Aerial Vehicle on an Unmanned Ground Vehicle using Model Predictive Control

Boström, Emil, Börjesson, Erik January 2022 (has links)
The research on autonomous vehicles, and more specifically cooperation between autonomous vehicles, has become a prominent research field during the last cou- ple of decades. One example is the combination of an unmanned aerial vehicle (UAV) together with an unmanned ground vehicle (UGV). The benefits of this are that the two vehicles complement each other, where the UAV provides an aerial view and can reach areas where a ground vehicle can not. Furthermore, since the UAV has a limited range, the UGV can then serve as transport and recharge sta- tion for the UAV. This master thesis studies how model predictive control (MPC) can be used to land a UAV on a moving UGV.  A linear MPC is chosen, since previous work using this has shown promising results. The UAV is chosen to be controlled using commands in pitch, roll and climbing rate. The MPC is designed as a decoupled controller, with a separate horizontal and vertical controller. This allows for a spatial constraint to be im- plemented, which constrains the UAV from entering ground level before arriving above the UGV. It also constrains the UAV from potentially hitting protruding ob- jects on the UGV. The horizontal controller uses a simple planner, which guides the UAV to land on the UGV from behind.  The MPC is evaluated using a additive white Gaussian noise (AWGN) sen- sor error model with zero mean. The scenario used is that the UAV starts 50 m from the UGV, and the UGV starts driving in a given direction turning randomly. The MPC lands successfully in 100 % of the simulations for a wide range of tun- ings. The MPC maintains the same landing statistics with a delay in the sensor information of up to 500 ms. The AWGN could be increased while maintaining successful landings, however with significantly more retakes and longer landing times. Lower AWGN variance only slightly improves performance, suggesting that the MPC is quite robust towards high variance in the state estimation.  The MPC is also compared to a PID controller. The MPC has significantly shorter landing times. The PID has a more oscillatory control signal, however, the PID has a lower variance in landing positions, but a slightly less centered mean on the UGV. The overall results show that an MPC can be used to achieve a flexible controller that can be tuned and reformulated to fit the situation, and performs as good or better compared to a PID controller.  The hardware tests show promising results for the implementation of the MPC. The controller is not tuned and no system identification is done specifi- cally for the physical UAV, suggesting that the controller is robust for varying settings. Even though the UAV never lands on the UGV, the visual behavior and control signal plots suggest that it would be able to land. However, these tests are performed using global navigation satellite system state estimation on a sta- tionary UGV, therefore further tests need to be performed in more challenging scenarios.

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