568 research outputs found
A path planning and path-following control framework for a general 2-trailer with a car-like tractor
Maneuvering a general 2-trailer with a car-like tractor in backward motion is
a task that requires significant skill to master and is unarguably one of the
most complicated tasks a truck driver has to perform. This paper presents a
path planning and path-following control solution that can be used to
automatically plan and execute difficult parking and obstacle avoidance
maneuvers by combining backward and forward motion. A lattice-based path
planning framework is developed in order to generate kinematically feasible and
collision-free paths and a path-following controller is designed to stabilize
the lateral and angular path-following error states during path execution. To
estimate the vehicle state needed for control, a nonlinear observer is
developed which only utilizes information from sensors that are mounted on the
car-like tractor, making the system independent of additional trailer sensors.
The proposed path planning and path-following control framework is implemented
on a full-scale test vehicle and results from simulations and real-world
experiments are presented.Comment: Preprin
Anti-Jackknifing Control of Tractor-Trailer Vehicles via Intrinsically Stable MPC
It is common knowledge that tractor-trailer vehicles are affected by jackknifing, a phenomenon that consists in the divergence of the trailer hitch angle and ultimately causes the vehicle to fold up. For the case of backwards motion, in which jackknifing can also occur at low speeds, we present a control method that drives the vehicle along a reference Cartesian trajectory while avoiding the divergence of the hitch angle. In particular, a feedback control law is obtained by combining two actions: a tracking term, computed using input-output linearization, and a corrective term, generated via IS-MPC, an intrinsically stable MPC scheme which is effective for stable inversion of nonminimum-phase systems. The proposed method has been verified in simulation and experimentally validated on a purposely built prototype
Comparison of Modern Controls and Reinforcement Learning for Robust Control of Autonomously Backing Up Tractor-Trailers to Loading Docks
Two controller performances are assessed for generalization in the path following task of autonomously backing up a tractor-trailer. Starting from random locations and orientations, paths are generated to loading docks with arbitrary pose using Dubins Curves. The combination vehicles can be varied in wheelbase, hitch length, weight distributions, and tire cornering stiffness. The closed form calculation of the gains for the Linear Quadratic Regulator (LQR) rely heavily on having an accurate model of the plant. However, real-world applications cannot expect to have an updated model for each new trailer. Finding alternative robust controllers when the trailer model is changed was the motivation of this research.
Reinforcement learning, with neural networks as their function approximators, can allow for generalized control from its learned experience that is characterized by a scalar reward value. The Linear Quadratic Regulator and the Deep Deterministic Policy Gradient (DDPG) are compared for robust control when the trailer is changed. This investigation quantifies the capabilities and limitations of both controllers in simulation using a kinematic model. The controllers are evaluated for generalization by altering the kinematic model trailer wheelbase, hitch length, and velocity from the nominal case.
In order to close the gap from simulation and reality, the control methods are also assessed with sensor noise and various controller frequencies. The root mean squared and maximum errors from the path are used as metrics, including the number of times the controllers cause the vehicle to jackknife or reach the goal. Considering the runs where the LQR did not cause the trailer to jackknife, the LQR tended to have slightly better precision. DDPG, however, controlled the trailer successfully on the paths where the LQR jackknifed. Reinforcement learning was found to sacrifice a short term reward, such as precision, to maximize the future expected reward like reaching the loading dock. The reinforcement learning agent learned a policy that imposed nonlinear constraints such that it never jackknifed, even when it wasn\u27t the trailer it trained on
The Effect of Sideslip on Jackknife Limits During Low Speed Trailer Operation
Jackknifing refers to the serious situation where a vehicle-trailer system
enters a jackknife state and the vehicle and trailer eventually collide if
trailer operation is not corrected. This paper considers low speed trailer
maneuvering typical of trailer backing where jackknife state limits can vary
due to sideslip caused by physical interaction between the vehicle, trailer,
and environment. Analysis of a kinematic model considering sideslip at the
vehicle and trailer wheels indicates that vehicle-trailer systems should be
divided into three categories based on the ratio of hitch length and trailer
tongue length, each with distinct behaviors. The Long Trailer category may have
no jackknifing state while the other two categories always have states leading
to jackknifing. It is found that jackknife limits, which are the boundaries
between the jackknifing state and the recoverable regions, can be divided into
safe and unsafe limits, the latter of which must be avoided. Simulations and
physical experiments support these results and provide insight about the
implications of vehicle and trailer states with slip that lead to jackknifing.
Simulations also demonstrate the benefit of considering these new slip-based
jackknife limits in trailer backing control
Control of autonomous multibody vehicles using artificial intelligence
The field of autonomous driving has been evolving rapidly within the last few years and
a lot of research has been dedicated towards the control of autonomous vehicles, especially
car-like ones. Due to the recent successes of artificial intelligence techniques, even
more complex problems can be solved, such as the control of autonomous multibody vehicles.
Multibody vehicles can accomplish transportation tasks in a faster and cheaper way
compared to multiple individual mobile vehicles or robots.
But even for a human, driving a truck-trailer is a challenging task. This is because of the
complex structure of the vehicle and the maneuvers that it has to perform, such as reverse
parking to a loading dock. In addition, the detailed technical solution for an autonomous
truck is challenging and even though many single-domain solutions are available, e.g. for
pathplanning, no holistic framework exists. Also, from the control point of view, designing
such a controller is a high complexity problem, which makes it a widely used benchmark.
In this thesis, a concept for a plurality of tasks is presented. In contrast to most of the existing
literature, a holistic approach is developed which combines many stand-alone systems
to one entire framework. The framework consists of a plurality of modules, such as modeling,
pathplanning, training for neural networks, controlling, jack-knife avoidance, direction
switching, simulation, visualization and testing. There are model-based and model-free
control approaches and the system comprises various pathplanning methods and target
types. It also accounts for noisy sensors and the simulation of whole environments.
To achieve superior performance, several modules had to be developed, redesigned and
interlinked with each other. A pathplanning module with multiple available methods optimizes
the desired position by also providing an efficient implementation for trajectory following.
Classical approaches, such as optimal control (LQR) and model predictive control
(MPC) can safely control a truck with a given model. Machine learning based approaches,
such as deep reinforcement learning, are designed, implemented, trained and tested successfully.
Furthermore, the switching of the driving direction is enabled by continuous
analysis of a cost function to avoid collisions and improve driving behavior.
This thesis introduces a working system of all integrated modules. The system proposed
can complete complex scenarios, including situations with buildings and partial trajectories.
In thousands of simulations, the system using the LQR controller or the reinforcement
learning agent had a success rate of >95 % in steering a truck with one trailer, even with
added noise. For the development of autonomous vehicles, the implementation of AI at
scale is important. This is why a digital twin of the truck-trailer is used to simulate the full
system at a much higher speed than one can collect data in real life.Tesi
Transportation Mission-Based Optimization of Heavy Combination Road Vehicles and Distributed Propulsion, Including Predictive Energy and Motion Control
This thesis proposes methodologies to improve heavy vehicle design by reducing the total cost of ownership and by increasing energy efficiency and safety.Environmental issues, consumers expectations and the growing demand for freight transport have created a competitive environment in providing better transportation solutions. In this thesis, it is proposed that freight vehicles can be designed in a more cost- and energy-efficient manner if they are customized for narrow ranges of operational domains and transportation use-cases. For this purpose, optimization-based methods were applied to minimize the total cost of ownership and to deliver customized vehicles with tailored propulsion components that best fit the given transportation missions and operational environment. Optimization-based design of the vehicle components was found to be effective due to the simultaneous consideration of the optimization of the transportation mission infrastructure, including charging stations, loading-unloading, routing and fleet composition and size, especially in case of electrified propulsion. Implementing integrated vehicle hardware-transportation optimization could reduce the total cost of ownership by up to 35% in the case of battery electric heavy vehicles. Furthermore, in this thesis, the impacts of two future technological advancements, i.e., heavy vehicle electrification and automation, on road freight transport were discussed. It was shown that automation helps the adoption of battery electric heavy vehicles in freight transport. Moreover, the optimizations and simulations produced a large quantity of data that can help users to select the best vehicle in terms of the size, propulsion system, and driving system for a given transportation assignment. The results of the optimizations revealed that battery electric and hybrid heavy combination vehicles exhibit the lowest total cost of ownership in certain transportation scenarios. In these vehicles, propulsion can be distributed over different axles of different units, thus the front units may be pushed by the rear units. Therefore, online optimal energy management strategies were proposed in this thesis to optimally control the vehicle motion and propulsion in terms of the minimum energy usage and lateral stability. These involved detailed multitrailer vehicle modeling and the design and solution of nonlinear optimal control problems
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