1,058 research outputs found
Mobility Evaluation of Wheeled Robots on Soft Terrain: Effect of Internal Force Distribution
[Abstract]
Many applications of wheeled robots include operations in unstructured environments. Optimizing vehicle mobility is of key importance in these cases. Reduced mobility can limit the ability of the robot to achieve the mission goals and can even render it immobile in extreme cases. In this paper, some aspects of the effect of the wheel–ground interaction force distribution on mobility are investigated. A performance index based on the normal force distribution is used to compare different design layouts and vehicle configurations. The validity of this index was assessed using both multibody dynamics simulation and experimental results obtained with a six-wheeled rover prototype. Results confirmed that modifying the system configuration and employing active suspensions to alter the normal force distribution can lead to an increase of traction force available at the wheel–terrain interfaces, thus improving rover mobility. Finally, the study was extended to consider the change of soil properties during operation due to the multipass effect. Optimum load distributions were obtained as the solution of a constrained maximization problem.MINECO; JCI-2012-1237
Slip Modelling, Estimation and Control of Omnidirectional Wheeled Mobile Robots with Powered Caster Wheels
Ph.DDOCTOR OF PHILOSOPH
A novel concept for analysis and performance evaluation of wheeled rovers
[Abstract] - The analysis, design, and operation planning of rovers are often based on predictive dynamic simulation, where the multibody model of the vehicle is combined with terramechanics relations for the representation of the wheel–ground interaction. There are, however, limitations in terramechanics models that prevent their use in parametric analysis and simulation studies. Increasing mobility is generally a primary objective for the design and operation of rovers. The models and assumptions used in the analysis phase should target this objective. In this paper we put forward a new concept for the analysis of wheeled rovers, particularly for applications in off-road environments on soft soil. We propose a novel view of the problem based on the development of models that are primarily intended to represent how parameter changes in the robot design can influence performance. These models allow for the definition of indicators, which gives information about the behavior of the system. We term such models observative. In the reported work, a set of indicators for rover performance is formulated using such models. The ability of these indicators to characterize the behavior of a rover is assessed with a series of simulation tests and experiments. The indicators defined using observative models succeeded to capture the changes in rover performance due to variations in the system parameters. Results show that the proposed models can provide a useful tool for the design and operation of planetary exploration rovers
In Depth Analysis of Power Balance, Handling, and the Traction Subsystem of an Articulated Skid-Steering Robot for Sustainable Agricultural Monitoring
This paper reports on the energy balance test performed on Agri.Q, an eight-wheel articulated robot intended to be a sustainable monitoring tool within the precision agriculture paradigm, and proposes an in-depth analysis of the traction subsystem in order to develop an appropriate traction allocation strategy to improve navigation through hilly or mountainous crops. Tests were conducted on the contribution of the orientable photovoltaic panel to the mission duration and overall sustainability, showing that a suitable mission plan, including dedicated charging phases, could significantly increase the robot’s operating time. A series of simulations of circular trajectories of different curvature and at different longitudinal velocities on flat ground were performed, with the aim of mapping the robot’s behaviour at steady state. The results of the simulations were analysed, paying particular attention to the required torques, manoeuvrability and forces exchanged on the ground. The simulations conducted demonstrated and extended previous results obtained on similar robotic architectures, which suffer from significant understeer behaviour due to significant lateral wheel slip during turning. They also showed the limitations of currently employed traction motors, but also the advantages of a proper traction allocation strategy involving the rear module.
Article highlights.
Agri.Q energy balance tests have been carried out to assess its endurance and sustainability
The traction and handling behaviours of Agri.Q were mapped and discussed in detail in order to improve them
Agri.Q has proven to be a basis for the future implementation of precision agriculture to advance the SDG
Climbing and Walking Robots
With the advancement of technology, new exciting approaches enable us to render mobile robotic systems more versatile, robust and cost-efficient. Some researchers combine climbing and walking techniques with a modular approach, a reconfigurable approach, or a swarm approach to realize novel prototypes as flexible mobile robotic platforms featuring all necessary locomotion capabilities. The purpose of this book is to provide an overview of the latest wide-range achievements in climbing and walking robotic technology to researchers, scientists, and engineers throughout the world. Different aspects including control simulation, locomotion realization, methodology, and system integration are presented from the scientific and from the technical point of view. This book consists of two main parts, one dealing with walking robots, the second with climbing robots. The content is also grouped by theoretical research and applicative realization. Every chapter offers a considerable amount of interesting and useful information
Wheel torque control for a rough terrain rover
Navigating in rough terrain is a complex task that requires the robot to be considered as a holistic system. Algorithms, which don’t consider the physical dimensions and capabilities of the mobile robot lead to inefficient motion and suffer from a lack of robustness. A physical model of the robot is necessary for trajectory control. In this paper, quasi-static modeling of a six-wheeled robot with a passive suspension mechanism is presented together with a method for selecting the optimal torques considering the system constraints: maximal and minimal torques, positive normal forces. The aim of this method is to limit wheel slip and to improve climbing capabilities. The modeling and the optimization are applied to the Shrimp rover
Methods for the improvement of power resource prediction and residual range estimation for offroad unmanned ground vehicles
Unmanned Ground Vehicles (UGVs) are becoming more widespread in their
deployment. Advances in technology have improved not only their reliability but also
their ability to perform complex tasks. UGVs are particularly attractive for operations
that are considered unsuitable for human operatives. These include dangerous
operations such as explosive ordnance disarmament, as well as situations where
human access is limited including planetary exploration or search and rescue missions
involving physically small spaces. As technology advances, UGVs are gaining increased
capabilities and consummate increased complexity, allowing them to participate in
increasingly wide range of scenarios.
UGVs have limited power reserves that can restrict a UGV’s mission duration and also
the range of capabilities that it can deploy. As UGVs tend towards increased
capabilities and complexity, extra burden is placed on the already stretched power
resources. Electric drives and an increasing array of processors, sensors and effectors,
all need sufficient power to operate. Accurate prediction of mission power
requirements is therefore of utmost importance, especially in safety critical scenarios
where the UGV must complete an atomic task or risk the creation of an unsafe
environment due to failure caused by depleted power.
Live energy prediction for vehicles that traverse typical road surfaces is a wellresearched
topic. However, this is not sufficient for modern UGVs as they are required
to traverse a wide variety of terrains that may change considerably with prevailing
environmental conditions. This thesis addresses the gap by presenting a novel
approach to both off and on-line energy prediction that considers the effects of
weather conditions on a wide variety of terrains. The prediction is based upon nonlinear
polynomial regression using live sensor data to improve upon the accuracy
provided by current methods.
The new approach is evaluated and compared to existing algorithms using a custom
‘UGV mission power’ simulation tool. The tool allows the user to test the accuracy of
various mission energy prediction algorithms over a specified mission routes that
include a variety of terrains and prevailing weather conditions. A series of experiments that test and record the ‘real world’ power use of a typical
small electric drive UGV are also performed. The tests are conducted for a variety of
terrains and weather conditions and the empirical results are used to validate the
results of the simulation tool.
The new algorithm showed a significant improvement compared with current
methods, which will allow for UGVs deployed in real world scenarios where they must
contend with a variety of terrains and changeable weather conditions to make
accurate energy use predictions. This enables more capabilities to be deployed with a
known impact on remaining mission power requirement, more efficient mission
durations through avoiding the need to maintain excessive estimated power reserves
and increased safety through reduced risk of aborting atomic operations in safety
critical scenarios.
As supplementary contribution, this work created a power resource usage and
prediction test bed UGV and resulting data-sets as well as a novel simulation tool for
UGV mission energy prediction. The tool implements a UGV model with accurate
power use characteristics, confirmed by an empirical test series. The tool can be used
to test a wide variety of scenarios and power prediction algorithms and could be used
for the development of further mission energy prediction technology or be used as a
mission energy planning tool
Support polygon in the hybrid legged-wheeled CENTAURO robot: modelling and control
Search for the robot capable to perform well in the real-world has sparked an interest in the hybrid locomotion systems. The hybrid legged-wheeled robots combine the advantages of the standard legged and wheeled platforms by switching between the quick and efficient wheeled motion on the flat grounds and the more versatile legged mobility on the unstructured terrains. With the locomotion flexibility offered by the hybrid mobility and appropriate control tools, these systems have high potential to excel in practical applications adapting effectively to real-world during locomanipuation operations. In contrary to their standard well-studied counterparts, kinematics of this newer type of robotic platforms has not been fully understood yet. This gap may lead to unexpected results when the standard locomotion methods are applied to hybrid legged-wheeled robots. To better understand mobility of the hybrid legged-wheeled robots, the model that describes the support polygon of a general hybrid legged-wheeled robot as a function of the wheel angular velocities without assumptions on the robot kinematics or wheel camber angle is proposed and analysed in this thesis. Based on the analysis of the developed support polygon model, a robust omnidirectional driving scheme has been designed. A continuous wheel motion is resolved through the Inverse Kinematics (IK) scheme, which generates robot motion compliant with the Non-Sliding Pure-Rolling (NSPR) condition. A higher-level scheme resolving a steering motion to comply with the non-holonomic constraint and to tackle the structural singularity is proposed. To improve the robot performance in presence to the unpredicted circumstances, the IK scheme has been enhanced with the introduction of a new reactive support polygon adaptation task. To this end, a novel quadratic programming task has been designed to push the system Support Polygon Vertices (SPVs) away from the robot Centre of Mass (CoM), while respecting the leg workspace limits. The proposed task has been expressed through the developed SPV model to account for the hardware limits. The omnidirectional driving and reactive control schemes have been verified in the simulation and hardware experiments. To that end, the simulator for the CENTAURO robot that models the actuation dynamics and the software framework for the locomotion research have been developed
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