426 research outputs found
Navigation capabilities of mid-cost GNSS/INS vs. smartphone analysis and comparison in urban navigation scenarios
Proceedings of: 17th International Conference on Information Fusion (FUSION 2014): Salamanca, Spain 7-10 July 2014.High accuracy navigation usually require expensive sensors and/or its careful integration into a complex and finely tuned system. Smartphones pack a high number of sensors in a portable format, becoming a source of low-quality information with a high heterogeneity and redundancy. This work compares pure GNSS/INS capabilities on both types of platform, and discuss the weaknesses/opportunities offered by the smartphone. The analysis is carried out in a modular context-aware sensor fusion architecture developed for a previous work. It intends to serve as a preparation for answering bigger questions: can smartphones provide robust and high-quality navigation in vehicles? In which conditions? Where are the limits in the different navigation scenarios?This work was supported in part by Projects MINECO TEC2012-37832-C02-01, CICYT TEC2011-28626-C02-02, CAM CONTEXTS (S2009/TIC-1485)Publicad
On the vehicle sideslip angle estimation: a literature review of methods, models and innovations
Typical active safety systems controlling the dynamics of passenger cars rely on real-time monitoring of the vehicle sideslip angle (VSA), together with other signals like wheel angular velocities, steering angle, lateral acceleration, and the rate of rotation about the vertical axis, known as the yaw rate.
The VSA (aka attitude or “drifting” angle) is defined as the angle between the vehicle longitudinal axis and the direction of travel, taking the centre of gravity as a reference. It is basically a measure of the misalignment between vehicle orientation and trajectory therefore it is a vital piece of information enabling directional stability assessment, in transients following emergency manoeuvres for instance. As explained in the introduction the VSA is not measured directly for impracticality and it is estimated on the basis of available measurements like wheel velocities, linear and angular accelerations etc.
This work is intended to provide a comprehensive literature review on the VSA estimation problem. Two main estimation methods have been categorised, i.e. Observer-based and Neural Network-based, focusing on the most effective and innovative approaches. As the first method normally relies on a vehicle model, a review of the vehicle models has been included. Advantages and limitations of each technique have been highlighted and discussed
Developments in Estimation and Control for Cloud-Enabled Automotive Vehicles.
Cloud computing is revolutionizing access to distributed information and computing resources that can facilitate future data and computation intensive vehicular control functions and improve vehicle driving comfort and safety. This dissertation investigates several potential Vehicle-to-Cloud-to-Vehicle (V2C2V) applications that can enhance vehicle control and enable additional functionalities by integrating onboard and cloud resources.
Firstly, this thesis demonstrates that onboard vehicle sensors can be used to sense road profiles and detect anomalies. This information can be shared with other vehicles and transportation authorities within a V2C2V framework. The response of hitting a pothole is characterized by a multi-phase dynamic model which is validated by comparing simulation results with a higher-fidelity commercial modeling package. A novel framework of simultaneous road profile estimation and anomaly detection is developed by combining a jump diffusion process (JDP)-based estimator and a multi-input observer. The performance of this scheme is evaluated in an experimental vehicle. In addition, a new clustering algorithm is developed to compress anomaly information by processing anomaly report streams.
Secondly, a cloud-aided semi-active suspension control problem is studied demonstrating for the first time that road profile information and noise statistics from the cloud can be used to enhance suspension control. The problem of selecting an optimal damping mode from a finite set of damping modes is considered and the best mode is selected based on performance prediction on the cloud.
Finally, a cloud-aided multi-metric route planner is investigated in which safety and comfort metrics augment traditional planning metrics such as time, distance, and fuel economy. The safety metric is developed by processing a comprehensive road and crash database while the comfort metric integrates road roughness and anomalies. These metrics and a planning algorithm can be implemented on the cloud to realize the multi-metric route planning. Real-world case studies are presented. The main contribution of this part of the dissertation is in demonstrating the feasibility and benefits of enhancing the existing route planning algorithms with safety and comfort metrics.PhDAerospace EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/120710/1/zhaojli_1.pd
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Real-time sensor data development for smart truck drivetrains
Heavy articulated transport vehicles have a poor reputation associated with dramatic road accidents with frequent fatalities for those in automobiles. The result of this work is a formal data flow structure to enhance real-time decision-making in complex mechanical systems to increase performance capability and responsiveness to human commands. This structure recognizes the multiple layers of highly non-linear mechanical components (actuators, wheel tire & ground surfaces, controllers, power supplies, human/machine interfaces, etc.) that must operate in unison (i.e., reduce conflicts) in real-time (in milli-seconds) to enhance operator (driver) control to maximize human choice. This work contains a discussion on dependable sensor data is vital in complex systems that rely on a suite of sensors for both control as well as condition monitoring purposes as well as discussion on real-time energy distribution analysis in high momentum mechanical systems. The focus will be on tractor trucks of class 7 & 8 that are outfitted with an array of low-cost redundant sensors leveraging advances in intelligent robotic systems. This work details many topics including: Most relevant sensor types and their technologies, Designing, implementing, and maintaining a multi-sensor system using feasible industry standards, Sensor signal integrity and data flow processing for decision making, Asynchronous data flow methods for operating decision making schemes in real-time, Multiple applications to enhance tractor trucks systems with multi-sensor systems for real-time decision making.Mechanical Engineerin
Kinisi: A Platform for Autonomizing Off-Road Vehicles
This project proposed a modular system that would autonomize off-road vehicles while retaining full manual operability. This MQP team designed and developed a Level 3 autonomous vehicle prototype using an SAE Baja vehicle outfitted with actuators and exteroceptive sensors. At the end of the project, the vehicle had a drive-by-wire system, could localize itself using sensors, generate a map of its surroundings, and plan a path to follow a desired trajectory. Given a map, the vehicle could traverse a series of obstacles in an enclosed environment. The long- term goal is to alter the software system to make it modular and operate in real-time, so the vehicle can autonomously navigate off-road terrain to rescue and aid a distressed individual
State estimation technique for a planetary robotic rover
Given the long traverse times and severe environmental constraints on a planet like Mars, the only option feasible now is to observe and explore the planet through more sophisticated planetary rovers. To achieve increasingly ambitious mission objectives under such extreme conditions, the rovers must have autonomy. Increased autonomy, obviously, relies on the quality of estimates of rover's state i.e. its position and orientation relative to some starting frame of reference. This research presents a state estimation approach based on Extended Kalman Filter (EKF) to fuse distance from odometry and attitude from an Inertial Measurement Unit (IMU), thus mitigating the errors generated by the use of either system alone. To simulate a Sun-sensor based approach for absolute corrections, a magnetic compass was used to give absolute heading updates. The technique was implemented on MotherBot, a custom-designed skid steered rover. Experimental results validate the application of the presented estimation strategy. It showed an error range within 3% of the distance travelled as compared to about 8% error obtained from direct fusion
Road Surface Feature Extraction and Reconstruction of Laser Point Clouds for Urban Environment
Automakers are developing end-to-end three-dimensional (3D) mapping system for Advanced Driver Assistance Systems (ADAS) and autonomous vehicles (AVs). Using geomatics, artificial intelligence, and SLAM (Simultaneous Localization and Mapping) systems to handle all stages of map creation, sensor calibration and alignment. It is crucial to have a system highly accurate and efficient as it is an essential part of vehicle controls. Such mapping requires significant resources to acquire geographic information (GIS and GPS), optical laser and radar spectroscopy, Lidar, and 3D modeling applications in order to extract roadway features (e.g., lane markings, traffic signs, road-edges) detailed enough to construct a “base map”. To keep this map current, it is necessary to update changes due to occurring events such as construction changes, traffic patterns, or growth of vegetation. The information of the road play a very important factor in road traffic safety and it is essential for for guiding autonomous vehicles (AVs), and prediction of upcoming road situations within AVs. The data size of the map is extensive due to the level of information provided with different sensor modalities for that reason a data optimization and extraction from three-dimensional (3D) mobile laser scanning (MLS) point clouds is presented in this thesis. The research shows the proposed hybrid filter configuration together with the dynamic developed mechanism provides significant reduction of the point cloud data with reduced computational or size constraints. The results obtained in this work are proven by a real-world system
Road vehicle state estimation using low-cost GPS/INS
Due to noise and bias in the Inertial Navigation System (INS), vehicle dynamics
measurements using the INS are inaccurate. Although alternative methods involving
the integration of INS with accurate Global Positioning System (GPS) exist and
are accurate, this kind of system is far too expensive to become value-adding to
production vehicles. This thesis therefore considers two aspects: 1) the possibility
of estimating vehicle dynamics using low-cost INS and GPS, and 2) the importance
of vehicle dynamics in terms of handling in the eyes of customers upon vehicle
purchase. The former aspect is considered from an engineering perspective and the
latter is studied in a marketing context.
From an engineering point of view, knowledge of vehicle dynamics not only improves
existing safety control systems, such the Anti-lock Braking System (ABS)
and Electronic Stabilising Program (ESP), but also allows the development of new
systems. Based on modelling and simulation in MATLAB/Simulink, low-cost GPS
and in-car INS (such as accelerometers, gyroscopes and wheel speed sensors) measurements
are fused using Kalman Filters (KFs) to estimate the vehicle dynamics.
These estimations are then compared with the simulation results from IPG Car-
Maker. For most simulations, the speed of the vehicle is kept between 15 to 55kph.
It is found that while triple KF designs are able to estimate the tyre radius, the
longitudinal velocity and the heading angle accurately, an integrated KF design
with known vehicle parameters is also able to estimate the lateral velocity precisely.
Apart from studying and comparing different KF designs with restricted sensors
quality, the effects and benefits of different sensor qualities in dynamic estimations
are also studied via the variation of sensor sampling rates and accuracies. This investigation
produces a design procedure and estimation error analyses (theoretical
and graphical) which may help future engineers in designing their KFs.
From a marketing perspective, it is important to understand customers’ purchase
reasons in order to allocate resources more efficiently and effectively. As GPS/INS
KF designs are able to enhance vehicle handling, it is vital to understand the relative
importance of vehicle handling as a consumer purchase choice criterion. Based on two surveys, namely the New Vehicle Experience Survey in the US (NVES US)
and the New Car Buyer Survey in the UK (NCBS UK), analyses are performed in a
computer program called the Predictive Analytics SoftWare (PASW), which is formerly
known as the Statistical Package for the Social Sciences (SPSS). The number
of purchase reasons are first reduced with factor analysis, the latent factors produced
are then used in the SPSS Two Step Cluster analysis for customer segmentation.
With the customer segments and the latent factors defined, a discriminant analysis
is carried out to determine customer type in the automobile sector, in particular for
Jaguar Cars. It is found that customers in general take vehicle handling for granted
and often underrate its importance in their purchase. New vehicle handling-aided
systems therefore need to be marketed in terms of the value they add to other benefits
such as reliability and performance in order to increase sales and stakeholder
value
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