29 research outputs found
Computationally-efficient visual inertial odometry for autonomous vehicle
This thesis presents the design, implementation, and validation of a novel nonlinearfiltering
based Visual Inertial Odometry (VIO) framework for robotic navigation in GPSdenied
environments. The system attempts to track the vehicle’s ego-motion at each time
instant while capturing the benefits of both the camera information and the Inertial Measurement
Unit (IMU). VIO demands considerable computational resources and processing
time, and this makes the hardware implementation quite challenging for micro- and nanorobotic
systems. In many cases, the VIO process selects a small subset of tracked features
to reduce the computational cost. VIO estimation also suffers from the inevitable accumulation
of error. This limitation makes the estimation gradually diverge and even fail to
track the vehicle trajectory over long-term operation. Deploying optimization for the entire
trajectory helps to minimize the accumulative errors, but increases the computational cost
significantly. The VIO hardware implementation can utilize a more powerful processor
and specialized hardware computing platforms, such as Field Programmable Gate Arrays,
Graphics Processing Units and Application-Specific Integrated Circuits, to accelerate the
execution. However, the computation still needs to perform identical computational steps
with similar complexity. Processing data at a higher frequency increases energy consumption
significantly. The development of advanced hardware systems is also expensive and
time-consuming. Consequently, the approach of developing an efficient algorithm will be
beneficial with or without hardware acceleration. The research described in this thesis
proposes multiple solutions to accelerate the visual inertial odometry computation while
maintaining a comparative estimation accuracy over long-term operation among state-ofthe-
art algorithms.
This research has resulted in three significant contributions. First, this research involved
the design and validation of a novel nonlinear filtering sensor-fusion algorithm using trifocal
tensor geometry and a cubature Kalman filter. The combination has handled the system
nonlinearity effectively, while reducing the computational cost and system complexity significantly.
Second, this research develops two solutions to address the error accumulation
issue. For standalone self-localization projects, the first solution applies a local optimization
procedure for the measurement update, which performs multiple corrections on a single
measurement to optimize the latest filter state and covariance. For larger navigation
projects, the second solution integrates VIO with additional pseudo-ranging measurements
between the vehicle and multiple beacons in order to bound the accumulative errors. Third,
this research develops a novel parallel-processing VIO algorithm to speed up the execution
using a multi-core CPU. This allows the distribution of the filtering computation on each
core to process and optimize each feature measurement update independently.
The performance of the proposed visual inertial odometry framework is evaluated using
publicly-available self-localization datasets, for comparison with some other open-source
algorithms. The results illustrate that a proposed VIO framework is able to improve the
VIO’s computational efficiency without the installation of specialized hardware computing
platforms and advanced software libraries
Algorithms for Positioning with Nonlinear Measurement Models and Heavy-tailed and Asymmetric Distributed Additive Noise
Determining the unknown position of a user equipment using measurements obtained from transmitters with known locations generally results in a nonlinear measurement function. The measurement errors can have a heavy-tailed and/ or skewed distribution, and the likelihood function can be multimodal.A positioning problem with a nonlinear measurement function is often solved by a nonlinear least squares (NLS) method or, when filtering is desired, by an extended Kalman filter (EKF). However, these methods are unable to capture multiple peaks of the likelihood function and do not address heavy-tailedness or skewness. Approximating the likelihood by a Gaussian mixture (GM) and using a GM filter (GMF) solves the problem. The drawback is that the approximation requires a large number of components in the GM for a precise approximation, which makes it unsuitable for real-time positioning on small mobile devices.This thesis studies a generalised version of Gaussian mixtures, which is called GGM, to capture multiple peaks. It relaxes the GM’s restriction to non-negative component weights. The analysis shows that the GGM allows a significant reduction of the number of required Gaussian components when applied for approximating the measurement likelihood of a transmitter with an isotropic antenna, compared with the GM. Therefore, the GGM facilitates real-time positioning in small mobile devices. In tests for a cellular telephone network and for an ultra-wideband network the GGM and its filter provide significantly better positioning accuracy than the NLS and the EKF.For positioning with nonlinear measurement models, and heavytailed and skewed distributed measurement errors, an Expectation Maximisation (EM) algorithm is studied. The EM algorithm is compared with a standard NLS algorithm in simulations and tests with realistic emulated data from a long term evolution network. The EM algorithm is more robust to measurement outliers. If the errors in training and positioning data are similar distributed, then the EM algorithm yields significantly better position estimates than the NLS method. The improvement in accuracy and precision comes at the cost of moderately higher computational demand and higher vulnerability to changing patterns in the error distribution (of training and positioning data). This vulnerability is caused by the fact that the skew-t distribution (used in EM) has 4 parameters while the normal distribution (used in NLS) has only 2. Hence the skew-t yields a closer fit than the normal distribution of the pattern in the training data. However, on the downside if patterns in training and positioning data vary than the skew-t fit is not necessarily a better fit than the normal fit, which weakens the EM algorithm’s positioning accuracy and precision. This concept of reduced generalisability due to overfitting is a basic rule of machine learning.This thesis additionally shows how parameters of heavy-tailed and skewed error distributions can be fitted to training data. It furthermore gives an overview on other parametric methods for solving the positioning method, how training data is handled and summarised for them, how positioning is done by them, and how they compare with nonparametric methods. These methods are analysed by extensive tests in a wireless area network, which shows the strength and weaknesses of each method
Estimation Algorithms for Non-Gaussian State-Space Models with Application to Positioning
State-space models (SSMs) are used to model systems with hidden time-varying state and observable measurement output. In statistical SSMs, the state dynamics is assumed known up to a random term referred to as the process noise, and the measurements contain random measurement noise. Kalman filter (KF) and Rauch– Tung–Striebel smoother (RTSS) are widely-applied closed-form algorithms that provide the parameters of the exact Bayesian filtering and smoothing distributions for discrete-time linear statistical SSMs where the process and measurement noises follow Gaussian distributions. However, when the SSM involves nonlinear functions and/or non-Gaussian noises, the Bayesian filtering and smoothing distributions cannot in general be solved using closed-form algorithms. This thesis addresses approximate Bayesian time-series inference for two positioning-related problems where the assumption of Gaussian noises cannot capture all useful knowledge of the considered system’s statistical properties: map-assisted indoor positioning and positioning using time-delay measurements.The motion constraints imposed by the indoor map are typically incorporated in the position estimate using the particle filter (PF) algorithm. The PF is a Monte Carlo algorithm especially suited for statistical SSMs where the Bayesian posterior distributions are too complicated to be adequately approximated using a well-known distribution family with a low-dimensional parameter space. In mapassisted indoor positioning, the trajectories that cross walls or floor levels get a low probability in the model. In this thesis, improvements to three different PF algorithms for map-assisted indoor positioning are proposed and compared. In the wall-collision PF, weighted random samples, also known as particles, are moved based on inertial sensor measurements, and the particles that collide with the walls are downweighted. When the inertial sensor measurements are very noisy, map information is used to guide the particles such that fewer particles collide with the walls, which implies that more particles contribute to the estimation. When no inertial sensor information is used, the particles are moved along the links of a graph that is dense enough to approximate the set of expected user paths.Time-delay based ranging measurements of e.g. ultra-wideband (UWB) and Global Navigation Satellite Systems (GNSSs) contain occasional positive measurement errors that are large relative to the majority of the errors due to multipath effects and denied line of sight. In this thesis, computationally efficient approximate Bayesian filters and smoothers are proposed for statistical SSMs where the measurement noise follows a skew t -distribution, and the algorithms are applied to positioning using time-delay based ranging measurements. The skew t -distribution is an extension of the Gaussian distribution, which has two additional parameters that affect the heavytailedness and skewness of the distribution. When the measurement noise model is heavy-tailed, the optimal Bayesian algorithm is robust to occasional large measurement errors, and when the model is positively (or negatively) skewed, the algorithms account for the fact that most large errors are known to be positive (or negative). Therefore, the skew t -distribution is more flexible than the Gaussian distribution and captures more statistical features of the error distributions of UWB and GNSS measurements. Furthermore, the skew t -distribution admits a conditionally Gaussian hierarchical form that enables approximating the filtering and smoothing posteriors with Gaussian distributions using variational Bayes (VB) algorithms. The proposed algorithms can thus be computationally efficient compared to Monte Carlo algorithms especially when the state is high-dimensional. It is shown in this thesis that the skew-t filter improves the accuracy of UWB based indoor positioning and GNSS based outdoor positioning in urban areas compared to the extended KF. The skew-t filter’s computational burden is higher than that of the extended KF but of the same magnitude.Tila-avaruusmalleilla mallinnetaan järjestelmiä, joilla on tuntema-ton ajassa muuttuva tila sekä mitatattava ulostulo. Tilastollisissa tila-avaruusmalleissa järjestelmän tilan muutos tunnetaan lukuunotta-matta prosessikohinaksi kutsuttua satunnaista termiä, ja mittauk-set sisältävät satunnaista mittauskohinaa. Kalmanin suodatin sekäRauchin Tungin ja Striebelin siloitin ovat yleisesti käytettyjä sulje-tun muodon estimointialgoritmeja, jotka tuottavat tarkat bayesiläi-set suodatus- ja siloitusjakaumat diskreettiaikaisille lineaarisille ti-lastollisille tila-avaruusmalleille, joissa prosessi- ja mittauskohinatnoudattavat gaussisia jakaumia. Jos käsiteltyyn tila-avaruusmalliinkuitenkin liittyy epälineaarisia funktioita tai epägaussisia kohinoita,bayesiläisiä suodatus- ja siloitusjakaumia ei yleensä voida ratkais-ta suljetun muodon algoritmeilla. Tässä väitöskirjassa tutkitaan ap-proksimatiivista bayesiläistä aikasarjapäättelyä ja sen soveltamistakahteen paikannusongelmaan, joissa gaussinen jakauma ei mallinnariittävän hyvin kaikkea hyödyllistä tietoa tutkitun järjestelmän tilas-tollisista ominaisuuksista: kartta-avusteinen sisätilapaikannus sekäsignaalin kulkuaikamittauksiin perustuva paikannus.Sisätilakartan tuottamat liikerajoitteet voidaan liittää paikkaestimaat-tiin käyttäen partikkelisuodattimeksi kutsuttua algoritmia. Partik-kelisuodatin on Monte Carlo -algoritmi, joka soveltuu erityisesti ti-lastollisille tila-avaruusmalleille, joissa bayesiläisen posteriorijakau-man tiheysfunktio on niin monimutkainen, että sen approksimointitunnetuilla matalan parametridimension jakaumilla ei ole mielekäs-tä. Kartta-avusteisessa sisätilapaikannuksessa reitit, jotka leikkaavatseiniä tai kerrostasoja, saavat muita pienemmät todennäköisyydet.Tässä väitöskirjassa esitetään parannuksia kolmeen eri partikkelisuo-datusalgoritmiin, joita sovelletaan kartta-avusteiseen sisätilapaikan-vnukseen. Seinätörmayssuodattimessa painolliset satunnaisnäytteeteli partikkelit liikkuvat inertiasensorimittausten mukaisesti, ja sei-nään törmäävät partikkelit saavat pienet painot. Kun inertiasensori-mittauksissa on paljon kohinaa, partikkeleita voidaan ohjata siten,että seinätörmäysten määrä vähenee, jolloin suurempi osa partikke-leista vaikuttaa estimaattiin. Kun inertiasensorimittauksia ei käytetälainkaan, sisätilakartta voidaan esittää graafina, jonka kaarilla partik-kelit liikkuvat ja joka on riittävän tiheä approksimoimaan odotetta-vissa olevien reittien joukkoa.Esimerkiksi laajan taajuuskaistan radioista (UWB, ultra-wideband)tai paikannussatelliiteista saatavat radiosignaalin kulkuaikaan pe-rustuvat etäisyysmittaukset taas voivat sisältää monipolkuheijastus-ten ja suoran reitin estymisen aiheuttamia positiivismerkkisiä vir-heitä, jotka ovat huomattavan suuria useimpiin mittausvirheisiinverrattuna. Tässä väitöskirjassa esitetään laskennallisesti tehokkaitabayesiläisen suodattimen ja siloittimen approksimaatioita tilastol-lisille tila-avaruusmalleille, joissa mittauskohina noudattaa vinoat -jakaumaa. Vino t -jakauma on gaussisen jakauman laajennos, jasillä on kaksi lisäparametria, jotka vaikuttavat jakauman paksuhän-täisyyteen ja vinouteen. Kun mittauskohinaa mallintava jakaumaoletetaan paksuhäntäiseksi, optimaalinen bayesiläinen algoritmi eiole herkkä yksittäisille suurille mittausvirheille, ja kun jakauma olete-taan positiivisesti (tai negatiivisesti) vinoksi, algoritmit hyödyntävättietoa, että suurin osa suurista virheistä on positiivisia (tai negatiivi-sia). Vino t -jakauma on siis gaussista jakaumaa joustavampi, ja sillävoidaan mallintaa kulkuaikaan perustuvien mittausten virhejakau-maa tarkemmin kuin gaussisella jakaumalla. Vinolla t -jakaumalla onmyös ehdollisesti gaussinen esitys, joka soveltuu suodatus- ja siloi-tusposteriorien approksimointiin variaatio-Bayes-algoritmilla. Näinollen esitetyt algoritmit voivat olla laskennallisesti tehokkaampiakuin Monte Carlo -algoritmit erityisesti tilan ollessa korkeaulotteinen.Tässä väitöskirjassa näytetään, että vino-t -virhejakauman käyttö pa-rantaa UWB-radioon perustuvan sisätilapaikannuksen tarkkuuttasekä satelliittipohjaisen ulkopaikannuksen tarkkuutta kaupunkiym-päristössä verrattuna laajennettuun Kalmanin suodattimeen. Vino-t -suodatuksen laskennallinen vaativuus on suurempi mutta samaakertaluokkaa kuin laajennetun Kalmanin suodattimen
Reliable Navigation for SUAS in Complex Indoor Environments
Indoor environments are a particular challenge for Unmanned Aerial Vehicles (UAVs). Effective navigation through these GPS-denied environments require alternative localization systems, as well as methods of sensing and avoiding obstacles while remaining on-task. Additionally, the relatively small clearances and human presence characteristic of indoor spaces necessitates a higher level of precision and adaptability than is common in traditional UAV flight planning and execution. This research blends the optimization of individual technologies, such as state estimation and environmental sensing, with system integration and high-level operational planning.
The combination of AprilTag visual markers, multi-camera Visual Odometry, and IMU data can be used to create a robust state estimator that describes position, velocity, and rotation of a multicopter within an indoor environment. However these data sources have unique, nonlinear characteristics that should be understood to effectively plan for their usage in an automated environment. The research described herein begins by analyzing the unique characteristics of these data streams in order to create a highly-accurate, fault-tolerant state estimator.
Upon this foundation, the system built, tested, and described herein uses Visual Markers as navigation anchors, visual odometry for motion estimation and control, and then uses depth sensors to maintain an up-to-date map of the UAV\u27s immediate surroundings. It develops and continually refines navigable routes through a novel combination of pre-defined and sensory environmental data. Emphasis is put on the real-world development and testing of the system, through discussion of computational resource management and risk reduction
Clustering for filtering: multi-object detection and estimation using multiple/massive sensors
Advanced multi-sensor systems are expected to combat the challenges that arise in object recognition and state estimation in harsh environments with poor or even no prior information, while bringing new challenges mainly related to data fusion and computational burden. Unlike the prevailing Markov-Bayes framework that is the basis of a large variety of stochastic filters and the approximate, we propose a clustering-based methodology for multi-sensor multi-object detection and estimation (MODE), named clustering for filtering (C4F), which abandons unrealistic assumptions with respect to the objects, background and sensors. Rather, based on cluster analysis of the input multi-sensor data, the C4F approach needs no prior knowledge about the latent objects (whether quantity or dynamics), can handle time-varying uncertainties regarding the background and sensors such as noises, clutter and misdetection, and does so computationally fast. This offers an inherently robust and computationally efficient alternative to conventional Markov–Bayes filters for dealing with the scenario with little prior knowledge but rich observation data. Simulations based on representative scenarios of both complete and little prior information have demonstrated the superiority of our C4F approach
Estimation Algorithms for Non-Gaussian State-Space Models with Application to Positioning
State-space models (SSMs) are used to model systems with hidden time-varying state and observable measurement output. In statistical SSMs, the state dynamics is assumed known up to a random term referred to as the process noise, and the measurements contain random measurement noise. Kalman filter (KF) and Rauch– Tung–Striebel smoother (RTSS) are widely-applied closed-form algorithms that provide the parameters of the exact Bayesian filtering and smoothing distributions for discrete-time linear statistical SSMs where the process and measurement noises follow Gaussian distributions. However, when the SSM involves nonlinear functions and/or non-Gaussian noises, the Bayesian filtering and smoothing distributions cannot in general be solved using closed-form algorithms. This thesis addresses approximate Bayesian time-series inference for two positioning-related problems where the assumption of Gaussian noises cannot capture all useful knowledge of the considered system’s statistical properties: map-assisted indoor positioning and positioning using time-delay measurements.The motion constraints imposed by the indoor map are typically incorporated in the position estimate using the particle filter (PF) algorithm. The PF is a Monte Carlo algorithm especially suited for statistical SSMs where the Bayesian posterior distributions are too complicated to be adequately approximated using a well-known distribution family with a low-dimensional parameter space. In mapassisted indoor positioning, the trajectories that cross walls or floor levels get a low probability in the model. In this thesis, improvements to three different PF algorithms for map-assisted indoor positioning are proposed and compared. In the wall-collision PF, weighted random samples, also known as particles, are moved based on inertial sensor measurements, and the particles that collide with the walls are downweighted. When the inertial sensor measurements are very noisy, map information is used to guide the particles such that fewer particles collide with the walls, which implies that more particles contribute to the estimation. When no inertial sensor information is used, the particles are moved along the links of a graph that is dense enough to approximate the set of expected user paths.Time-delay based ranging measurements of e.g. ultra-wideband (UWB) and Global Navigation Satellite Systems (GNSSs) contain occasional positive measurement errors that are large relative to the majority of the errors due to multipath effects and denied line of sight. In this thesis, computationally efficient approximate Bayesian filters and smoothers are proposed for statistical SSMs where the measurement noise follows a skew t -distribution, and the algorithms are applied to positioning using time-delay based ranging measurements. The skew t -distribution is an extension of the Gaussian distribution, which has two additional parameters that affect the heavytailedness and skewness of the distribution. When the measurement noise model is heavy-tailed, the optimal Bayesian algorithm is robust to occasional large measurement errors, and when the model is positively (or negatively) skewed, the algorithms account for the fact that most large errors are known to be positive (or negative). Therefore, the skew t -distribution is more flexible than the Gaussian distribution and captures more statistical features of the error distributions of UWB and GNSS measurements. Furthermore, the skew t -distribution admits a conditionally Gaussian hierarchical form that enables approximating the filtering and smoothing posteriors with Gaussian distributions using variational Bayes (VB) algorithms. The proposed algorithms can thus be computationally efficient compared to Monte Carlo algorithms especially when the state is high-dimensional. It is shown in this thesis that the skew-t filter improves the accuracy of UWB based indoor positioning and GNSS based outdoor positioning in urban areas compared to the extended KF. The skew-t filter’s computational burden is higher than that of the extended KF but of the same magnitude.Tila-avaruusmalleilla mallinnetaan järjestelmiä, joilla on tuntema-ton ajassa muuttuva tila sekä mitatattava ulostulo. Tilastollisissa tila-avaruusmalleissa järjestelmän tilan muutos tunnetaan lukuunotta-matta prosessikohinaksi kutsuttua satunnaista termiä, ja mittauk-set sisältävät satunnaista mittauskohinaa. Kalmanin suodatin sekäRauchin Tungin ja Striebelin siloitin ovat yleisesti käytettyjä sulje-tun muodon estimointialgoritmeja, jotka tuottavat tarkat bayesiläi-set suodatus- ja siloitusjakaumat diskreettiaikaisille lineaarisille ti-lastollisille tila-avaruusmalleille, joissa prosessi- ja mittauskohinatnoudattavat gaussisia jakaumia. Jos käsiteltyyn tila-avaruusmalliinkuitenkin liittyy epälineaarisia funktioita tai epägaussisia kohinoita,bayesiläisiä suodatus- ja siloitusjakaumia ei yleensä voida ratkais-ta suljetun muodon algoritmeilla. Tässä väitöskirjassa tutkitaan ap-proksimatiivista bayesiläistä aikasarjapäättelyä ja sen soveltamistakahteen paikannusongelmaan, joissa gaussinen jakauma ei mallinnariittävän hyvin kaikkea hyödyllistä tietoa tutkitun järjestelmän tilas-tollisista ominaisuuksista: kartta-avusteinen sisätilapaikannus sekäsignaalin kulkuaikamittauksiin perustuva paikannus.Sisätilakartan tuottamat liikerajoitteet voidaan liittää paikkaestimaat-tiin käyttäen partikkelisuodattimeksi kutsuttua algoritmia. Partik-kelisuodatin on Monte Carlo -algoritmi, joka soveltuu erityisesti ti-lastollisille tila-avaruusmalleille, joissa bayesiläisen posteriorijakau-man tiheysfunktio on niin monimutkainen, että sen approksimointitunnetuilla matalan parametridimension jakaumilla ei ole mielekäs-tä. Kartta-avusteisessa sisätilapaikannuksessa reitit, jotka leikkaavatseiniä tai kerrostasoja, saavat muita pienemmät todennäköisyydet.Tässä väitöskirjassa esitetään parannuksia kolmeen eri partikkelisuo-datusalgoritmiin, joita sovelletaan kartta-avusteiseen sisätilapaikan-vnukseen. Seinätörmayssuodattimessa painolliset satunnaisnäytteeteli partikkelit liikkuvat inertiasensorimittausten mukaisesti, ja sei-nään törmäävät partikkelit saavat pienet painot. Kun inertiasensori-mittauksissa on paljon kohinaa, partikkeleita voidaan ohjata siten,että seinätörmäysten määrä vähenee, jolloin suurempi osa partikke-leista vaikuttaa estimaattiin. Kun inertiasensorimittauksia ei käytetälainkaan, sisätilakartta voidaan esittää graafina, jonka kaarilla partik-kelit liikkuvat ja joka on riittävän tiheä approksimoimaan odotetta-vissa olevien reittien joukkoa.Esimerkiksi laajan taajuuskaistan radioista (UWB, ultra-wideband)tai paikannussatelliiteista saatavat radiosignaalin kulkuaikaan pe-rustuvat etäisyysmittaukset taas voivat sisältää monipolkuheijastus-ten ja suoran reitin estymisen aiheuttamia positiivismerkkisiä vir-heitä, jotka ovat huomattavan suuria useimpiin mittausvirheisiinverrattuna. Tässä väitöskirjassa esitetään laskennallisesti tehokkaitabayesiläisen suodattimen ja siloittimen approksimaatioita tilastol-lisille tila-avaruusmalleille, joissa mittauskohina noudattaa vinoat -jakaumaa. Vino t -jakauma on gaussisen jakauman laajennos, jasillä on kaksi lisäparametria, jotka vaikuttavat jakauman paksuhän-täisyyteen ja vinouteen. Kun mittauskohinaa mallintava jakaumaoletetaan paksuhäntäiseksi, optimaalinen bayesiläinen algoritmi eiole herkkä yksittäisille suurille mittausvirheille, ja kun jakauma olete-taan positiivisesti (tai negatiivisesti) vinoksi, algoritmit hyödyntävättietoa, että suurin osa suurista virheistä on positiivisia (tai negatiivi-sia). Vino t -jakauma on siis gaussista jakaumaa joustavampi, ja sillävoidaan mallintaa kulkuaikaan perustuvien mittausten virhejakau-maa tarkemmin kuin gaussisella jakaumalla. Vinolla t -jakaumalla onmyös ehdollisesti gaussinen esitys, joka soveltuu suodatus- ja siloi-tusposteriorien approksimointiin variaatio-Bayes-algoritmilla. Näinollen esitetyt algoritmit voivat olla laskennallisesti tehokkaampiakuin Monte Carlo -algoritmit erityisesti tilan ollessa korkeaulotteinen.Tässä väitöskirjassa näytetään, että vino-t -virhejakauman käyttö pa-rantaa UWB-radioon perustuvan sisätilapaikannuksen tarkkuuttasekä satelliittipohjaisen ulkopaikannuksen tarkkuutta kaupunkiym-päristössä verrattuna laajennettuun Kalmanin suodattimeen. Vino-t -suodatuksen laskennallinen vaativuus on suurempi mutta samaakertaluokkaa kuin laajennetun Kalmanin suodattimen
Ultra-wideband Based Indoor Localization of Mobile Nodes in ToA and TDoA Configurations
Zandian R. Ultra-wideband Based Indoor Localization of Mobile Nodes in ToA and TDoA Configurations. Bielefeld: Universität Bielefeld; 2019.This thesis discusses the utilization of ultra-wideband (UWB) technology in indoor localization scenarios and proposes system setup and evaluates different localization algorithms in order to improve the localization accuracy and stability of such systems in non-ideal conditions of the indoor environment.
Recent developments and advances of technology in the areas of ubiquitous Internet, robotics and internet of things (IoT) have resulted in emerging new application areas in daily life in which localization systems are vital. The significant demand for a robust and accurate localization system that is applicable in indoor areas lacking satellites link, can be sensed. The UWB technology offers accurate localization systems with an accuracy of below 10 cm and covering the range of up to a few hundred meters thanks to their dedicated large bandwidth, modulation technique and signal power.
In this thesis, the technology behind the UWB systems is discussed in detail. In terms of localization topologies, different scenarios with the focus on time-based methods are introduced. The main focus of this thesis is on the differential time of arrival localization systems (TDoA) with unilateral constellation that is suitable for robotic localization and navigation applications.
A new approach for synchronization of TDoA topology is proposed and influence of clock inaccuracies in such systems are thoroughly evaluated. For localization engine, two groups of static and dynamic iterative algorithms are introduced. Among the possible dynamic methods, extended Kalman filter (EKF), H∞ and unscented Kalman filter (UKF) are discussed and meticulously evaluated.
In order to tackle the non-line of sight (NLOS) problem of such systems, for detection stage several solutions which are based on parametric machine learning methods are proposed. Furthermore, for mitigation phase two solutions namely adjustment of measurement variance and innovation term are suggested. Practical results prove the efficiency and high reliability of the proposed algorithms with positive NLOS condition detection rate of more than 87%.
In practical trials, the localization system is evaluated in indoor and outdoor arenas in both line of sight and non-line of sight conditions. The results show that the proposed detection and mitigation methods can be successfully applied for both small and large-scale arenas with the higher performance of the localization filters in terms of accuracy in large-scale scenarios
Accurate Localization with Ultra-Wideband Ranging for Multi-Robot Systems
RÉSUMÉ : Avec l’avancement de la technologie matérielle et logicielle, l’application de l’automatisation et de la robotique se développe rapidement. Les systèmes multi-robots sont particulièrement prometteurs en raison de leur grande efficacité et robustesse. De tels systèmes peuvent être utilisés pour aider les humains à effectuer efficacement des tâches dangereuses ou pénibles, telles que l’intervention en cas de catastrophe, l’exploration souterraine, etc. Pour déployer un système multi-robot dans un environnement sans GPS, la coordination des robots dans le système est un défi crucial. Chaque robot doit avoir une estimation précise de sa propre position pour permettre aux robots du système de collaborer pour la réalisation de leur tâche. Comme cette direction de recherche est relativement nouvelle, les approches existantes ne sont pas encore abouties. Elles consistent principalement en des systèmes centralisés qui reposent sur des signaux GPS. La dépendance sur un signal GPS limite l’application aux espaces extérieurs ouverts. De plus, les systèmes centralisés sont confrontés au risque d’un point de défaillance unique, qui limite la robustesse du système. Par ailleurs, un système centralisé n’est pas toujours approprié à une taille grandissante, comme lors d’ajout de nouveaux groupes de robots ou lors de la fusion de différents groupes. Par conséquent, une solution distribuée, décentralisée, et adaptée à de larges groupes de tailles variables pouvant produire une estimation et un suivi du positionnement des robots dans un environnement sans GPS est souhaitée. Dans ce travail, nous adoptons une stratégie descendante pour relever ces défis.----------ABSTRACT : With the advancement of hardware and software technology, the everyday applications of automation and robotics are developing rapidly. Multi-robot systems are particularly promising because of their high efficiency and robustness. Such systems can be used to assist humans in performing dangerous or strenuous tasks, such as disaster response, subterranean exploration, etc. To deploy a multi-robot system in an environment without a global positioning system (GPS), coordinating the robots in the system is a crucial challenge. Each robot needs to have the correct tracking of its own and its teammates positions to enable the robots to cooperate. Because this research direction is relatively new, there are not many mature methods: existing approaches are mainly centralized systems that rely on GPS signals. The dependence on GPS restricts the application to the outdoors or indoor spaces with expensive infrastructure. Centralized systems also face the risk of a single point of failure, which is not acceptable for critical systems. In addition, centralized systems can be hard to scale both statically and dynamically (e.g. adding new groups of robots or merging different groups). Therefore, a distributed and scalable solution with accurate positioning and tracking in a GPS-denied environment is desired. In this work, we follow a top-down strategy to address these challenges