Visually guided autonomous robot navigation : an insect based approach.

Weber, Keven

January 1998

Giving robots the ability to move around autonomously in various real-world environments has long been a major challenge for Artificial Intelligence. New approaches to the design and control of autonomous robots have shown the value of drawing inspiration from the natural world. Animals navigate, perceive and interact with various uncontrolled environments with seemingly little effort. Flying insects, in particular, are quite adept at manoeuvring in complex, unpredictable and possibly hostile environments.Inspired by the miniature machine view of insects, this thesis contributes to the autonomous control of mobile robots through the application of insect-based visual cues and behaviours. The parsimonious, yet robust, solutions offered by insects are directly applicable to the computationally restrictive world of autonomous mobile robots. To this end, two main navigational domains are focussed on: corridor guidance and visual homing.Within a corridor environment, safe navigation is achieved through the application of simple and intuitive behaviours observed in insect, visual navigation. By observing and responding to observed apparent motions in a reactive, yet intelligent way, the robot is able to exhibit useful corridor guidance behaviours at modest expense. Through a combination of both simulation and real-world robot experiments, the feasibility of equipping a mobile robot with the ability to safely navigate in various environments, is demonstrated.It is further shown that the reactive nature of the robot can be augmented to incorporate a map building method that allows previously encountered corridors to be recognised, through the observation of landmarks en route. This allows for a more globally-directed navigational goal.Many animals, including insects such as bees and ants, successfully engage in visual homing. This is achieved through the association of ++ / visual landmarks with a specific location. In this way, the insect is able to 'home in' on a previously visited site by simply moving in such a way as to maximise the match between the currently observed environment and the memorised 'snapshot' of the panorama as seen from the goal. A mobile robot can exploit the very same strategy to simply and reliably return to a previously visited location.This thesis describes a system that allows a mobile robot to home successfully. Specifically, a simple, yet robust, homing scheme that relies only upon the observation of the bearings of visible landmarks, is proposed. It is also shown that this strategy can easily be extended to incorporate other visual cues which may improve overall performance.The homing algorithm described, allows a mobile robot to home incrementally by moving in such a way as to gradually reduce the discrepancy between the current view and the view obtained from the home position. Both simulation and mobile robot experiments are again used to demonstrate the feasibility of the approach.

Mobilní robot s GNSS navigací / GNSS Navigated Mobile Robot

Chmelař, Jakub

January 2018

The diploma thesis is focused on the topic of global satellite navigation of mobile robots. The paper describes the principle of currently available global satellite navigation systems. The main element of the thesis is the proposal of mobile robot navigation algorithm. An integral part is also the design of a mobile robot to verify the functionality of the navigation algorithm. The robot software program is described. At the end, everything is verified by real experiments.

Návrh a implementace autonomního dokování mobilního robotu / Development of mobile robot autonomous docking

Čepl, Miroslav

January 2019

This thesis implements solution for automatic docking for a mobile robot using visual markers. After initial survey of already implemented works, new docking solution is proposed. Feasibility of the solution is verified with tests of marker detection precision. The implementation is tested in a simulation and with a real robot. The functionality of the proposed solution is verified by long-term tests. The result of this work is robot’s ability to navigate known environment to find and dock a charging station. After charging the robot is able to safely disconnect from the station.

Navigace mobilního robotu pomocí fuzzy logiky / Mobile robot navigation by means of fuzzy logic

Janovec, Aleš

January 2010

In the introductory part of this thesis there is an analysis of methods, which are used for navigation of mobile robots. The main part of the thesis contains a proposal of control system of mobile robot. Robot control system is based on fuzzy modeling. To test the control, a system simulation environment is created in C #, in which experiments were performed.

Socially aware robot navigation

Antonucci, Alessandro

03 November 2022

A growing number of applications involving autonomous mobile robots will require their navigation across environments in which spaces are shared with humans. In those situations, the robot’s actions are socially acceptable if they reflect the behaviours that humans would generate in similar conditions. Therefore, the robot must perceive people in the environment and correctly react based on their actions and relevance to its mission. In order to give a push forward to human-robot interaction, the proposed research is focused on efficient robot motion algorithms, covering all the tasks needed in the whole process, such as obstacle detection, human motion tracking and prediction, socially aware navigation, etc. The final framework presented in this thesis is a robust and efficient solution enabling the robot to correctly understand the human intentions and consequently perform safe, legible, and socially compliant actions. The thesis retraces in its structure all the different steps of the framework through the presentation of the algorithms and models developed, and the experimental evaluations carried out both with simulations and on real robotic platforms, showing the performance obtained in real–time in complex scenarios, where the humans are present and play a prominent role in the robot decisions. The proposed implementations are all based on insightful combinations of traditional model-based techniques and machine learning algorithms, that are adequately fused to effectively solve the human-aware navigation. The specific synergy of the two methodology gives us greater flexibility and generalization than the navigation approaches proposed so far, while maintaining accuracy and reliability which are not always displayed by learning methods.

A snake-based scheme for path planning and control with constraints by distributed visual sensors

Cheng, Yongqiang, Jiang, Ping, Hu, Yim Fun

09 August 2013

Yes / This paper proposes a robot navigation scheme using wireless visual sensors deployed in an environment. Different from the conventional autonomous robot approaches, the scheme intends to relieve massive on-board information processing required by a robot to its environment so that a robot or a vehicle with less intelligence can exhibit sophisticated mobility. A three-state snake mechanism is developed for coordinating a series of sensors to form a reference path. Wireless visual sensors communicate internal forces with each other along the reference snake for dynamic adjustment, react to repulsive forces from obstacles, and activate a state change in the snake body from a flexible state to a rigid or even to a broken state due to kinematic or environmental constraints. A control snake is further proposed as a tracker of the reference path, taking into account the robot’s non-holonomic constraint and limited steering power. A predictive control algorithm is developed to have an optimal velocity profile under robot dynamic constraints for the snake tracking. They together form a unified solution for robot navigation by distributed sensors to deal with the kinematic and dynamic constraints of a robot and to react to dynamic changes in advance. Simulations and experiments demonstrate the capability of a wireless sensor network to carry out low-level control activities for a vehicle. / Royal Society, Natural Science Funding Council (China)

Proposta de uma plataforma de testes para o desenvolvimento de veículos autônomos / Test platform proposal for the development of autonomous vehicles

Hernandez Beleño, Ruben Dario, 1986-

20 August 2018

Orientador: Janito Vaqueiro Ferreira / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-20T14:52:32Z (GMT). No. of bitstreams: 1 HernandezBeleno_RubenDario_M.pdf: 6591392 bytes, checksum: fd4c66b4e3769739bb1a4283c418d2d8 (MD5) Previous issue date: 2012 / Resumo: Com o avanço da tecnologia refletida nos sistemas eletrônicos e de computação, os métodos do controle de trajetória no sistema de navegação se tornaram importantes nas diversas aplicações de veículos autônomos, como na geração de mapas, desvio de obstáculos e tarefas de posicionamento. Além disso, o controle pode proporcionar um ganho significativo na confiabilidade, versatilidade e precisão das tarefas robóticas, questões cruciais na maioria das aplicações reais. O presente trabalho tem como objetivo principal apresentar a criação de um veículo autônomo em escala. Para tanto foi desenvolvido um sistema de função sensorial que provê informações sobre a posição e orientação do carro a partir de quatro sistemas sensoriais como GPS, acelerômetro, giroscópio e a bussola (IMU), para que o veículo autônomo possa realizar a rota corretamente, de forma eficiente e segura. Neste projeto foi desenvolvido um software que integra os sistemas de controle e de sensoriamento. Além disso, foi projetado um módulo que controla a posição e orientação do veículo. O robô antes de realizar a manobra calcula a distância mínima relacionada ao próximo ponto da coordenada planejada para trocar sua referência de trajetória satisfazendo a orientação do caminho e do veículo. Para fins de avaliação, foram realizados experimentos em ambientes reais onde o carro percorre um conjunto determinado de coordenadas geográficas sem nenhuma intervenção humana, apresentando resultados do seguimento de trajetórias proposto e validando os sistemas sensoriais, além do algoritmo de controle projetado / Abstract: As electronic and computational systems technology advances, the use of path control methods in navigation systems become very important for different autonomous vehicles applications such as generating maps, avoiding obstacles and carrying out positioning tasks. In addition, controls can help increase the reliability, versatility and precision level of programmed tasks, which is exceedingly significant regarding real applications. The first aim of this work is to present the creation of an autonomous scale vehicle. We have developed a sensor system that provides information about the vehicle's position and orientation through four sensor systems such as gps, accelerometer, gyroscope and compass so that it can effectively and safely cover the right route. This project developed a software, which integrates the control and sensors systems. In addition, a control module was projected for the positioning and orientation of the vehicle. Before the robot turns to any direction, it calculates the minimal distance to the next step of the programmed coordinate, in order to change its own referenced trajectory, satisfying the orientation of the trajectory and the vehicle. For the task validation were done experiments in real life scenarios, where the vehicle follows a determined group of geo-coordinates without any human intervention, presenting results of the purposed following trajectories, validating the sensors systems and the control algorithm / Mestrado / Mecanica dos Sólidos e Projeto Mecanico / Mestre em Engenharia Mecânica

Navegação de robôs móveis

Veículos autônomos

Rastreamento automático

Sistemas embarcados (Computadores)

Sistemas de veículos auto-guiados

Navigation mobile robot

Vehicles autonomous

Automatic tracking

Systems embedded computer

Systems self-guided vehicles

Bearing-only SLAM : a vision-based navigation system for autonomous robots

Huang, Henry

January 2008

To navigate successfully in a previously unexplored environment, a mobile robot must be able to estimate the spatial relationships of the objects of interest accurately. A Simultaneous Localization and Mapping (SLAM) sys- tem employs its sensors to build incrementally a map of its surroundings and to localize itself in the map simultaneously. The aim of this research project is to develop a SLAM system suitable for self propelled household lawnmowers. The proposed bearing-only SLAM system requires only an omnidirec- tional camera and some inexpensive landmarks. The main advantage of an omnidirectional camera is the panoramic view of all the landmarks in the scene. Placing landmarks in a lawn field to define the working domain is much easier and more flexible than installing the perimeter wire required by existing autonomous lawnmowers. The common approach of existing bearing-only SLAM methods relies on a motion model for predicting the robot’s pose and a sensor model for updating the pose. In the motion model, the error on the estimates of object positions is cumulated due mainly to the wheel slippage. Quantifying accu- rately the uncertainty of object positions is a fundamental requirement. In bearing-only SLAM, the Probability Density Function (PDF) of landmark position should be uniform along the observed bearing. Existing methods that approximate the PDF with a Gaussian estimation do not satisfy this uniformity requirement. This thesis introduces both geometric and proba- bilistic methods to address the above problems. The main novel contribu- tions of this thesis are: 1. A bearing-only SLAM method not requiring odometry. The proposed method relies solely on the sensor model (landmark bearings only) without relying on the motion model (odometry). The uncertainty of the estimated landmark positions depends on the vision error only, instead of the combination of both odometry and vision errors. 2. The transformation of the spatial uncertainty of objects. This thesis introduces a novel method for translating the spatial un- certainty of objects estimated from a moving frame attached to the robot into the global frame attached to the static landmarks in the environment. 3. The characterization of an improved PDF for representing landmark position in bearing-only SLAM. The proposed PDF is expressed in polar coordinates, and the marginal probability on range is constrained to be uniform. Compared to the PDF estimated from a mixture of Gaussians, the PDF developed here has far fewer parameters and can be easily adopted in a probabilistic framework, such as a particle filtering system. The main advantages of our proposed bearing-only SLAM system are its lower production cost and flexibility of use. The proposed system can be adopted in other domestic robots as well, such as vacuum cleaners or robotic toys when terrain is essentially 2D.

Co-design of architectures and algorithms for mobile robot localization and model-based detection of obstacles / Adéquation algorithme-architecture pour la localisation de robot mobile et la détection basée modèle d'obstacles

Törtei, Dániel

02 December 2016

Un véhicule autonome ou un robot mobile est équipé d'un système de navigation qui doit comporter plusieurs briques fonctionnelles pour traiter de perception, localisation, planification de trajectoires et locomotion. Dès que ce robot ou ce véhicule se déplace dans un environnement humain dense, il exécute en boucle et en temps réel plusieurs fonctions pour envoyer des consignes aux moteurs, pour calculer sa position vis-à-vis d'un repère de référence connu, et pour détecter de potentiels obstacles sur sa trajectoire; du fait de la richesse sémantique des images et du faible coût des caméras, ces fonctions exploitent souvent la vision. Les systèmes embarqués sur ces machines doivent alors intégrer des cartes assez puissantes pour traiter des données visuelles en temps réel. Par ailleurs, les contraintes d'autonomie de ces plateformes imposent de très faibles consommations énergétiques. Cette thèse proposent des architectures de type SOPC (System on Programmable Chip) conçues par une méthodologie de co-design matériel/logiciel pour exécuter de manière efficace les fonctions de localisation et de détection des obstacles à partir de la vision. Les résultats obtenus sont équivalents ou meilleurs que l'état de l'art, concernant la gestion de la carte locale d'amers pour l'odométrie-visuelle par une approche EKF-SLAM, et le rapport vitesse d'exécution sur précision pour ce qui est de la détection d'obstacles par identification dans les images d'objets (piétons, voitures...) sur la base de modèles appris au préalable. / An autonomous mobile platform is endowed with a navigational system which must contain multiple functional bricks: perception, localization, path planning and motion control. As soon as such a robot or vehicle moves in a crowded environment, it continously loops several tasks in real time: sending reference values to motors' actuators, calculating its position in respect to a known reference frame and detection of potential obstacles on its path. Thanks to semantic richness provided by images and to low cost of visual sensors, these tasks often exploit visual cues. Other embedded systems running on these mobile platforms thus demand for an additional integration of high-speed embeddable processing systems capable of treating abundant visual sensorial input in real-time. Moreover, constraints influencing the autonomy of the mobile platform impose low power consumption. This thesis proposes SOPC (System on a Programmable Chip) architectures for efficient embedding of vison-based localization and obstacle detection tasks in a navigational pipeline by making use of the software/hardware co-design methodology. The obtained results are equivalent or better in comparison to state-of-the-art for both EKF-SLAM based visual odometry: regarding the local map size management containing seven-dimensional landmarks and model-based detection-by-identification obstacle detection: algorithmic precision over execution speed metric.

Navigation du robot

SLAM visuel

Détection visuelle d'obstacles

Adéquation algorithme architecture

SoPC

Cartes embarquées hétérogenes

Robot navigation

Visual SLAM

Visual obstacle detection

Hw/sw co-design

SoPC

Heterogeneous embedded boards