A Decorrelated Distributed EKF-SLAM System for the Autonomous Navigation of Mobile Robots

Some autonomous navigation methods, when implemented alone, can lead to poor performance, whereas their combinations, when well thought out, can yield exceptional performances. We have demonstrated this by combining the artificial potential field and fuzzy logic methods in the framework of mobile robots’ autonomous navigation. In this article, we investigate a possible combination of three methods widely used in the autonomous navigation of mobile robots, and whose individual implementation still does not yield the expected performances. These are as follows: the artificial potential field, which is quick and easy to implement but faces local minima and robustness problems. Fuzzy logic is robust but computationally intensive. Finally, neural networks have an exceptional generalization capacity, but face data collection problems for the learning base and robustness. This article aims to exploit the advantages offered by each of these approaches to design a robust, intelligent, and computationally efficient controller. The combination of the artificial potential field and interval type-2 fuzzy logic resulted in an interval type-2 fuzzy logic controller whose advantage over the classical interval type-2 fuzzy logic controller was the small size of the rule base. However, it kept all the classical interval type-2 fuzzy logic controller characteristics, with the major disadvantage that type-reduction remains the main cause of high computation time. In this article, the type-reduction process is replaced with two layers of neural networks. The resulting controller is an interval type-2 fuzzy neural network controller with the artificial potential field controller’s outputs as auxiliary inputs. The results obtained by performing a series of experiments on a mobile platform demonstrate the proposed navigation system’s efficiency.

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A Bionic Spatial Cognition Model and Method for Robots Based on the Hippocampus Mechanism

Frontiers in Neurorobotics ◽

10.3389/fnbot.2021.769829 ◽

2022 ◽

Vol 15 ◽

Author(s):

Jinsheng Yuan ◽

Wei Guo ◽

Fusheng Zha ◽

Pengfei Wang ◽

Mantian Li ◽

...

Keyword(s):

Mobile Robots ◽

Spatial Cognition ◽

Calculation Method ◽

Autonomous Navigation ◽

Path Integration ◽

Motion Information ◽

Robot Perception ◽

Environmental Cognition ◽

Biological Principle ◽

Cognition Model

The hippocampus and its accessory are the main areas for spatial cognition. It can integrate paths and form environmental cognition based on motion information and then realize positioning and navigation. Learning from the hippocampus mechanism is a crucial way forward for research in robot perception, so it is crucial to building a calculation method that conforms to the biological principle. In addition, it should be easy to implement on a robot. This paper proposes a bionic cognition model and method for mobile robots, which can realize precise path integration and cognition of space. Our research can provide the basis for the cognition of the environment and autonomous navigation for bionic robots.

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Autonomous and Safe Navigation of Mobile Robots in Vineyard with Smooth Collision Avoidance

Agriculture ◽

10.3390/agriculture11100954 ◽

2021 ◽

Vol 11 (10) ◽

pp. 954

Author(s):

Abhijeet Ravankar ◽

Ankit A. Ravankar ◽

Arpit Rawankar ◽

Yohei Hoshino

Keyword(s):

Mobile Robots ◽

Real Time ◽

Collision Avoidance ◽

Autonomous Navigation ◽

Autonomous Robots ◽

Robot Navigation ◽

Indoor Environments ◽

Safe Distance ◽

Field Robots ◽

Safe Navigation

In recent years, autonomous robots have extensively been used to automate several vineyard tasks. Autonomous navigation is an indispensable component of such field robots. Autonomous and safe navigation has been well studied in indoor environments and many algorithms have been proposed. However, unlike structured indoor environments, vineyards pose special challenges for robot navigation. Particularly, safe robot navigation is crucial to avoid damaging the grapes. In this regard, we propose an algorithm that enables autonomous and safe robot navigation in vineyards. The proposed algorithm relies on data from a Lidar sensor and does not require a GPS. In addition, the proposed algorithm can avoid dynamic obstacles in the vineyard while smoothing the robot’s trajectories. The curvature of the trajectories can be controlled, keeping a safe distance from both the crop and the dynamic obstacles. We have tested the algorithm in both a simulation and with robots in an actual vineyard. The results show that the robot can safely navigate the lanes of the vineyard and smoothly avoid dynamic obstacles such as moving people without abruptly stopping or executing sharp turns. The algorithm performs in real-time and can easily be integrated into robots deployed in vineyards.

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Navigation of a wheeled mobile robotic agent using modified grey wolf optimization controller

International Journal of Intelligent Unmanned Systems ◽

10.1108/ijius-06-2020-0023 ◽

2021 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Chittaranjan Paital ◽

Saroj Kumar ◽

Manoj Kumar Muni ◽

Dayal R. Parhi ◽

Prasant Ranjan Dhal

Keyword(s):

Path Planning ◽

Mobile Robot ◽

Mobile Robots ◽

Real Time ◽

Autonomous Navigation ◽

Simulation Software ◽

Grey Wolf ◽

Grey Wolf Optimization ◽

Content Type ◽

Cluttered Environment

PurposeSmooth and autonomous navigation of mobile robot in a cluttered environment is the main purpose of proposed technique. That includes localization and path planning of mobile robot. These are important aspects of the mobile robot during autonomous navigation in any workspace. Navigation of mobile robots includes reaching the target from the start point by avoiding obstacles in a static or dynamic environment. Several techniques have already been proposed by the researchers concerning navigational problems of the mobile robot still no one confirms the navigating path is optimal.Design/methodology/approachTherefore, the modified grey wolf optimization (GWO) controller is designed for autonomous navigation, which is one of the intelligent techniques for autonomous navigation of wheeled mobile robot (WMR). GWO is a nature-inspired algorithm, which mainly mimics the social hierarchy and hunting behavior of wolf in nature. It is modified to define the optimal positions and better control over the robot. The motion from the source to target in the highly cluttered environment by negotiating obstacles. The controller is authenticated by the approach of V-REP simulation software platform coupled with real-time experiment in the laboratory by using Khepera-III robot.FindingsDuring experiments, it is observed that the proposed technique is much efficient in motion control and path planning as the robot reaches its target position without any collision during its movement. Further the simulation through V-REP and real-time experimental results are recorded and compared against each corresponding results, and it can be seen that the results have good agreement as the deviation in the results is approximately 5% which is an acceptable range of deviation in motion planning. Both the results such as path length and time taken to reach the target is recorded and shown in respective tables.Originality/valueAfter literature survey, it may be said that most of the approach is implemented on either mathematical convergence or in mobile robot, but real-time experimental authentication is not obtained. With a lack of clear evidence regarding use of MGWO (modified grey wolf optimization) controller for navigation of mobile robots in both the environment, such as in simulation platform and real-time experimental platforms, this work would serve as a guiding link for use of similar approaches in other forms of robots.

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Autonomous Navigation of Mobile Robots in Vineyard

The Proceedings of JSME annual Conference on Robotics and Mechatronics (Robomec) ◽

10.1299/jsmermd.2021.1p2-a15 ◽

2021 ◽

Vol 2021 (0) ◽

pp. 1P2-A15

Author(s):

Abhijeet RAVANKAR ◽

Ankit A. RAVANKAR ◽

Yohei HOSHINO

Keyword(s):

Mobile Robots ◽

Autonomous Navigation

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Optimal trajectories generation for autonomous navigation tasks in mobile robots

2018 15th International Conference on Electrical Engineering, Computing Science and Automatic Control (CCE) ◽

10.1109/iceee.2018.8533936 ◽

2018 ◽

Author(s):

Viridiana Y. Hernandez Marquez ◽

Rafael S. Nunez Cruz ◽

Juan M. Ibarra Zannatha ◽

Carlos Enriquez Ramirez

Keyword(s):

Mobile Robots ◽

Autonomous Navigation ◽

Optimal Trajectories

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Robustness and Controllability Analysis for Autonomous Navigation of Two-Wheeled Mobile Robots

Volume 8: 31st Mechanisms and Robotics Conference, Parts A and B ◽

10.1115/detc2007-35415 ◽

2007 ◽

Author(s):

Alessio Salerno ◽

Jorge Angeles

Keyword(s):

Mobile Robots ◽

Autonomous Navigation ◽

Autonomous Robots ◽

Upper Bounds ◽

Small Time ◽

Dynamics Model ◽

Wheeled Mobile Robots ◽

Rank Condition ◽

Dynamics Response ◽

Kalman Rank Condition

This work deals with the robustness and controllability analysis for autonomous navigation of two-wheeled mobile robots. The analysis of controllability of the systems at hand is conducted using both the Kalman rank condition for controllability and the Lie Algebra rank condition. We show that the robots targeted in this work can be controlled using a model for autonomous navigation by means of their dynamics model: kinematics will not be sufficient to completely control these underactuated systems. After having proven that these autonomous robots are small-time locally controllable from every equilibrium point and locally accessible from the remaining points, the uncertainty is modeled resorting to a multiplicative approach. The dynamics response of these robots is analyzed in the frequency domain. Upper bounds for the complex uncertainty are established.

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A hand-drawn map-based navigation method for mobile robots using objectness measure

International Journal of Advanced Robotic Systems ◽

10.1177/1729881419846339 ◽

2019 ◽

Vol 16 (3) ◽

pp. 172988141984633 ◽

Cited By ~ 1

Author(s):

Jie Niu ◽

Kun Qian

Keyword(s):

Mobile Robots ◽

Autonomous Navigation ◽

Saliency Map ◽

Experimental Results ◽

Environment Map ◽

Environmental Cognition ◽

Candidate Regions ◽

Cognitive Environment ◽

Candidate Object ◽

Navigation Method

Correct cognition of the environment is the premise of mobile robots to realize autonomous navigation control tasks. The inconsistency caused by time-varying environmental information is a bottleneck for the development and application of cognitive environment technologies. In this article, we propose an environmental cognition method that uses a hand-drawn map. Firstly, we use the single skeleton refinement and fuzzy c-means algorithms to segment the image. Then, we select candidate regions combining the saliency map. At the same time, we use the superpixels straddling method to filter the windows. The final candidate object regions are obtained based on a fusion of saliency segmentation and superpixels clustering. Based on the above objectness estimation results, we use a human–computer interaction method to construct an inaccurate hand-drawn environment map for navigation. The experimental results from PASCAL VOC2007 validate the efficacy of the proposed objectness measure method, where our result of 41.2% on mean average precision is the best of the tested methods. Furthermore, the experimental results of robot navigation in the actual scene also verified the effectiveness of the proposed approach.

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