Real-time WiFi localization of heterogeneous robot teams using an online random forest

Balaguer, Benjamin; Erinc, Gorkem; Carpin, Stefano

doi:10.1007/s10514-015-9432-5

Cited by 20 publications

(6 citation statements)

References 22 publications

(47 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Previous works using classification techniques include the usage of k-Nearest Neighbors [24,25], support vector machines [26,27], random forests [28], among others. While works using regression techniques include linear interpolation in graphs [29], smoothing functions [30], Gaussian Processes Regression (GPR) [12,31], among others.…”

Section: Introductionmentioning

confidence: 99%

Development of Magnetic-Based Navigation by Constructing Maps Using Machine Learning for Autonomous Mobile Robots in Real Environments

Takebayashi

Miyagusuku

Ozaki

2021

Sensors

View full text Add to dashboard Cite

Localization is fundamental to enable the use of autonomous mobile robots. In this work, we use magnetic-based localization. As Earth’s geomagnetic field is stable in time and is not affected by nonmagnetic materials, such as a large number of people in the robot’s surroundings, magnetic-based localization is ideal for service robotics in supermarkets, hotels, etc. A common approach for magnetic-based localization is to first create a magnetic map of the environment where the robot will be deployed. For this, magnetic samples acquired a priori are used. To generate this map, the collected data is interpolated by training a Gaussian Process Regression model. Gaussian processes are nonparametric, data-drive models, where the most important design choice is the selection of an adequate kernel function. These models are flexible and generate mean predictions as well as the confidence of those predictions, making them ideal for their use in probabilistic approaches. However, their computational and memory cost scales poorly when large datasets are used for training, making their use in large-scale environments challenging. The purpose of this study is to: (i) enable magnetic-based localization on large-scale environments by using a sparse representation of Gaussian processes, (ii) test the effect of several kernel functions on robot localization, and (iii) evaluate the accuracy of the approach experimentally on different large-scale environments.

show abstract

Section: Introductionmentioning

confidence: 99%

Development of Magnetic-Based Navigation by Constructing Maps Using Machine Learning for Autonomous Mobile Robots in Real Environments

Takebayashi

Miyagusuku

Ozaki

2021

Sensors

View full text Add to dashboard Cite

show abstract

“…for quadrotor in below-canopy environment is a rather complicated problem compared to navigating above the canopy or in urban area, e.g., in a complex forest environment, due to the unstructured below-canopy environments, occlusion of blades and different light intensity, the navigation capabilities of the quadrotor is limited and the effects of path planning and obstacle avoidance are also greatly affected [6]. These numerous uncertainties, complicated threats, dense and irregular obstacles, severe non-structural constraints and multi dynamic constraints have become a challenge [7]. A series of classical methods e.g.…”

Section: Introductionmentioning

confidence: 99%

A Variable-Step RRT^* Path Planning Algorithm for Quadrotors in Below-Canopy

Liu

Feng

et al. 2020

IEEE Access

View full text Add to dashboard Cite

Rapidly-exploring random tree (RRT * ) algorithm has been widely applied to path planning problem for quadrotor, which takes a great amount of static and dynamic constraints into account. However, conventional RRT * algorithm is suffering low convergence rate and efficiency in below-canopy environment, where is usually occupied with narrow aisles and uneven distributed obstacles. In order to enrich the forest information database and obtain information efficiently in blow-canopy, an improved variable-step RRT * algorithm has been proposed in this paper. In the proposed algorithm, the sampling nodes are determined by the target bias sampling strategy with variable probability. To further increase the efficiency of node generation and balance the searching time and security in areas with different obstacles densities, the eventtriggered step size extension has been proposed according to hyperbolic tangent function. After that, both Euclidean distance and angle constraints are adopted in the cost function of node connection optimization. Then, the path is further optimized by path trimming and Bezier curves smooth method. Finally, the demonstration of the proposed algorithm is presented to show its efficiency, and the comparison result with existing RRT-like algorithms indicates that the performance of our algorithm is better than RRT, RRT * and DDRRT in terms of convergence and accuracy. Comparing to other classical path planning methods such as A * , Artificial potential field and Fuzzy-logic, our method also shows its superiority.INDEX TERMS RRT * , Path planning, quadrotor, below-canopy environment, variable-step.

show abstract

“…An bluetooth-based accurate method is proposed for mobile robots and tested in Raghavan ( 2010 ). A WiFi-based solution is present to solve the localization problem for robots operating in unknown environments Benjamin ( 2015 ). Although the received signal strength indication (RSSI)-based technology can also be used for indoor localization, it commonly provides an insufficient accuracy.…”

Section: Introductionmentioning

confidence: 99%

Improving Accuracy of Mobile Robot Localization by Tightly Fusing LiDAR and DR data

Shmaliy

Shen

et al. 2020

Lecture Notes of the Institute for Computer Sciences, Social Informatics and Telecommunications Engineering

View full text Add to dashboard Cite

In this paper, a tightly-coupled light detection and ranging (LiDAR)/dead reckoning (DR) navigation system with uncertain sampling time is designed for mobile robot localization. The Kalman filter (KF) is used as the main data fusion filter, where the state vector is composed of the position error, velocity error, yaw, and sampling time. The observation is provided of the difference between the LiDAR-derived and DR-derived distances measured from the corner feature points (CFPs) to the mobile robot. A real test experiment has been conducted to verify a good performance of the proposed method and show that it allows for a higher accuracy compared to the traditional LiDAR/DR integration.

show abstract

Real-time WiFi localization of heterogeneous robot teams using an online random forest

Cited by 20 publications

References 22 publications

Development of Magnetic-Based Navigation by Constructing Maps Using Machine Learning for Autonomous Mobile Robots in Real Environments

Development of Magnetic-Based Navigation by Constructing Maps Using Machine Learning for Autonomous Mobile Robots in Real Environments

A Variable-Step RRT^* Path Planning Algorithm for Quadrotors in Below-Canopy

Improving Accuracy of Mobile Robot Localization by Tightly Fusing LiDAR and DR data

Contact Info

Product

Resources

About

Real-time WiFi localization of heterogeneous robot teams using an online random forest

Cited by 20 publications

References 22 publications

Development of Magnetic-Based Navigation by Constructing Maps Using Machine Learning for Autonomous Mobile Robots in Real Environments

Development of Magnetic-Based Navigation by Constructing Maps Using Machine Learning for Autonomous Mobile Robots in Real Environments

A Variable-Step RRT* Path Planning Algorithm for Quadrotors in Below-Canopy

Improving Accuracy of Mobile Robot Localization by Tightly Fusing LiDAR and DR data

Contact Info

Product

Resources

About

A Variable-Step RRT^* Path Planning Algorithm for Quadrotors in Below-Canopy