Probabilistic Approach to Robot Motion Planning in Dynamic Environments

Mohanan, M. G.; Salgaonkar, Ambuja

doi:10.1007/s42979-020-00185-0

Cited by 10 publications

(4 citation statements)

References 45 publications

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“…Thus, the hyperprameters are currently determined with the aim to maximize the trajectory length. In future investigations, however, the hyperparameters will be optimized regarding the multi-objectives trajectory length, smoothness of the trajectory, and computational requirements like memory and execution time by developing a method for estimating the parameters automatically, e.g., via a Kalman filter [55]-based algorithm like in this example on robot motion planning [33], so that less experts knowledge have to be provided. Classical approaches like grid search or gradient-based approaches would require a ground truth to Considering the presented results, the introduced framework can reconstruct trajectories from both, guided and Brownian motion systems, even under high particle densities.…”

Section: Discussionmentioning

confidence: 99%

A Probabilistic Particle Tracking Framework for Guided and Brownian Motion Systems with High Particle Densities

et al. 2021

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This paper presents a new framework for particle tracking based on a Gaussian Mixture Model (GMM). It is an extension of the state-of-the-art iterative reconstruction of individual particles by a continuous modeling of the particle trajectories considering the position and velocity as coupled quantities. The proposed approach includes an initialization and a processing step. In the first step, the velocities at the initial points are determined after iterative reconstruction of individual particles of the first four images to be able to generate the tracks between these initial points. From there on, the tracks are extended in the processing step by searching for and including new points obtained from consecutive images based on continuous modeling of the particle trajectories with a Gaussian Mixture Model. The presented tracking procedure allows to extend existing trajectories interactively with low computing effort and to store them in a compact representation using little memory space. To demonstrate the performance and the functionality of this new particle tracking approach, it is successfully applied to a synthetic turbulent pipe flow, to the problem of observing particles corresponding to a Brownian motion (e.g., motion of cells), as well as to problems where the motion is guided by boundary forces, e.g., in the case of particle tracking velocimetry of turbulent Rayleigh–Bénard convection.

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Section: Discussionmentioning

confidence: 99%

A Probabilistic Particle Tracking Framework for Guided and Brownian Motion Systems with High Particle Densities

et al. 2021

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“…The links have an ordered structure in which each link has its own coordinate system, and is positioned relative to the coordinate system of the previous link. The position of the link i in the coordinate system of its ancestor is obtained by computing the joint angle [34,[36][37][38][39][40][41][42][43].…”

Section: Kinematics For Robotic Hand Motionmentioning

confidence: 99%

Robotic Mushroom Harvesting by Employing Probabilistic Road Map and Inverse Kinematics

Mohanan¹,

Ambuja²

2021

BIJIAM

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A collision-free path to a destination position in a random farm is determined using a probabilistic roadmap (PRM) that can manage static and dynamic obstacles. The position of ripening mushrooms is a result of picture processing. A mushroom harvesting robot is explored that uses inverse kinematics (IK) at the target position to compute the state of a robotic hand for grasping a ripening mushroom and plucking it. The Denavit-Hartenberg approach was used to create a kinematic model of a two-finger dexterous hand with three degrees of freedom for mushroom picking. Unlike prior experiments in mushroom harvesting, mushrooms are not planted in a grid or design, but are randomly scattered. At any point throughout the harvesting process, no human interaction is necessary.

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“…The robot is designed to locate the most efficient path for harvesting ripe mushrooms from a field of plants planted at random. In addition, the applications of the biologically motivated meta-heuristic algorithms firefly algorithm (FA) and ant colony optimization (ACO) [8] have been researched and evaluated. An in-depth analysis and critical examination of the important contributions to path planning in dynamic contexts is conducted in [9].…”

Section: Introductionmentioning

confidence: 99%

Bayesian probabilistic modeling in robosoccer environment for robot path planning

Steffi,

Mehta,

Venkatesh

2024

Bulletin EEI

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The main goal of a route planning approach is to find a trajectory that safely transports the robot from one site to the next. Furthermore, it should provide an energy-efficient path so the computer can calculate it rapidly. This study develops a path-planning system for robots to approach the ball without collision. The Bayesian optimization algorithm (BOA) is used to identify the shortest path between the robot and the ball. BOA employs a probabilistic model to seek the optimum of an uncertain objective function efficiently. The performance of the BOA-based path planning system is compared to other optimization algorithms such as genetic algorithm, ant colony optimization, and firefly algorithm. BOA’s acquisition functions such as expected improvement, probability of improvement (PI), and upper confidence bound, are investigated. The exact locations of the robots and the ball are fed into optimization problems to discover the optimum path. The results reveal that the BOA system outperforms other systems in terms of computational time for planning the optimum path in dynamic situations and BOA-PI is the fastest algorithm.

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Probabilistic Approach to Robot Motion Planning in Dynamic Environments

Cited by 10 publications

References 45 publications

A Probabilistic Particle Tracking Framework for Guided and Brownian Motion Systems with High Particle Densities

A Probabilistic Particle Tracking Framework for Guided and Brownian Motion Systems with High Particle Densities

Robotic Mushroom Harvesting by Employing Probabilistic Road Map and Inverse Kinematics

Bayesian probabilistic modeling in robosoccer environment for robot path planning

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