Trajectory Planning for a Mobile Robot in a Dynamic Environment Using an LSTM Neural Network

Molina-Leal, Alejandra; Gómez-Espinosa, Alfonso; Cabello, Jesús Arturo Escobedo; Cuan-Urquizo, Enrique; Cruz-Ramírez, Sergio Rolando

doi:10.3390/app112210689

Cited by 10 publications

(9 citation statements)

References 35 publications

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“…The concept of robot operating system (ROS) navigation planners provides a detailed framework that can integrate different types of algorithms and sensors to develop complex robotics applications [ 112 ]. Emerging solutions have utilised neural networks (NNs) to optimise traditional path planning and obstacle avoidance techniques in recent times [ 43 , 113 ]. A neural network is a layered framework of interconnected nodes that takes input based on a designed task and produces network prediction or classification as output.…”

Section: Learning-based Navigation Techniques (Methods)mentioning

confidence: 99%

“…A neural network is a layered framework of interconnected nodes that takes input based on a designed task and produces network prediction or classification as output. The authors [ 113 ] applied a long short-term memory (LSTM) neural network using robot pose and agent to obstacle distance as the input to solve end-to-end path planning while avoiding a dynamic obstacle. Other authors applied multilayer perceptron (MLP) network classic path planning algorithms to demonstrate improved performance [ 114 ].…”

Section: Learning-based Navigation Techniques (Methods)mentioning

confidence: 99%

“…Most obstacle detection, avoidance, and path planning solutions are unstable and must be robust to be applicable in real-world scenarios. These systems rely on various parameters, and finding suitable configurations is difficult and results in unpredictable performance [ 113 ]. This can be exacerbated when dealing with limited training data.…”

Section: Drawbacks and Future Workmentioning

confidence: 99%

See 2 more Smart Citations

Advancements in Learning-Based Navigation Systems for Robotic Applications in MRO Hangar: Review

Adiuku,

Avdelidis,

Tang

et al. 2024

Sensors

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The field of learning-based navigation for mobile robots is experiencing a surge of interest from research and industry sectors. The application of this technology for visual aircraft inspection tasks within a maintenance, repair, and overhaul (MRO) hangar necessitates efficient perception and obstacle avoidance capabilities to ensure a reliable navigation experience. The present reliance on manual labour, static processes, and outdated technologies limits operation efficiency in the inherently dynamic and increasingly complex nature of the real-world hangar environment. The challenging environment limits the practical application of conventional methods and real-time adaptability to changes. In response to these challenges, recent years research efforts have witnessed advancement with machine learning integration aimed at enhancing navigational capability in both static and dynamic scenarios. However, most of these studies have not been specific to the MRO hangar environment, but related challenges have been addressed, and applicable solutions have been developed. This paper provides a comprehensive review of learning-based strategies with an emphasis on advancements in deep learning, object detection, and the integration of multiple approaches to create hybrid systems. The review delineates the application of learning-based methodologies to real-time navigational tasks, encompassing environment perception, obstacle detection, avoidance, and path planning through the use of vision-based sensors. The concluding section addresses the prevailing challenges and prospective development directions in this domain.

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Section: Learning-based Navigation Techniques (Methods)mentioning

confidence: 99%

Section: Learning-based Navigation Techniques (Methods)mentioning

confidence: 99%

Section: Drawbacks and Future Workmentioning

confidence: 99%

See 1 more Smart Citation

Advancements in Learning-Based Navigation Systems for Robotic Applications in MRO Hangar: Review

Adiuku,

Avdelidis,

Tang

et al. 2024

Sensors

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show abstract

“…Long 19 presented a multi‐scenario multi‐stage framework to learn a policy, which can achieve a sensor‐level collision avoidance. Molina‐Leal 20 adopted a long short‐term memory network to allow the robot to reach the goal without colliding with dynamic obstacles. Zhelo 21 adopted the asynchronous advantage actor‐critic (A3C) algorithm for mapless navigation with the sum of the external reward and the curiosity reward.…”

Section: Related Workmentioning

confidence: 99%

Path planning for multiple agents in an unknown environment using soft actor critic and curriculum learning

Sun

Yan

Qin

2022

Computer Animation & Virtual

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Path planning can guarantee that agents reach their goals without colliding with obstacles and other agents in an optimal way and it is a very important component in the research of crowd simulation. In this article, we propose a novel path planning approach for multiple agents which combines soft actor critic (SAC) algorithm and curriculum learning to solve the problems of single policy, slow convergence of the policy in an unknown environment with sparse rewards. The path planning task is set as lessons from easy to difficult, and the neural network of the SAC algorithm is arranged to learn in sequence, and finally the neural network can be fully competent for the path planning task. We also stack the state information to address the problems caused by limited observation for policy learning, and design a comprehensive reward function to make agents reach their goals successfully and avoid collisions with static obstacles and other agents. The experimental results demonstrate that our approach can plan smooth and natural paths for multiple agents, and furthermore, our model has a certain generalization ability and a better adaptability to the changes in a dynamic environment.

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“…The ability to navigate through a given environment is considered to be one of the most desirable characteristics of autonomous robots [5], [8]- [11]. Path planning is a method for an autonomous robot to get from the beginning point to the goal while traversing an environment that includes both static and dynamic obstacles [12], [13]. It is possible to divide path planning into global and local planning, depending on the scope of the map [8], [14]- [20].…”

Section: Introductionmentioning

confidence: 99%

Optimization of an Autonomous Mobile Robot Path Planning Based on Improved Genetic Algorithms

Abu,

Bukhari,

Adli

et al. 2023

Journal of Robotics and Control

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Mobile robots are intended to operate in a variety of environments, and they need to be able to navigate and travel around obstacles, such as objects and barriers. In order to guarantee that the robot will not come into contact with any obstacles or other objects during its movement, algorithms for path planning have been demonstrated. The basic goal while constructing a route is to find the fastest and smoothest route between the starting point and the destination. This article describes route planning using the improvised genetic algorithm with the Bezier Curve (GA-BZ). This study carried out two main experiments, each using a 20x20 random grid map model with varying percentages of obstacles (5%, 15%, and 30% in the first experiment, and 25% and 50% in the second). In the initial experiments, the population (PN), generation (GN), and mutation rate (MR) of genetic algorithms (GA) will be altered to the following values: (PN = 100, 125, 150, or 200; GN = 100, 125, 150; and MR = 0.1, 0.3, 0.5, 0.7) respectively. The goal is to evaluate the effectiveness of AMR in terms of travel distance (m), total time (s), and total cost (RM) in comparison to traditional GA and GA-BZ. The second experiment examined robot performance utilising GA, GA-BZ, Simulated Annealing (SA), A-Star (A*), and Dijkstra's Algorithms (DA) for path distance (m), time travel (s), and fare trip (RM). The simulation results are analysed, compared, and explained. In conclusion, the project is summarised.

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Trajectory Planning for a Mobile Robot in a Dynamic Environment Using an LSTM Neural Network

Cited by 10 publications

References 35 publications

Advancements in Learning-Based Navigation Systems for Robotic Applications in MRO Hangar: Review

Advancements in Learning-Based Navigation Systems for Robotic Applications in MRO Hangar: Review

Path planning for multiple agents in an unknown environment using soft actor critic and curriculum learning

Optimization of an Autonomous Mobile Robot Path Planning Based on Improved Genetic Algorithms

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