Path Following for Autonomous Mobile Robots with Deep Reinforcement Learning

Cao, Yu; Ni, Kan; Kawaguchi, Takahiro; Hashimoto, Seiji

doi:10.3390/s24020561

Sensors

2024

DOI: 10.3390/s24020561

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Path Following for Autonomous Mobile Robots with Deep Reinforcement Learning

Yu Cao,

Kan Ni,

Takahiro Kawaguchi

et al.

Abstract: Autonomous mobile robots have become integral to daily life, providing crucial services across diverse domains. This paper focuses on path following, a fundamental technology and critical element in achieving autonomous mobility. Existing methods predominantly address tracking through steering control, neglecting velocity control or relying on path-specific reference velocities, thereby constraining their generality. In this paper, we propose a novel approach that integrates the conventional pure pursuit algor… Show more

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2024

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Cited by 4 publications

References 38 publications

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Research on trajectory tracking of wheeled mobile robots using fuzzy PID based on TD3

Wang,

Deng,

Zhang

et al. 2024

J. Phys.: Conf. Ser.

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This study addresses the issues and limitations of trajectory tracking for Non-holonomic wheeled mobile robot (NWMR) under traditional PID control, including low accuracy, high response delay, poor robustness, and stability concerns. We propose a strategy that combines the Twin Delayed Deep Deterministic Policy Gradient (TD3) algorithm with fuzzy PID control to optimize PID parameter tuning for more precise robot trajectory tracking. Fuzzy logic is introduced to adjust the PID controller parameters, making them more adaptive and robust. The bidirectional long short-term memory (BiLSTM) network enhances the time series processing capability of the Actor-Critic network, improving the system’s state representation and prediction abilities. A curiosity-driven exploration method is employed to increase policy diversity and avoid premature convergence. Simulation experiments using the ROS Noetic and Gazebo platforms demonstrate that this method significantly outperforms traditional PID and TD3 algorithms in terms of trajectory alignment, training time, accuracy, and stability.

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Research on trajectory tracking of wheeled mobile robots using fuzzy PID based on TD3

Wang,

Deng,

Zhang

et al. 2024

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

show abstract

Trajectory Tracking Control of Mobile Manipulator Based on Improved Sliding Mode Control Algorithm

Cui,

Song,

Zheng

et al. 2024

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Research on trajectory tracking control for climbing welding robots holds significant importance in the field of automated welding. However, existing trajectory tracking methods suffer from issues such as jitter and slow speed. In this paper, an improved sliding mode control strategy is proposed based on the self-designed wall-climbing welding mobile manipulator. Firstly, a new adaptive sliding mode control strategy is proposed for the mobile platform based on the kinematic model. By introducing a new approach law, the controller is designed when the distance between the center of mass is unknown. Secondly, regarding the manipulator, we analyze simplified dynamic equations, extract uncertain components, and utilize a CNN for compensation. This compensation strategy is integrated into the sliding mode control law, achieving precise control over the manipulator and effectively resolving issues like slow tracking speeds, large errors, and chattering. The stability of the robot control system is proved by the Lyapunov function. Through simulation analysis and experimental validation, the proposed control method is confirmed to be feasible and superior.

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Design, Construction, and Validation of an Experimental Electric Vehicle with Trajectory Tracking

Morales Viscaya,

Barranco Gutiérrez,

González Gómez

2024

Sensors

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This research presents an experimental electric vehicle developed at the Tecnológico Nacional de México Celaya campus. It was decided to use a golf cart-type gasoline vehicle as a starting point. Initially, the body was removed, and the vehicle was electrified, meaning its engine was replaced with an electric one. Subsequently, sensors used to measure the vehicle states were placed, calibrated, and instrumented. Additionally, a mathematical model was developed along with a strategy for the parametric identification of this model. A communication scheme was implemented consisting of four slave devices responsible for controlling the accelerator, brake, steering wheel, and measuring the sensors related to odometry. The master device is responsible for communicating with the slaves, displaying information on a screen, creating a log, and implementing trajectory tracking techniques based on classical, geometric, and predictive control. Finally, the performance of the control algorithms implemented on the experimental prototype was compared in terms of tracking error and control input across three different types of trajectories: lane change, right-angle curve, and U-turn.

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Path Following for Autonomous Mobile Robots with Deep Reinforcement Learning

Cited by 4 publications

References 38 publications

Research on trajectory tracking of wheeled mobile robots using fuzzy PID based on TD3

Research on trajectory tracking of wheeled mobile robots using fuzzy PID based on TD3

Trajectory Tracking Control of Mobile Manipulator Based on Improved Sliding Mode Control Algorithm

Design, Construction, and Validation of an Experimental Electric Vehicle with Trajectory Tracking

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