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Robust-adaptive-behavior strategy for human-following robots in unknown environments based on fuzzy inference mechanism

Toan Van Nguyen (Department of Electrical and Information Engineering, Seoul National University of Science and Technology, Seoul, Korea and Robotics R&D Center, Syscon, Incheon, Korea)
Minh Hoang Do (Robotics R&D Center, Syscon, Incheon, Korea)
Jaewon Jo (Robotics R&D Center, Syscon, Incheon, Korea)

Industrial Robot

ISSN: 0143-991X

Article publication date: 30 March 2022

Issue publication date: 20 September 2022

217

Abstract

Purpose

To follow and maintain an appropriate distance to the selected target person (STP), the mobile robot is required to have capabilities: the human detection and tracking and an efficient following strategy with a smooth manner that does not appear threatening to the STP and surroundings. The efficient following strategy must integrate the STP position and the obstacle information to achieve smooth and safe human-following behaviors, especially in unknown environments where robot does not have understandings in advance. The purpose of this study is to propose a robust-adaptive-behavior strategy for mobile robots.

Design/methodology/approach

This paper presents a robust-adaptive-behavior strategy (RABS) based on the fuzzy inference mechanism to help the robot follow the STP effectively in various unknown environments with the real-time obstacle avoidance, both indoor and outdoor and on different robot platforms. In which, the traversability of robots’ unknown surrounding environments is analyzed by using the STP position and the obstacle information obtained from the two dimensional laser scan, whose purpose is to choose the highest-traversability-score direction (HTSD) and an adaptive-safe-following distance (ASFD). Then, the HTSD, the ASFD and the current velocity of the robot are considered as inputs of the fuzzy system to adjust its velocity smoothly.

Findings

The proposed RABS is verified by a set of experiments using a real big-heavy autonomous mobile robot (BH-AMR), with the dimension 0.8 × 1.2 (m), weight 150 (kg), full-load 500 (kg), aiding smart factories. The obtained results have shown that the proposed RABS equips the BH-AMR with the ability to follow the STP smoothly and safely even when the robot is moving at the maximum speed 1.5 (m/s).

Research limitations/implications

In this paper, the autonomous mobile robot considers all environments as unknown even when it is working in mapped environments. This limitation is presented clearly in the future works section.

Practical implications

This proposed method can be used to help the autonomous mobile robot support persons in factories, hospitals, restaurants, supermarkets or at the airports.

Originality/value

This paper presents a RABS, including three new features: a fuzzy-based solution to help human-following robots maintain an appropriate distance to the STP safely and smoothly with the maximum velocity 1.5 (m/s); the proposed fuzzy-based solution, an adaptive vector field histogram and a new approach for the STP tracking is combined to follow the STP and avoid the collision simultaneously in unknown indoor and outdoor environments; the proposed RABS is considered for BH-AMRs (with the dimension 0.8 × 1.2 (m), weight 150 (kg), full-load 500 (kg)) to serve real tasks in smart factories.

Keywords

Acknowledgements

This research was financially supported by Syscon, Incheon, South Korea. In developments and experiments, Syscon supported working environments, autonomous mobile robot and also other equipments. And the authors are also gratefully appreciate their colleagues in Syscon for their cooperation in this research.

Availability of data and material: Demo video was sent to the journal as a part of this submission.

Citation

Nguyen, T.V., Do, M.H. and Jo, J. (2022), "Robust-adaptive-behavior strategy for human-following robots in unknown environments based on fuzzy inference mechanism", Industrial Robot, Vol. 49 No. 6, pp. 1089-1100. https://doi.org/10.1108/IR-01-2022-0009

Publisher

:

Emerald Publishing Limited

Copyright © 2022, Emerald Publishing Limited

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