A Survey of Machine Learning Approaches for Mobile Robot Control

Rybczak, Monika; Popowniak, Natalia; Lazarowska, Agnieszka

doi:10.3390/robotics13010012

Cited by 3 publications

(1 citation statement)

References 103 publications

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“…The model size was reduced by 40% through quantization and an additional 20% through structured pruning in hardware implementation. Normally, quantization is a common machine-learning technique to reduce model size [24]. On the other hand, pruning is a machine-learning technique that decreases the size of complex models by eliminating some of their parameters to make them run faster on hardware [25].…”

Section: Fall Detection Capabilitymentioning

confidence: 99%

New Eldercare Robot with Path-Planning and Fall-Detection Capabilities

Elwaly,

Abdellatif,

El-Shaer

2024

Applied Sciences

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The rapid growth of the elderly population has led to an increased demand for effective and personalized eldercare solutions. In this paper, the design and development of an eldercare robot is presented. This robot is specifically tailored to meet the two specific challenges faced by the elderly. The first is the continuous indoor tracking of the elder, while the second is the fall detection. A comprehensive overview of the hardware and software components, as well as the control architecture of the robot is presented. The hardware design of the robot incorporates a range of features, including a perception system comprising a 2D Lidar, IMU, and camera for environment mapping, localization, and fall detection. The software stack of the robot is explained as consisting of layers for perception, mapping, and localization. The robot is tested experimentally to validate its path planning capability by using Hector SLAM and the RRT* technique. Experimental path planning has shown a positioning accuracy of 93.8% on average. Elderly fall detection is achieved by using the YOLOv7 algorithm at a percentage of 96%. Experimental results have been discussed and evaluated.

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Section: Fall Detection Capabilitymentioning

confidence: 99%

New Eldercare Robot with Path-Planning and Fall-Detection Capabilities

Elwaly,

Abdellatif,

El-Shaer

2024

Applied Sciences

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Belief Revision for Physical Robots: Opportunities and Challenges

Hunter,

Daon

2024

2024 IEEE Canadian Conference on Electrical and Computer Engineering (CCECE)

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Study of Human–Robot Interactions for Assistive Robots Using Machine Learning and Sensor Fusion Technologies

Raj,

Kos

2024

Electronics

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In recent decades, the potential of robots’ understanding, perception, learning, and action has been widely expanded due to the integration of artificial intelligence (AI) into almost every system. Cooperation between AI and human beings will be responsible for the bright future of AI technology. Moreover, for a perfect manually or automatically controlled machine or device, the device must perform together with a human through multiple levels of automation and assistance. Humans and robots cooperate or interact in various ways. With the enhancement of robot efficiencies, they can perform more work through an automatic method; therefore, we need to think about cooperation between humans and robots, the required software architectures, and information about the designs of user interfaces. This paper describes the most important strategies of human–robot interactions and the relationships between several control techniques and cooperation techniques using sensor fusion and machine learning (ML). Based on the behavior and thinking of humans, a human–robot interaction (HRI) framework is studied and explored in this article to make attractive, safe, and efficient systems. Additionally, research on intention recognition, compliance control, and perception of the environment by elderly assistive robots for the optimization of HRI is investigated in this paper. Furthermore, we describe the theory of HRI and explain the different kinds of interactions and required details for both humans and robots to perform different kinds of interactions, including the circumstances-based evaluation technique, which is the most important criterion for assistive robots.

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A Survey of Machine Learning Approaches for Mobile Robot Control

Cited by 3 publications

References 103 publications

New Eldercare Robot with Path-Planning and Fall-Detection Capabilities

New Eldercare Robot with Path-Planning and Fall-Detection Capabilities

Belief Revision for Physical Robots: Opportunities and Challenges

Study of Human–Robot Interactions for Assistive Robots Using Machine Learning and Sensor Fusion Technologies

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