Grasp Posture Control of Wearable Extra Robotic Fingers with Flex Sensors Based on Neural Network

Joga Dharma Setiawan,Wahyu Caesarendra,Muhammad Mutoha,Adam Glowacz,M Munadi,Mochammad Ariyanto

doi:10.3390/electronics9060905

Joga Dharma Setiawan, Wahyu Caesarendra + Show 4 more

Open Access

https://doi.org/10.3390/electronics9060905

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Journal: Electronics	Publication Date: May 29, 2020
Citations: 15	License type: CC BY 4.0

Affiliation: Diponegoro University, Universiti Brunei Darussalam

Abstract

This study proposes a data-driven control method of extra robotic fingers to assist a user in bimanual object manipulation that requires two hands. The robotic system comprises two main parts, i.e., robotic thumb (RT) and robotic fingers (RF). The RT is attached next to the user’s thumb, while the RF is located next to the user’s little finger. The grasp postures of the RT and RF are driven by bending angle inputs of flex sensors, attached to the thumb and other fingers of the user. A modified glove sensor is developed by attaching three flex sensors to the thumb, index, and middle fingers of a wearer. Various hand gestures are then mapped using a neural network. The input data of the robotic system are the bending angles of thumb and index, read by flex sensors, and the outputs are commanded servo angles for the RF and RT. The third flex sensor is attached to the middle finger to hold the extra robotic finger’s posture. Two force-sensitive resistors (FSRs) are attached to the RF and RT for the haptic feedback when the robot is worn to take and grasp a fragile object, such as an egg. The trained neural network is embedded into the wearable extra robotic fingers to control the robotic motion and assist the human fingers in bimanual object manipulation tasks. The developed extra fingers are tested for their capacity to assist the human fingers and perform 10 different bimanual tasks, such as holding a large object, lifting and operate an eight-inch tablet, and lifting a bottle, and opening a bottle cap at the same time.

Highlights

The use of robotic arms is typically common in manufacturing and service operations [1,2].The current research is more focused on robots that can be worn due to the growing demand for them.The most widely known of these types of robots are prosthesis and exoskeleton robots
InIn this study, a wearable extra robotic finger is successfully developed to assist bimanual tasks that are commonly performed by two normal healthy hands
A data-driven method based on neural that are commonly performed by two normal healthy hands

Summary

Introduction

The use of robotic arms is typically common in manufacturing and service operations [1,2].The current research is more focused on robots that can be worn due to the growing demand for them.The most widely known of these types of robots are prosthesis and exoskeleton robots. The current research is more focused on robots that can be worn due to the growing demand for them. A prosthesis is used to replace the lost limbs of humans due to accidents or birth defects. Many researchers around the world have developed myoelectric prosthetic hands to replace and add upper limbs, [3,4,5,6,7,8,9,10,11], and ankle/foot prosthesis for the lower limb [12,13,14]. The researchers in Italy strive to replicate the human hand as closely as possible, Electronics 2020, 9, 905; doi:10.3390/electronics9060905 www.mdpi.com/journal/electronics

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