Shahrooz Shahin scite author profile

This paper proposes a bioinspired adaptive anchoring module that can be integrated into robots to enhance their mobility and manipulation abilities. The design of the module is inspired by the structure of the mouth in Chilean lamprey (Mordacia lapicida) where a combination of suction and several arrays of teeth with different sizes around the mouth opening is used for catching preys and anchoring onto them. The module can deploy a suitable mode of attachment, via teeth or vacuum suction, to different contact surfaces in response to the textural properties of those surfaces. In order to make a decision on the suitable mode of attachment, an original dataset of 500 images of outdoor and indoor surfaces was used to train a visual surface examination model using YOLOv3; a virtually real-time object detection algorithm. The mean average precision of the trained model was calculated to be 91%. We have conducted a series of pull-out tests to characterize the module's strength of attachments. The results of the experiments indicate that the anchoring module can withstand an applied detachment force of up to 70N and 30N when attached using teeth and vacuum suction, respectively.

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Faster R-CNN-based Decision Making in a Novel Adaptive Dual-Mode Robotic Anchoring System

Shahin

Sadeghian

Sareh

2021

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This paper proposes a novel adaptive anchoring module that can be integrated into robots to enhance their mobility and manipulation abilities. The module can deploy a suitable mode of attachment, via spines or vacuum suction, to different contact surfaces in response to the textural properties of the surfaces. In order to make a decision on the suitable mode of attachment, an original dataset of 100 images of outdoor and indoor surfaces was enhanced using a WGAN-GP generating an additional 200 synthetic images. The enhanced dataset was then used to train a visual surface examination model using Faster R-CNN. The addition of synthetic images increased the mean average precision of the Faster R-CNN model from 81.6% to 93.9%. We have also conducted a series of load tests to characterize the module's strength of attachments. The results of the experiments indicate that the anchoring module can withstand an applied detachment force of around 22N and 20N when attached using spines and vacuum suction on the ideal surfaces, respectively.

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Simulation, control and construction of a four Mecanum-wheeled robot

Shahin¹,

Sadeghian²,

Sedigh

et al. 2017

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Shahrooz Shahin

Control of a four-mecanum wheeled robot with a soft-robotic glove

Design, Development and Control of a Three Flexible-Fingers Gripper Based On Hand Gesture

Autonomous Decision Making in a Bioinspired Adaptive Robotic Anchoring Module

Faster R-CNN-based Decision Making in a Novel Adaptive Dual-Mode Robotic Anchoring System

Simulation, control and construction of a four Mecanum-wheeled robot

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