Assistant robot through deep learning

Moreno, Róbinson Jiménez; Pinzón-Arenas, Javier Orlando; Pachón, César G.

doi:10.11591/ijece.v10i1.pp1053-1062

Cited by 8 publications

(6 citation statements)

References 21 publications

(25 reference statements)

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“…Within this group, we find robot pets that stimulate the development of children, mobile manipulators that transport heavy loads, and assistance robots that mobilize or perform rehabilitation procedures on people with health problems, among others [ 2 , 3 ]. According to their applications, robots can be subdivided into six main groups: ( i) Military robots , which are used to perform tasks of exploration, surveillance, security, rescue, etc., and are responsible for carrying out activities in hostile environments that can be considered high-risk for people [ 4 , 5 ]; ( ii) Construction robots have the ability to be programmed to perform complex tasks or operate semi-autonomously, aimed at improving productivity as well as accident prevention in the workplace [ 6 , 7 ]; ( iii) Field robots have transformed various aspects of the agricultural, livestock, and mining industries, reducing production costs and increasing profits, thus increasing the economy of population [ 8 , 9 ]; (iv) Learning robots, which are didactic tools that improve the learning process, and they are regularly implemented in stimulation therapies for children with learning problems such as autism and attention deficit, among others [ 2 , 10 , 11 ]; ( v) Entertainment robots , capable of performing various tasks with the aim of entertaining and accompanying human beings, they are commonly used as interactive toys for children [ 12 ]; and finally ( vi) Robots in medicine, which can be autonomous or tele-operated. They are classified into surgeon robots, prosthetic robots, therapeutic robots, and assistance robots, considered as precise mechanisms with high accuracy due to the large number of sensors and actuators that have this technology [ 13 , 14 ].…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Unified Motion Control of a Robotic Standing Wheelchair for Rehabilitation Purposes

Ortiz

Palacios-Navarro

Andaluz

et al. 2021

Sensors

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Technological advances in recent years have shown interest in the development of robots in the medical field. The integration of robotic systems in areas of assistance and rehabilitation improves the user’s quality of life. In this context, this article presents a proposal for the unified control of a robotic standing wheelchair. Considering primary and secondary tasks as control objectives, the system performs tasks autonomously and the change of position and orientation can be performed at any time. The development of the control scheme was divided in two parts: (i) kinematic controller to solve the desired motion problem; and (ii) dynamic compensation of the standing wheelchair–human system. The design of the two controllers considers the theory of linear algebra, proposing a low computational cost and an asymptotically stable algorithm, without disturbances. The stability and robustness analysis of the system is performed by analyzing the evolution of the control errors in each sampling period. Finally, real experiments of the performance of the developed controller are performed using a built and instrumented standing wheelchair.

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Section: Introductionmentioning

confidence: 99%

Three-Dimensional Unified Motion Control of a Robotic Standing Wheelchair for Rehabilitation Purposes

Ortiz

Palacios-Navarro

Andaluz

et al. 2021

Sensors

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“…Figure 1 (left) illustrates the test environment used, where the black background where the nuts to be relocated would be found is highlighted. The system has an interface that allows human intervention and control, through the Telegram application [29] capable of operating from an Android or IOS cell phone. Figure 1 (right) illustrates the local controller based on a raspberry pi 2 model B, programed in python, the pi-camera V1 of the raspberry was used for image acquisition, and its GPIO module is used as a driver to each servomotor.…”

Section: Proposed Methodsmentioning

confidence: 99%

Robotic hex-nut sorting system with deep learning

Almanza

Baquero

Moreno

2021

IJECE

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<span>This article exposes the design and implementation of an automation system based on a robotic arm for hex-nut classification, using pattern recognition and image processing. The robotic arm work based on three servo motors and an electromagnetic end effector. The pattern recognition implemented allows classifying three different types of hex-nut through deep learning algorithms based on convolutional neural network architectures. The proposed methodology exposes four phases: the first is the design, implementation, and control of a robotic arm. The second is the capture, classification, and image treatment; the third allows gripping the nut through the robot’s inverse kinematic. The final phase is the re-localization of the hex-nut in the respective container. The automation system successfully classifies all the types of hex-nuts, where the convolutional network used is an efficient and recent pattern recognition method, with an accuracy of 100% in 150 iterations. This development allows for obtaining a novel algorithm for robotic applications in hex-nut sorting.</span>

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“…In [13], we are talking about assistive robotics and possibility of using three convolutional neural networks that are trained, one for recognizing group of tools, second for speech recognition, trained with names of tools, and third for recognition of user's hand, taking in consideration classification of 2 gestures: open and closed hand. As a result, authors have developed functional application for assistive robotics capable of receiving and correctly identifying voice commands, associating them with physical object, picking it up and delivering it to user's hands.…”

Section: Related Workmentioning

confidence: 99%

Some Features of Classifiers Implementation for Object Recognition in Specialized Computer systems

Abu-Jassar¹,

Al-Sharo²,

Lyashenko³

et al. 2021

TEM Journal

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Generalized formalization of recognition algorithm for specialized computer systems is presented in this paper. The structure features of image recognition methods, which have to be taken into account when developing classifiers for object recognition in specialized computer systems, are described. The fundamental types of images characteristics-features, which are used in various methods of image recognition, are discussed. Approaches to development of classifiers for recognizing robotization objects, which are implemented on basis of Haar classifiers, are discussed. The issues of using machine learning algorithm of adaptive gain AdaBoost for development of such classifiers are also considered. Utilities have been developed for implementation of classifiers for object recognition in specialized computer systems.

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