Sistema de identificación de intención de movimiento para el control mioeléctrico de una prótesis de mano robótica

Quinayás-Burgos, César Augusto; Gaviria-López, Carlos Alberto

doi:10.11144/javeriana.iyu19-1.siim

Cited by 9 publications

(2 citation statements)

References 21 publications

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“…The architecture levels are described below. The Human–Machine Interface (HMI) is devoted to measuring and interpreting the humans’ signals for identifying four types of grip postures (rest, open hand, power grip, and tripod grip) [ 120 ] and to sending this information to the next level (as well as the AIP, IPL, F5 and PMv areas in human brain, Section 5 ). The Haptic Perception (HP) level receives information from robotic hand sensors and HMI and generates information (contact and slip) to the high-level control (HLC), (FA-I and SA-II, Section 5.1 ).…”

Section: Control Strategies For Hand Prosthesesmentioning

confidence: 99%

Hierarchical Human-Inspired Control Strategies for Prosthetic Hands

Gentile

Cordella

Zollo

2022

Sensors

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The abilities of the human hand have always fascinated people, and many studies have been devoted to describing and understanding a mechanism so perfect and important for human activities. Hand loss can significantly affect the level of autonomy and the capability of performing the activities of daily life. the technological improvements have led to the development of mechanically advanced commercial prostheses, the control strategies are rather simple (proportional or on/off control). The use of these commercial systems is unnatural and not intuitive, and therefore frequently abandoned by amputees. The components of an active prosthetic hand are the mechatronic device, the decoding system of human biological signals into gestures and the control law that translates all the inputs into desired movements. The real challenge is the development of a control law replacing human hand functions. This paper presents a literature review of the control strategies of prosthetics hands with a multiple-layer or hierarchical structure, and points out the main critical aspects of the current solutions, in terms of human’ functions replicated with the prosthetic device. The paper finally provides several suggestions for designing a control strategy able to mimic the functions of the human hand.

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Section: Control Strategies For Hand Prosthesesmentioning

confidence: 99%

Hierarchical Human-Inspired Control Strategies for Prosthetic Hands

Gentile

Cordella

Zollo

2022

Sensors

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“…The others are invasive and require surgery to place the electrodes inside the muscles. The latter option provides the best performance, as the obtained signal is cleaner and contains less noise, but implanting electrodes also represents greater costs and risks [7].…”

Section: Introductionmentioning

confidence: 99%

Advances in the mental control of a robotic hand

2020

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Introduction: The present article is the product of the research "Advances in the mental control of a robotic hand", developed at the University of Pamplona in the year 2019. Problem: Currently one of the main problems presented by robotic hand prostheses is the way in which the user indicates the movements to be performed. Given this, the best results have been obtained using invasive systems. Objective: The main objective of the system is to allow a person to control the movements and / or gestures of a robotic hand using their thoughts, in such a way that the control is as natural and precise as possible. Methodology: Use is made of a non-invasive, low-cost brain-computer interface (BCI) for the generation of control system references. Results: The performance of the system is directly subject to the user's ability to recreate actions or movements in their mind; the more defined your thinking, the better the control response. Conclusion: Mind control represents a new challenge for users, but as it is used, it becomes a more natural and precise control method, offering great control possibilities to people who make daily use of robotic hand prostheses. Originality: Through this research, an alternative is formulated for the control of hand prostheses, which does not require invasive systems and has the advantage of being low cost. Limitations: Frustration, stress and external noise are factors that directly affect the performance of the system.

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