Effective Multi-Mode Grasping Assistance Control of a Soft Hand Exoskeleton Using Force Myography

Islam, Muhammad Raza Ul; Bai, Shaoping

doi:10.3389/frobt.2020.567491

Cited by 15 publications

(9 citation statements)

References 27 publications

(31 reference statements)

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“…To acquire effective biosignals, the sensor needs to be in close contact with the skin, and piezoresistive sensors have this characteristic. The most frequently used piezoresistive sensors are force-sensitive resistors (FSR), for instance, FSR 402 [ 27 , 28 , 29 ] and FSR 400 [ 16 , 30 ], which are based on resistive polymer thick film sensor (RPTF) technology. Because of their thin profile, flexibility, and low cost, they become a practical solution for prosthetic pressure measurement [ 31 ].…”

Section: Data Acquisitionmentioning

confidence: 99%

“…In time domain, there are five commonly used parameters to describe signal features: mean absolute value (MAV) [ 17 , 82 , 83 ], mean absolute value slope [ 22 , 27 ], slope sign changes (SSC) [ 83 , 84 , 85 ], zero crossing (ZC) [ 83 , 84 ] and waveform length (WL) [ 86 ]. These features mainly apply to signal amplitude, while in the frequency domain, signal power information and frequency information are mainly utilized.…”

Section: Data Processingmentioning

confidence: 99%

“…In consideration of simplifying the procedure, Muhammad chose slope to displace amplitude. They set four thresholds to distinguish four hand motions: rest, open, close, and grasp [ 27 ].…”

Section: Data Processingmentioning

confidence: 99%

See 2 more Smart Citations

A Review of EMG-, FMG-, and EIT-Based Biosensors and Relevant Human–Machine Interactivities and Biomedical Applications

Zheng

Zhao

et al. 2022

Biosensors

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Wearables developed for human body signal detection receive increasing attention in the current decade. Compared to implantable sensors, wearables are more focused on body motion detection, which can support human–machine interaction (HMI) and biomedical applications. In wearables, electromyography (EMG)-, force myography (FMG)-, and electrical impedance tomography (EIT)-based body information monitoring technologies are broadly presented. In the literature, all of them have been adopted for many similar application scenarios, which easily confuses researchers when they start to explore the area. Hence, in this article, we review the three technologies in detail, from basics including working principles, device architectures, interpretation algorithms, application examples, merits and drawbacks, to state-of-the-art works, challenges remaining to be solved and the outlook of the field. We believe the content in this paper could help readers create a whole image of designing and applying the three technologies in relevant scenarios.

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Section: Data Acquisitionmentioning

confidence: 99%

Section: Data Processingmentioning

confidence: 99%

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A Review of EMG-, FMG-, and EIT-Based Biosensors and Relevant Human–Machine Interactivities and Biomedical Applications

Zheng

Zhao

et al. 2022

Biosensors

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show abstract

“…[29,30] In addition to EMG signals, forcemyography (FMG) is another important muscle activity signal. [31][32][33][34] To date, various high-sensitivity pressure sensors have been utilized to detect subtle FMG signals by tightly attaching to the skin surface, such as resistive sensors, piezoelectric sensors, resistive polymer thick film sensors, and textile-based sensors, and has also been widely applied in active rehabilitation. [33,[35][36][37][38][39] Among these sensors, resistive pressure sensors are the most commonly used sensors in FMG detection due to their simple detection circuits and higher stability.…”

Section: Introductionmentioning

confidence: 99%

High‐Performance Hydrogel Sensors Enabled Multimodal and Accurate Human–Machine Interaction System for Active Rehabilitation

Wang,

Ding,

Luo

et al. 2023

Advanced Materials

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Human–machine interaction (HMI) technology shows an important application prospect in rehabilitation medicine, but it is greatly limited by the unsatisfactory recognition accuracy and wearing comfort. Here, this work develops a fully flexible, conformable, and functionalized multimodal HMI interface consisting of hydrogel‐based sensors and a self‐designed flexible printed circuit board. Thanks to the component regulation and structural design of the hydrogel, both electromyogram (EMG) and forcemyography (FMG) signals can be collected accurately and stably, so that they are later decoded with the assistance of artificial intelligence (AI). Compared with traditional multichannel EMG signals, the multimodal human–machine interaction method based on the combination of EMG and FMG signals significantly improves the efficiency of human–machine interaction by increasing the information entropy of the interaction signals. The decoding accuracy of the interaction signals from only two channels for different gestures reaches 91.28%. The resulting AI‐powered active rehabilitation system can control a pneumatic robotic glove to assist stroke patients in completing movements according to the recognized human motion intention. Moreover, this HMI interface is further generalized and applied to other remote sensing platforms, such as manipulators, intelligent cars, and drones, paving the way for the design of future intelligent robot systems.

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“…Primarily, FMG has been used in gesture classification for prosthetics [7,13,8,14]. Only a limited number of studies have also exploited FMG for RHO control, whereas in most cases the signal was collected from the forearm contralateral to the worn RHO [15,16]. However, measuring FMG from the contralateral side restricts the conduction of bimanual tasks which are crucial for many activities in daily living.…”

Section: Introductionmentioning

confidence: 99%

Feasibility of force myography for the direct control of an assistive robotic hand orthosis

Gantenbein

Ahmadizadeh

Heeb

et al. 2023

Preprint

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Background: Assistive robotic hand orthoses can support people with sensorimotor hand impairment in many activities of daily living and therefore help to regain independence. However, in order for the users to fully benefit from the functionalities of such devices, a safe and reliable way to detect their movement intention for device control is crucial. Gesture recognition based on force myography measuring volumetric changes in the muscles during contraction has been previously shown to be a viable and easy to implement strategy to control hand prostheses. Whether this approach could be efficiently applied to intuitively control an assistive robotic hand orthosis remains to be investigated. Methods: In this work, we assessed the feasibility of using force myography measured from the forearm to control a robotic hand orthosis worn on the hand ipsilateral to the measurement site. In ten neurologically-intact participants wearing a robotic hand orthosis, we collected data for four gestures trained in nine arm configurations, i.e., seven static positions and two dynamic movements, corresponding to typical activities of daily living conditions. In an offline analysis, we determined achieved classification accuracies for two binary classifiers (one for opening and one for closing) and further assessed the impact of individual training arm configurations on the overall performance. Results: We achieved an overall classification accuracy of 92.9% (averaged over two binary classifiers, individual accuracies 95.5% and 90.3%, respectively) but found a large variation in performance between participants, ranging from 75.4% up to 100%. Further, we found that the number of training arm configurations could be reduced from nine to six without notably decreasing classification performance. Conclusion: The results of this work support the general feasibility of using force myography as an intuitive intention detection strategy for a hand orthosis. Further, the findings also generated valuable insights into challenges and potential ways to overcome them in view of applying such technologies for assisting people with sensorimotor hand impairment during activities of daily living.

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Effective Multi-Mode Grasping Assistance Control of a Soft Hand Exoskeleton Using Force Myography

Cited by 15 publications

References 27 publications

A Review of EMG-, FMG-, and EIT-Based Biosensors and Relevant Human–Machine Interactivities and Biomedical Applications

A Review of EMG-, FMG-, and EIT-Based Biosensors and Relevant Human–Machine Interactivities and Biomedical Applications

High‐Performance Hydrogel Sensors Enabled Multimodal and Accurate Human–Machine Interaction System for Active Rehabilitation

Feasibility of force myography for the direct control of an assistive robotic hand orthosis

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