Electro-mechanical stability of surface EMG sensors

Roy, Serge H.; Luca, G. De; Cheng, M. Samuel; Johansson, Anders; Gilmore, L. Donald; Luca, Carlo J. De

doi:10.1007/s11517-007-0168-z

Cited by 92 publications

(54 citation statements)

References 16 publications

(16 reference statements)

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“…Those practitioners involved in muscle re-education have an additional challenge due to the fact that sweat accumulation can alter the dielectric properties of passive as well as active electrodes (DeLuca, 2006). Roy et al (2007) found that conductive gel does not improve the signal quality in situations where perspiration or mechanical perturbations are encountered (as in dynamic SEMG activities). The most challenging scenario would be gait work with an adolescent because one would have to deal with movement artifact and excess skin oils due to adolescence.…”

Section: Impedance At the Skin-electrode Sitesmentioning

confidence: 94%

Electrical Concepts in the Surface Electromyographic Signal

Bolek

2009

Appl Psychophysiol Biofeedback

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There are frequently used electrical terms in the biofeedback literature. Often it is assumed that the reader has detailed knowledge of these terms. The difficulty begins when seemingly familiar terms are used as a basis for an in-depth explanation of the process of electromyography. For example, the concept of impedance is based on three building blocks of electricity: current, voltage and resistance. The term "impedance" is found in every manual for biofeedback equipment with the suggestion that the electrode site be kept "low" and the encoder input "high". A little electrical knowledge can explain why this is so and in the process formulate a more thorough understanding of the equipment used everyday with a client.

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Section: Impedance At the Skin-electrode Sitesmentioning

confidence: 94%

Electrical Concepts in the Surface Electromyographic Signal

Bolek

2009

Appl Psychophysiol Biofeedback

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“…racquet making contact with the ball or a foot making contact with the floor) can cause a movement at the electrode-skin interface and impair 22 the consistency of the signal by generating motion artefact (De Luca et al, 2010;Roy et al, 2007;Whitting et al, 2009). While it is expected that excessive motion artefact in the EMG signal caused 535 by mechanical perturbation at impact to have affected the consistency and reliability of data during some of the measurements, only one study reported the effect of impact from tennis strokes on EMG recordings (Groppel and Nirschl, 1986).…”

Section: Methodological Considerationsmentioning

confidence: 99%

Electromyographic assessment of forearm muscle function in tennis players with and without Lateral Epicondylitis

Alizadehkhaiyat

Frostick

2015

Journal of Electromyography and Kinesiology

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There is no consensus about the main aetiology of Lateral Epicondylitis (LE) or Tennis Elbow. While electromyographic assessment of alterations in neuromuscular control and activation patterns of forearm muscles has received increasing interest as potential intrinsic factors in non-tennis players, there has been insufficient attention in tennis players. The purpose of present review was to search the 5 literature for the electromyographic studies of forearm muscles in tennis players in order to 1) identify related implications for LE, 2) highlight key technical and methodological shortcomings, and 3) suggest potential pathways for future research.An electronic search of PubMed, Scopus, Web of Science, and Google Scholars (1980 to October 2014) was conducted. Titles, abstracts, and full-text articles were screened to identify "peer-reviewed" 10 studies specifically looking into "electromyographic assessment of forearm muscles" in "tennis players". After screening 104 articles, 13 original articles were considered in the main review involving a total of 216 participants (78% male, 22% female). There were indications of increased extensor activity in all tennis strokes and less experiences single-handed players, however with insufficient evidence to support their relationship with the development of LE. Studies varied widely 15 in study population, sample size, gender, level of tennis skills, electrode type, forearm muscles studied, EMG recording protocol, EMG normalisation, and reported parameters. As a result, it was not possible to present combined results of existing studies and draw concrete conclusions in terms of clinical implications of findings. There is a need for establishment of specific guidelines and recommendations for EMG assessment of forearm musculature in terms of electrode and muscle 20 selection. Further studies of both healthy controls and tennis players suffering from TE with adequate sample sizes and well-defined demographics are warranted.3

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“…The sensory system that we choose is Myo [21], which can be worn at the driver's forearm and integrates with an inertial measurement unit (IMU) [22][23][24] and eight EMG sensors [25][26][27]. The IMU chip contains an onboard digital motion processor (DMP) and MPU-9150 module which consists of a 3-axis accelerometer, a 3-axis gyroscope, and a 3-axis magnetometer.…”

Section: Wearable Sensory Systemmentioning

confidence: 99%

Hands-Free Maneuvers of Robotic Vehicles via Human Intentions Understanding Using Wearable Sensing

Wang

Guo

et al. 2018

Journal of Robotics

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Intelligent robotic vehicles are more and more fully automated, without steering wheels, gas/brake pedals, or gearshifts. However, allowing the human driver to step in and maneuver the robotic vehicle under specific driving requirements is a necessary issue that should be considered. To this end, we propose a wearable-sensing-based hands-free maneuver intention understanding approach to assist the human to naturally operate the robotic vehicle without physical contact. The human intentions are interpreted and modeled based on the fuzzy control using the forearm postures and muscle activities information detected by a wearable sensory system, which incorporates electromyography (EMG) sensors and inertial measurement unit (IMU). Based on the maneuver intention understanding model, the human can flexibly, intuitively, and conveniently control diverse vehicle maneuvers only using his intention expressions. This approach was implemented by a series of experiments in the practical situations on a lab-based 1/10 robotic vehicle research platform. Experimental results and evaluations demonstrated that, by taking advantage of the nonphysical contact and natural handleability of this approach, the robotic vehicle was successfully and effectively maneuvered to finish the driving tasks with considerable accuracy and robustness in human-robotic vehicle interaction.

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Electro-mechanical stability of surface EMG sensors

Cited by 92 publications

References 16 publications

Electrical Concepts in the Surface Electromyographic Signal

Electrical Concepts in the Surface Electromyographic Signal

Electromyographic assessment of forearm muscle function in tennis players with and without Lateral Epicondylitis

Hands-Free Maneuvers of Robotic Vehicles via Human Intentions Understanding Using Wearable Sensing

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