P.A. Parker scite author profile

This paper describes a novel approach to the control of a multifunction prosthesis based on the classification of myoelectric patterns. It is shown that the myoelectric signal exhibits a deterministic structure during the initial phase of a muscle contraction. Features are extracted from several time segments of the myoelectric signal to preserve pattern structure. These features are then classified using an artificial neural network. The control signals are derived from natural contraction patterns which can be produced reliably with little subject training. The new control scheme increases the number of functions which can be controlled by a single channel of myoelectric signal but does so in a way which does not increase the effort required by the amputee. Results are presented to support this approach.

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A wavelet-based continuous classification scheme for multifunction myoelectric control

Englehart

Hudgin²,

Parker

2001

IEEE Trans. Biomed. Eng.

613

342

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This work represents an ongoing investigation of dexterous and natural control of powered upper limbs using the myoelectric signal. When approached as a pattern recognition problem, the success of a myoelectric control scheme depends largely on the classification accuracy. A novel approach is described that demonstrates greater accuracy than in previous work. Fundamental to the success of this method is the use of a wavelet-based feature set, reduced in dimension by principal components analysis. Further, it is shown that four channels of myoelectric data greatly improve the classification accuracy, as compared to one or two channels. It is demonstrated that exceptionally accurate performance is possible using the steady-state myoelectric signal. Exploiting these successes, a robust online classifier is constructed, which produces class decisions on a continuous stream of data. Although in its preliminary stages of development, this scheme promises a more natural and efficient means of myoelectric control than one based on discrete, transient bursts of activity.

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Myoelectric signal processing for control of powered limb prostheses

Parker

Englehart

Hudgins

2006

Journal of Electromyography and Kinesiology

570

310

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Classification of the myoelectric signal using time-frequency based representations

Englehart

Hudgins

Parker

et al. 1999

Medical Engineering & Physics

544

303

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Control of Upper Limb Prostheses: Terminology and Proportional Myoelectric Control—A Review

Fougner

Stavdahl

Kyberd

et al. 2012

IEEE Trans. Neural Syst. Rehabil. Eng.

449

292

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Abstract-The recent introduction of novel multifunction hands as well as new control paradigms increase the demand for advanced prosthetic control systems. In this context, an unambiguous terminology and a good understanding of the nature of the control problem is important for efficient research and communication concerning the subject.Thus, one purpose of this paper is to suggest an unambiguous taxonomy, applicable to control systems for upper limb prostheses and also to prostheses in general. A functionally partitioned model of the prosthesis control problem is also presented along with the taxonomy.In the second half of the paper, the suggested taxonomy has been exploited in a comprehensive literature review on proportional myoelectric control of upper limb prostheses.The review revealed that the methods for system training have not matured at the same pace as the novel multifunction prostheses and more advanced intent interpretation methods. Few publications exist regarding the choice of training method and the composition of the training data set. In this context, the notion of outcome measures is essential. By definition, system training involves optimization, and the quality of the results depends heavily on the choice of appropriate optimization criteria. In order to further promote the development of proportional myoelectric control, these topics need to be addressed.

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P.A. Parker

A new strategy for multifunction myoelectric control

A wavelet-based continuous classification scheme for multifunction myoelectric control

Myoelectric signal processing for control of powered limb prostheses

Classification of the myoelectric signal using time-frequency based representations

Control of Upper Limb Prostheses: Terminology and Proportional Myoelectric Control—A Review

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