Identification of Multiple-Input Systems with Highly Coupled Inputs: Application to EMG Prediction from Multiple Intracortical Electrodes

A robust identification algorithm has been developed for linear, time-invariant, multiple-input single-output systems, with an emphasis on how this algorithm can be used to estimate the dynamic relationship between a set of neural recordings and related physiological signals. The identification algo...

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Bibliographic Details
Published in:Neural computation 2006-02, Vol.18 (2), p.329-355
Main Authors: Westwick, David T., Pohlmeyer, Eric A., Solla, Sara A., Miller, Lee E., Perreault, Eric J.
Format: Article
Language:English
Subjects:
Algorithms
Animals
Applied sciences
Arm - physiology
Artificial intelligence
Biological and medical sciences
Computer science
control theory
systems
Computer Simulation
Electrodes
Electromyography
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
General aspects. Models. Methods
Information retrieval. Graph
Learning and adaptive systems
Mathematics
Models, Neurological
Motor Cortex - physiology
Muscle, Skeletal - physiology
Primates
Probability and statistics
Probability theory and stochastic processes
Robust control
Sciences and techniques of general use
Special processes (renewal theory, markov renewal processes, semi-markov processes, statistical mechanics type models, applications)
Theoretical computing
Vertebrates: nervous system and sense organs
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Summary:A robust identification algorithm has been developed for linear, time-invariant, multiple-input single-output systems, with an emphasis on how this algorithm can be used to estimate the dynamic relationship between a set of neural recordings and related physiological signals. The identification algorithm provides a decomposition of the system output such that each component is uniquely attributable to a specific input signal, and then reduces the complexity of the estimation problem by discarding those input signals that are deemed to be insignificant. Numerical difficulties due to limited input bandwidth and correlations among the inputs are addressed using a robust estimation technique based on singular value decomposition. The algorithm has been evaluated on both simulated and experimental data. The latter involved estimating the relationship between up to 40 simultaneously recorded motor cortical signals and peripheral electromyograms (EMGs) from four upper limb muscles in a freely moving primate.The algorithm performed well in both cases:it provided reliable estimates of the system output and significantly reduced the number of inputs needed for output prediction. For example, although physiological recordings from up to 40 different neuronal signals were available, the input selection algorithm reduced this to 10 neuronal signals that made signicant contributions to the recorded EMGs.
ISSN:0899-7667
1530-888X
DOI:10.1162/089976606775093855