The spatial integration effect of surface electrode detecting myoelectric signal

The spectral properties of surface electrodes used for myoelectric signal detection were investigated using both a theoretical and an experimental approach. On the basis of the theoretical model, the single surface electrode was found to act as a low pass filter depending on the electrode diameter (d) and the fiber conduction velocities (CVs). Several dips in the power spectrum were also predicted for varying frequencies depending on d and CV. The mathematical expression of the surface electrode filter was highly consistent with previously demonstrated properties of the single fiber power spectrum. An experimental comparison between myoelectric signals from the vastus lateralis muscle recorded using two electrode pairs with different diameters confirmed this low pass filter effect. However, the dip phenomenon was not observed from experimental data. The practical consequences of the electrode filter effect are discussed with respect to the interpretation of changes in surface myoelectric signal spectrum, particularly when a shift toward the high frequencies is observed.<<ETX>>

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