Abstract
A spatial filter combines signals from multiple sensors to create a virtual channel that emphasizes specific brain activity while reducing interference. Spatial filters range from simple, fixed configurations-such as rereferencing, gradient, or Laplacian filters-to more sophisticated, data-driven approaches like beamforming or independent component analysis (ICA). Although the underlying principle is simple, understanding a spatial filter's behavior can be challenging because of the high dimensionality of the data and the multiple "spaces" involved-those of sources, sensors, fields, and signals. This paper examines the properties and limitations of spatial filters, focusing on the idea of a virtual electrode-a synthetic signal formed by combining channels from noninvasive techniques such as EEG or MEG. While a spatial filter can fully suppress some sources, it cannot perfectly isolate a single source while rejecting all others, as a real electrode could. This places clear limits on what a virtual electrode can represent. I here suggest an alternative view of it as a virtual scalpel-a tool for refining recorded data rather than capturing activity of a single neural source. Just as temporal filters shape signals over time, spatial filters are key tools for improving the clarity and interpretability of brain recordings.