Figure 5. Neuronal avalanches in human MEG reveal power law exponent of α = −3/2 at critical branching parameter σ = 1. A, Phase plots of the power law exponent, α, versus the branching parameter, σ, using axial sensors. Each point represents a single subject at a single Δt, where different colors correspond to different values of Δt (see color key; n = 104 subjects). B–D, Average phase plots of the exponent, α, versus the branching parameter, σ, for the several array types examined. Vertical and horizontal bars denote SD. Solid vertical and horizontal lines denote the point σ = 1, α = −3/2. Insets depict the corresponding sensor arrays. B, Axial (black circles) and virtual planar (blue squares) sensors. C, Subsamples of the array (only for axial sensors). Error bars were omitted for clarity of presentation. D, Coarse-grained array for axial (black circles) and planar (blue squares) sensors. E, F, Robustness to changes in threshold and peak detection method. E, Average phase plots from all sensors for threshold values ranging from ±2.7 to ±4.2 SD. Here and throughout the manuscript, an event was identified as the most extreme point in each excursion beyond the threshold (inset). Increasing the threshold from ±2.7 to ±4.2 SD reduced the avalanche rate by an order of magnitude from 27.3 to 2.4 Hz for bin width of 3.3 ms. F, Same as in E, but with a peak detection method that identifies events at all local extremum points beyond the threshold (inset). The change in peak detection method did not change substantially the overall rate of avalanches, which was 27.1 Hz at a threshold of ±2.7 SD and 2.5 Hz at ±4.2 SD.