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Implemented Methods

The package implements the following methods

Each method has additional parameters that can be passed via the options argument of the extract_saccades() function.

Engbert and Kliegl (2003)

The algorithm labels a sample as a saccade if velocity, measured in units of its standard deviation (see below), exceeds a predefined threshold (defaults to \(6\)) and the duration of a super-threshold period exceeds a minimal duration (defaults to \(12\) milliseconds). This method makes no assumptions about velocity in the units of degrees per second and can be used on any data (e.g., where samples encode gaze in screen position units).

The standard deviation is computed following formula #2 in Engbert and Kliegl (2003) as

sqrt(median(x^2) - median(x)^2)

However, if the value is smaller than .Machine$double.eps, it is recomputed via a mean estimator

sqrt(mean(x^2) - mean(x)^2)

Only a monocular version of the algorithm is implemented with binocular saccades computed using overlapping votes from two eyes. For method details and rationale for default parameter values refer to Engbert and Kliegl (2003).

Parameters:

Otero-Millan et al. (2014)

The algorithm:

  1. Detect local velocity peaks.
  2. Filter them based on a minimal inter-peak interval (defaults to \(30\) ms) and maximal allowed saccade rate (defaults to \(5\) Hz).
  3. Identify the onset and offset of a potential saccade using an absolute velocity threshold in degrees per second (defaults to \(3\)).
  4. Compute peak velocity and peak acceleration before and after the peak velocity was reached.
  5. Rotate velocity and peak acceleration via PCA and retain components above a predefined threshold for explained variance (defaults to \(0.05\)).
  6. Perform a cluster analysis on the remaining components for \(2\), \(3\), and \(4\) picking the solution with the smallest silhouette.
  7. Saccades are identified as a cluster with the highest average peak velocity.

For method details and rationale for default parameter values refer to Otero-Millan et al. (2014).

Parameters:

Nyström and Holmqvist (2010)

The algorithm:

  1. Identify physiologically implausible velocity and acceleration peaks (defaults to \(1000 \deg/s\) and \(100000 \deg/s^2\)).
  2. Identify noise onset/offset as samples around the implausible velocity/acceleration that are above median velocity. Exclude these samples from analysis.
  3. Identify velocity threshold \(PT = mean(V_{subthreshold}) + 6 \cdot std(V_{subthreshold})\) via an iterative method starting at arbitrary \(PT\) value (defaults to \(100 \deg/s\)). Stop when threshold change is below \(1 \deg/s\).
  4. Identify saccades as periods with peaks peaks above threshold \(PT\) and adjacent samples that are above \(PT_{onset/offset} = mean(V_{subthreshold}) + 3 \cdot std(V_{subthreshold})\).

For method details and rationale for default parameter values refer to Nyström and Holmqvist (2010).

Parameters:

References

Engbert, Ralf, and Reinhold Kliegl. 2003. Microsaccades uncover the orientation of covert attention.” Vision Research 43 (9): 1035–45. https://doi.org/10.1016/S0042-6989(03)00084-1.
Nyström, Marcus, and Kenneth Holmqvist. 2010. An adaptive algorithm for fixation, saccade, and glissade detection in eyetracking data.” Behavior Research Methods 42 (1): 188–204. https://doi.org/10.3758/BRM.42.1.188.
Otero-Millan, J., Jose L Alba Castro, Stephen L Macknik, and S. Martinez-Conde. 2014. Unsupervised clustering method to detect microsaccades.” Journal of Vision 14 (2): 18–18. https://doi.org/10.1167/14.2.18.

These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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