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saccadr is a modular and extendable R package to extract (micro)saccades from gaze samples via an ensemble of methods approach.
Although there is a consensus about a general definition of a saccade, the more specific details are harder to agree upon. Therefore, there are numerous algorithms that extract saccades based on various heuristics, which differ in the assumptions about velocity, acceleration, etc. The package uses these methods to label individual samples and then applies a majority vote approach to identify saccades. The package includes three methods (see Implemented Methods vignette) but can be extended via custom methods (see Using custom methods vignette). It also uses a modular approach to compute velocity and acceleration from noisy samples (see Velocity computation vignette). Finally, you can obtain methods votes per gaze sample instead of saccades (see Using sample votes vignette).
The extract_saccades()
function uses several methods to
label individual samples as belonging to a saccade, classifies a sample
as a potential saccade if its proportion of votes exceeds a preset
threshold, and then identifies saccades based on minimal saccade
duration and minimal time between the saccades. For binocular data, 1)
samples can be averaged before velocity computation, 2) votes
can be merged so that function returns binocular saccades, or 3)
saccades are extracted for each eye separately.
Currently, the library implements saccade detection using the following saccade detection methods. When using this package, please cite both the package and individual methods.
method_ek
: Engbert, R., & Kliegl, R. (2003).
Microsaccades uncover the orientation of covert attention. Vision
Research, 43(9), 1035–1045.
https://doi.org/10.1016/S0042-6989(03)00084-1method_om
: Otero-Millan, J., Castro, J. L. A.,
Macknik, S. L., & Martinez-Conde, S. (2014). Unsupervised clustering
method to detect microsaccades. Journal of Vision, 14(2), 18–18.
https://doi.org/10.1167/14.2.18method_nh
: Nyström, M., & Holmqvist, K. (2010). An
adaptive algorithm for fixation, saccade, and glissade detection in eye
tracking data. Behavior Research Methods, 42(1), 188–204.
https://doi.org/10.3758/BRM.42.1.188For current stable version use
install.packages("saccadr")
To install the development version from github
library("devtools")
install_github("alexander-pastukhov/saccadr", dependencies=TRUE)
The main function is extract_saccades()
. Minimally, it
takes x and y gaze samples, and sampling rate returning a table with
extracted saccades. Note that the function expects that units of the
gaze samples are degrees of visual angle, as some
methods use physiologically plausible velocity and acceleration
thresholds.
data("single_trial")
<- extract_saccades(single_trial$x, single_trial$y, sample_rate = 500) saccades
When the recording spans multiple trials, you need to specify this
via trial
parameter. This way velocity computation and
saccade detection methods respect trial boundaries.
data(monocular_ten_trials)
<- extract_saccades(monocular_ten_trials$x
saccades $y,
monocular_ten_trials500,
trial = monocular_ten_trials$trial)
There are three ways in which binocular data can be treated based on
the value of the binocular
parameter:
binocular = "merge"
(default): sample votes are
obtained from both eyes and for all methods and then averaged. This way
only binocular saccades (i.e., eye movements with sufficient temporal
overlap between eyes) are detected. Eye = "Binocular"
in
saccade description.binocular = "cyclopean"
: binocular data is converted to
an average cyclopean image before voting and saccades detection.
Eye = "Cyclopean"
in saccade description.binocular = "monocular"
: saccades are extracted
independently for each eye. Eye = "Left"
or
Eye = "Right"
in saccade description.data("single_trial_binocular")
# binocular saccades only
<- saccadr::extract_saccades(single_trial_binocular[, c('xL', 'xR')],
saccades_b c('yL', 'yR')],
single_trial_binocular[, sample_rate = 1000)
# cyclopean saccades from binocular data
<- saccadr::extract_saccades(single_trial_binocular[, c('xL', 'xR')],
saccades_c c('yL', 'yR')],
single_trial_binocular[, sample_rate = 1000,
binocular = "cyclopean")
# monocular saccades from binocular data
<- saccadr::extract_saccades(single_trial_binocular[, c('xL', 'xR')],
saccades_m c('yL', 'yR')],
single_trial_binocular[, sample_rate = 1000,
binocular = "monocular")
By default, all implemented methods are used for saccade detection but, if necessary, you can use their subset or even a single method. Note that you can also supply your own saccade detection function, please see Using custom methods vignette.
# Using a single method
<- extract_saccades(single_trial$x, single_trial$y, 500, methods = method_om)
saccades
# Using two methods
<- extract_saccades(single_trial$x, single_trial$y, 500, methods = list(method_ek, method_om)) saccades
Parameters for individual methods are passed via the
options
argument, which is a named list with
<parameter-name> = <value>
pairs. You can find
information on specific parameters and their default values in
Implemented Methods vignette. Here is an example of modifying a
velocity threshold, measured in units of standard deviation, for Engbert
& Kliegl (2003) method. The default value is 6 but we can make it
stricter
<- extract_saccades(single_trial$x, single_trial$y, 500, options = list("ek_velocity_threshold" = 8)) saccades
The voting threshold is the number of methods that must label a
sample as a potential saccade. By default, all but one method must agree
for a sample to be considered for a saccade
(vote_threshold = length(methods) - 1
) but is 1, if only a
single method was passed to the function. You can make voting more or
less restrictive via vote_threshold
parameter.
# A strict unanimous decision threshold
<- extract_saccades(single_trial$x, single_trial$y, 500, vote_threshold = 3)
saccades
# A slacker criterion that at least one of the three methods must label sample as a saccade
<- extract_saccades(single_trial$x, single_trial$y, 500, vote_threshold = 1) saccades
Because the gaze samples tend to be noisy, different methods use
various approaches for computing velocity from noisy samples. Methods by
Engbert & Kliegl (2003) and Otero-Millan et al. (2014) used the same
approach based on averaging over multiple samples to compute velocity,
whereas Nyström & Holmqvist (2010) compute a simple derivative and
then filter it. By default, package uses the former approach
(velocity_function = diff_ek
) but you can also use the
latter (velocity_function = diff_nh
) or implement a custom
method (see Velocity computation vignette). Acceleration is
computed the same way but from velocity samples. Here is an example of
using Nyström & Holmqvist (2010) velocity computation
<- extract_saccades(single_trial$x, single_trial$y, 500, velocity_function = diff_nh) saccades
Once the votes are in, saccades detection is based on their minimal
duration (minimal_duration_ms
parameter, defaults to 12 ms)
and minimal time between the saccades
(minimal_separation_ms
, defaults to 12 ms).
# Only longish saccades are extracted
<- extract_saccades(single_trial$x, single_trial$y, 500, minimal_duration_ms = 20) saccades
The extract_saccades()
function returns a table with
following columns:
Trial
Trial index.Eye
“Monocular” for monocular inputs. “Cyclopean” for
binocular data that was averaged before applying algorithms. “Binocular”
for binocular data with votes averaged after applying algorithms. “Left”
or “Right” for binocular data when eyes are processed
independently.OnsetSample
Index of the first sample.OffsetSample
Index of the last sample.Onset
Onset time relative to the trial start in
milliseconds.Offset
Offset time relative to the trial start in
milliseconds.Duration
Duration in milliseconds.DisplacementX
Horizontal displacement measured from the
first to the last sample.DisplacementY
Vertical displacement measured from the
first to the last sample.Displacement
Displacement magnitude measured from the
first to the last sample.DisplacementPhi
Displacement direction measured from
the first to the last sample.AmplitudeX
Horizontal displacement measured from the
leftmost to the rightmost sample.AmplitudeY
Vertical displacement measured from the
lowest to the uppermost sample.Amplitude
Displacement magnitude measured from the most
extreme samples.AmplitudePhi
Displacement direction measured from the
most extreme samples.VelocityPeak
Peak velocity.VelocityAvg
Average velocity.AccelerationPeak
Peak acceleration.AccelerationAvg
Average acceleration.AccelerationStart
Peak acceleration before peak
velocity was reached.AccelerationStop
Peak acceleration after peak velocity
was reached.Alternatively, if you use parameter return_votes = TRUE
the function can return votes per sample and method (and eye, for
binocular data). Please see Using sample votes vignette for
details.
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.