mt_plot_riverbed: Plot density of mouse positions across time steps.
In mousetrap: Process and Analyze Mouse-Tracking Data

mt_plot_riverbed

R Documentation

Plot density of mouse positions across time steps.

Description

mt_plot_riverbed creates a plot showing the distribution of one trajectory variable (e.g., the x-positions or velocity) per time step.

Usage

mt_plot_riverbed(
  data,
  use = "tn_trajectories",
  y = "xpos",
  y_range = NULL,
  y_bins = 250,
  facet_row = NULL,
  facet_col = NULL,
  facet_data = "data",
  grid_colors = c("gray30", "gray10"),
  na.rm = FALSE
)

Arguments

`data`	mousetrap data object containing the data to be plotted.
`use`	character string specifying the set of trajectories to use in the plot. The steps of this set will constitute the x axis. Defaults to 'tn_trajectories', which results in time steps being plotted on the x axis.
`y`	variable in the mousetrap data object to be plotted on the output's y dimension. Defaults to 'xpos', the cursor's x coordinate.
`y_range`	numerical vector containing two values that represent the upper and lower ends of the y axis. By default, the range is calculated from the data provided.
`y_bins`	number of bins to distribute along the y axis (defaults to 250).
`facet_row`	an optional character string specifying a variable in `data[[facet_data]]` that should be used for (row-wise) faceting. If specified, separate riverbed plots for each level of the variable will be created.
`facet_col`	an optional character string specifying a variable in `data[[facet_data]]` that should be used for (column-wise) faceting. If specified, separate riverbed plots for each level of the variable will be created.
`facet_data`	a character string specifying where the (optional) data containing the faceting variables can be found.
`grid_colors`	a character string or vector of length 2 specifying the grid color(s). If a single value is provided, this will be used as the grid color. If a vector of length 2 is provided, the first value will be used as the color for the major grid lines, the second value for the minor grid lines. If set to `NA`, no grid lines are plotted.
`na.rm`	logical specifying whether missing values should be removed. This is not done by default, because generally riverbed plots are generated from preprocess trajectories (e.g., time-normalized trajectories) that all have the same length (i.e., the same number of steps).

Details

This function plots the relative frequency of the values of a trajectory variable separately for each of a series of time steps. This type of plot has been used in previous research to visualize the distribution of x-positions per time step (e.g., Scherbaum et al., 2010).

mt_plot_riverbed usually is applied to time-normalized trajectory data as all trajectories must contain the same number of values (if na.rm=FALSE, the default).

Author(s)

Felix Henninger

Pascal J. Kieslich

References

Scherbaum, S., Dshemuchadse, M., Fischer, R., & Goschke, T. (2010). How decisions evolve: The temporal dynamics of action selection. Cognition, 115(3), 407-416.

Scherbaum, S., & Kieslich, P. J. (2018). Stuck at the starting line: How the starting procedure influences mouse-tracking data. Behavior Research Methods, 50(5), 2097–2110.

Examples

# Time-normalize trajectories
KH2017 <- mt_time_normalize(KH2017)
  
# Create riverbed plot for all trials
mt_plot_riverbed(KH2017)

## Not run: 
# Create separate plots for typical and atypical trials
mt_plot_riverbed(mt_example, facet_col="Condition")


# Create riverbed plot for all trials with custom x and y axis labels
mt_plot_riverbed(mt_example) +
  ggplot2::xlab("Time step") + ggplot2::ylab("X coordinate")

# Note that it is also possible to replace the
# default scale for fill with a custom scale
mt_plot_riverbed(mt_example, facet_col="Condition") +
  ggplot2::scale_fill_gradientn(colours=grDevices::heat.colors(9),
    name="Frequency", trans="log", labels=scales::percent)

## End(Not run)

mousetrap documentation built on May 29, 2024, 11:39 a.m.