knitr::opts_chunk$set( collapse = TRUE, comment = "#>", warning = FALSE, message = FALSE, fig.width = 7, fig.height = 7 )
Analysis of time series data often involves applying "rolling" functions to calculate, e.g. a "moving average". These functions are straightforward to write in any language and it makes sense to have C++ versions of common rolling functions available to R as they dramatically speed up calculations. Several packages exist that provide some version of this functionality:
Our goal in creating a new package of C++ rolling functions is to build up a suite of functions useful in environmental time series analysis. We want these functions to be available in a neutral environment with no underlying data model. The functions are as straightforward to use as is reasonably possible with a target audience of data analysts at any level of R expertise.
Install from CRAN with:
install.packages('MazamaRollUtils')
Install the latest version from GitHub with:
devtools::install_github("MazamaScience/MazamaRollUtils")
Many of the rolling functions in MazamaRollUtils have the names of familiar
R functions with roll_
prepended. These functions calculate rolling versions of
the expected statistic:
roll_max()
roll_mean()
roll_median()
roll_min()
roll_prod()
roll_sd()
roll_sum()
roll_var()
Additional rolling functions with no equivalent in base R include:
roll_MAD()
-- Median Absolute Deviationroll_hampel()
-- Hampel filterOther functions wrap the rolling functions to provide enhanced functionality. These are not required to return vectors of the same length as the input data.
findOutliers()
-- returns indices of outlier values identified by roll_hampel()
.All of the roll_~()
functions accept the same arguments where appropriate:
x
-- Numeric vector input.width
-- Integer width of the rolling window.by
-- Integer shift to use when sliding the window to the next location
align Character position of the return value within the window. One of: "left" | "center" | "right"
.na.rm
-- Logical specifying whether \code{NA} values should be removed
before the calculations within each window.The roll_mean()
function also accepts:
weights
-- Numeric vector of size width
specifying each window index weight.
If NULL
, unit weights are used.The output of each roll_~()
function is guaranteed to have the same length as
the input vector, with varying stretches of NA
at one or both ends
depending on arguments width
, align
and na.rm
. This makes it easy to
align the return values with the input data.
The example dataset included in the package contains a tiny amount of data but suffices to demonstrate usage of package functions.
library(MazamaRollUtils) # Extract vectors from our example dataset t <- example_pm25$datetime x <- example_pm25$pm25 # Plot with 3- and 24-hr rolling means layout(matrix(seq(2))) plot(t, x, pch = 16, cex = 0.5) lines(t, roll_mean(x, width = 3), col = 'red') title("3-hour Rolling Mean") plot(t, x, pch = 16, cex = 0.5) lines(t, roll_mean(x, width = 24), col = 'red') title("24-hour Rolling Mean") layout(1)
The next example uses all of the standard arguments to quickly calculate a daily maximum value and spread it out across all indices.
library(MazamaRollUtils) # Extract vectors from our example dataset t <- example_pm25$datetime x <- example_pm25$pm25 # Calculate the left-aligned 24-hr max every hour, ignoring NA values max_24hr <- roll_max(x, width = 24, align = "left", by = 1, na.rm = TRUE) # Calculate the left-aligned daily max once every 24 hours, ignoring NA values max_daily_day <- roll_max(x, width = 24, align = "left", by = 24, na.rm = TRUE) # Spread the max_daily_day value out to every hour with a right-aligned look "back" max_daily_hour <- roll_max(max_daily_day, width = 24, align = "right", by = 1, na.rm = TRUE) # Plot with 3- and 24-hr rolling means layout(matrix(seq(3))) plot(t, max_24hr, col = 'red') points(t, x, pch = 16, cex = 0.5) title("Rolling 24-hr Max") plot(t, max_daily_day, col = 'red') points(t, x, pch = 16, cex = 0.5) title("Daily 24-hr Max") plot(t, max_daily_hour, col = 'red') points(t, x, pch = 16, cex = 0.5) title("Hourly Daily Max") layout(1)
The roll_mean()
function accepts a weights
argument that can be used to
create a weighted moving average. The next example demonstrates creation of
an exponential weighting function to be applied to our data.
library(MazamaRollUtils) # Extract vectors from our example dataset t <- example_pm25$datetime x <- example_pm25$pm25 # Create weights for a 9-element exponentially weighted window # See: https://en.wikipedia.org/wiki/Moving_average N <- 9 alpha <- 2/(N + 1) w <- (1-alpha)^(0:(N-1)) weights <- rev(w) # right aligned window EMA <- roll_mean(x, width = N, align = "right", weights = weights) # Plot Exponential Moving Average (EMA) plot(t, x, pch = 16, cex = 0.5) lines(t, EMA, col = 'red') title("9-Element Exponential Moving Average")
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