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heatwaveR

The heatwaveR package is a project-wide update to the RmarineHeatWaves package, which is itself a translation of the original Python code written by Eric C. J. Oliver. The heatwaveR package also uses the same naming conventions for objects, columns, and arguments as the Python code.

The heatwaveR R package contains the original functions from the RmarineHeatWaves package that calculate and display marine heatwaves (MHWs) according to the definition of Hobday et al. (2016) as well as calculating and visualising marine cold-spells (MCSs) as first introduced in Schlegel et al. (2017a). It also contains the functionality to calculate the categories of MHWs as outlined in Hobday et al. (2018).

This package does what RmarineHeatWaves does, but faster. The entire package has been deconstructed and modularised, and we are continuing to implement slow portions of the code in C++. This has alleviated the bottlenecks that slowed down the climatology creation portions of the code as well as generally creating an overall increase in the speed of the calculations. Currently the R code runs about as fast as the original python functions, at least in as far as applying it to single time series of temperatures. Readers familiar with both languages will know about the ongoing debate around the relative speed of the two languages. In our experience, R can be as fast as python, provided that attention is paid to finding ways to reduce the computational inefficiencies that stem from i) the liberal use of complex and inefficient non-atomic data structures, such as data frames; ii) the reliance on non-vectorised calculations such as loops; and iii) lazy (but convenient) coding that comes from drawing too heavily on the tidyverse suite of packages. We will continue to ensure that heatwaveR becomes more-and-more efficient so that it can be applied to large gridded data products with ease.

This new package was developed and released in order to better accommodate the inclusion of the definitions of atmospheric heatwaves in addition to MHWs. Additionally, heatwaveR also provides the first implementation of a definition for a ‘compound heatwave’. There are currently multiple different definitions for this type of event and each of which has arguments provided for it within the ts2clm() and detect_event() functions.

This package may be installed from CRAN by typing the following command into the console:

install.packages("heatwaveR")

Or the development version may be installed from GitHub with:

devtools::install_github("robwschlegel/heatwaveR")

The functions

FunctionDescription
ts2clm()Constructs seasonal and threshold climatologies as per the definition of Hobday et al. (2016).
detect_event()The main function which detects the events as per the definition of Hobday et al. (2016).
block_average()Calculates annual means for event metrics.
category()Applies event categories to the output of detect_event() based on Hobday et al. (2018).
exceedance()A function similar to detect_event() but that detects consecutive days above/below a given static threshold.
event_line()Creates a time series line graph of the heatwave or cold-spell results from detect_event().
lolli_plot()Creates a lolliplot time series of a selected event metric from the results generated by detect_event().
geom_flame()Creates flame polygons of heatwaves or cold-spells from a time series.
geom_lolli()Creates lolliplots from a time series of a selected event metric.

The package also provides data of observed SST records for three historical MHWs: the 2011 Western Australia event, the 2012 Northwest Atlantic event, and the 2003 Mediterranean event.

The heatwave metrics

The detect_event() function will return a list of two tibbles (see the tidyverse), climatology and event, which are the time series climatology and MHW (or MCS) events, respectively. The climatology contains the full time series of daily temperatures, as well as the the seasonal climatology, the threshold and various aspects of the events that were detected. The software was designed for detecting extreme thermal events, and the units specified below reflect that intended purpose. However, various other kinds of extreme events (e.g. rainfall) may be detected according to the ‘heatwave’ specifications, and if that is the case, the appropriate minDuration etc. and units of measurement need to be determined by the user.

Climatology metricDescription
doyJulian day (day-of-year). For non-leap years it runs 1…59 and 61…366, while leap years run 1…366. This column will be named differently if another name was specified to the doy argument.
tThe date of the temperature measurement. This column will be named differently if another name was specified to the x argument.
tempIf the software was used for the purpose for which it was designed, seawater temperature (deg. C) on the specified date will be returned. This column will of course be named differently if another kind of measurement was specified to the y argument.
seasClimatological seasonal cycle (deg. C).
threshSeasonally varying threshold (e.g., 90th percentile) (deg. C).
varVariance (standard deviation) per doy of temp (deg. C). (not returned by default as of v0.3.5)
threshCriterionBoolean indicating if temp exceeds thresh.
durationCriterionBoolean indicating whether periods of consecutive threshCriterion are >= minDuration.
eventBoolean indicating if all criteria that define a MHW or MCS are met.
event_noA sequential number indicating the ID and order of occurrence of the MHWs or MCSs.

The events are summarised using a range of event metrics:

Event metricDescription
event_noA sequential number indicating the ID and order of the events. This allows one to match/join results between the climatology and event outputs.
index_startRow number from the given time series where the event starts.
index_peakRow number from the given time series where the event peaks.
index_endRow number from the given time series where the event ends.
durationDuration of event (days).
date_startStart date of event (date).
date_peakDate of event peak (date).
date_endEnd date of event (date).
intensity_meanMean intensity (deg. C).
intensity_maxMaximum (peak) intensity (deg. C).
intensity_varIntensity variability (standard deviation) (deg. C).
intensity_cumulativeCumulative intensity (deg. C x days).
rate_onsetOnset rate of event (deg. C / day).
rate_declineDecline rate of event (deg. C / day).

intensity_max_relThresh, intensity_mean_relThresh, intensity_var_relThresh, and intensity_cumulative_relThresh are as above except relative to the threshold (e.g., 90th percentile) rather than the seasonal climatology.

intensity_max_abs, intensity_mean_abs, intensity_var_abs, and intensity_cumulative_abs are as above except as absolute magnitudes rather than relative to the seasonal climatology or threshold.

Note that rate_onset and rate_decline will return NA when the event begins/ends on the first/last day of the time series. This may be particularly evident when the function is applied to large gridded data sets. Although the other metrics do not contain any errors and provide sensible values, please take this into account in the interpretation of the output. It must also be noted that events whose date_peak occur on the same day as the date_start or date_end of the event will return small negative values. This tends to only occur in areas with persistent ice cover. The authors are currently thinking about how best to handle this exception.

The Vignettes

For detailed explanations and walkthroughs on the use of the heatwaveR package please click on the Vignettes tab in the toolbar above, or follow the links below:

The Marine Heatwave Tracker

To see the heatwaveR package in action, check out the Marine Heatwave Tracker website. This is a daily updating global analysis of where in the world marine heatwaves are occurring. It has near real-time information as well as historic data going back to January 1st, 1982 and uses the Hobday et al. (2018) colour scheme to show how intense the MHWs are.

Contributing to heatwaveR

To contribute to the package please follow the guidelines here.

Please use this link to report any bugs found.

Citing heatwaveR

Because heatwaveR is and always will be free to use open source software, its citation in scientific literature and other sources is the primary metric through which the continued development of this package is motivated for. Therefore, if the heatwaveR package is used in any analyses please acknowledge this through the following citation:

Robert W. Schlegel and Albertus J. Smit (2018). heatwaveR: A central algorithm for the detection of heatwaves and cold-spells. Journal of Open Source Software, 3(27), 821, https://doi.org/10.21105/joss.00821

The BibTeX citation may be accessed in R with:

citation("heatwaveR")

For a list of sources that have cited heatwaveR see the Citations tab in the toolbar at the top of this page. If you do not see your publication in the list of citations and would like it added please contact the developer (see below).

References

Hobday, A.J. et al. (2016). A hierarchical approach to defining marine heatwaves. Progress in Oceanography, 141, pp. 227-238.

Schlegel, R. W., Oliver, E. C. J., Wernberg, T. W., Smit, A. J. (2017a). Nearshore and offshore co-occurrences of marine heatwaves and cold-spells. Progress in Oceanography, 151, pp. 189-205.

Schlegel, R. W., Oliver, E. C., Perkins-Kirkpatrick, S., Kruger, A., Smit, A. J. (2017b). Predominant atmospheric and oceanic patterns during coastal marine heatwaves. Frontiers in Marine Science, 4, 323.

Hobday, A. J., Oliver, E. C. J., Sen Gupta, A., Benthuysen, J. A., Burrows, M. T., Donat, M. G., Holbrook, N. J., Moore, P. J., Thomsen, M. S., Wernberg, T., Smale, D. A. (2018). Categorizing and naming marine heatwaves. Oceanography 31(2).

Acknowledgements

The Python code was written by Eric C. J. Oliver.

Contributors to the Marine Heatwaves definition and its numerical implementation include Alistair J. Hobday, Lisa V. Alexander, Sarah E. Perkins, Dan A. Smale, Sandra C. Straub, Jessica Benthuysen, Michael T. Burrows, Markus G. Donat, Ming Feng, Neil J. Holbrook, Pippa J. Moore, Hillary A. Scannell, Alex Sen Gupta, and Thomas Wernberg.

The translation from Python to R was done by A. J. Smit and the graphing functions were contributed by Robert. W. Schlegel.

Contact

Robert W. Schlegel

Data Scientist

Laboratoire d’Océanographie de Villefranche-sur-Mer, LOV

Institut de la Mer de Villefranche, IMEV

robert.schlegel@imev-mer.fr

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install.packages('heatwaveR')

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0.4.5

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MIT + file LICENSE

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Last Published

January 7th, 2021

Functions in heatwaveR (0.4.5)

clim_calc

Calculate seasonal and threshold climatologies as well as the variance.
block_average

Calculate yearly means for event metrics.
clim_spread

Spead a time series wide to allow for a climatology to be calculated.
geom_lolli

Visualise a timeline of several event metrics as 'lollipops'.
detect_event

Detect heatwaves and cold-spells.
geom_flame

Create 'flame' polygons.
category

Calculate the categories of events.
event_line

Create a line plot of heatwaves or cold-spells.
Algiers

Daily maximum (tX) and minimum (tN) air temperatures for Algiers, Algeria.
exceedance

Detect consecutive days in exceedance of a given threshold.
make_whole

Constructs a continuous, uninterrupted time series of temperatures.
ts2clm

Make a climatology from a daily time series.
lolli_plot

Create a timeline of selected event metrics as 'lollipops'.
heatwaveR-package

heatwaveR: Detect Heatwaves and Cold-Spells
smooth_percentile

Detect the climatology for a time series.
sst_Med

NOAA Optimally Interpolated (OI) v2.1 daily 1/4 degree SST for the Mediterranean region.
na_interp

Pad NA gaps of user-defined width with interpolated values.
proto_event

Detect proto-events based on a chosen criterion (column).
make_whole_fast

Constructs a continuous, uninterrupted time series of temperatures (faster).
sst_WA

NOAA Optimally Interpolated (OI) v2.1 daily 1/4 degree SST for the Western Australian region.
sst_NW_Atl

NOAA Optimally Interpolated (OI) v2.1 daily 1/4 degree SST for the NW Atlantic region.