## ----install, eval = FALSE---------------------------------------------------- # install.packages("RHRV", dependencies = TRUE) ## ----installDownloaded, eval = FALSE------------------------------------------ # setwd(sourceDirectory) # install.packages("RHRV_XXX",repos = NULL) ## ----library, message=FALSE, warning=FALSE------------------------------------ library('RHRV') ## ----accessingData, eval=FALSE------------------------------------------------ # # HRVData structure containing the heart beats # data("HRVData") # # HRVData structure storing the results of processing the # # heart beats: the beats have been filtered, interpolated, ... # data("HRVProcessedData") ## ----includeFigure, echo=FALSE, fig.align='center',fig.cap="The most important fields stored in the *HRVData* structure"---- knitr::include_graphics("figures/basicHRVData.png") ## ----creation, eval=TRUE------------------------------------------------------ hrv.data = CreateHRVData() hrv.data = SetVerbose(hrv.data, TRUE ) ## ----loading------------------------------------------------------------------ hrv.data = LoadBeatAscii(hrv.data, "example.beats", RecordPath = "beatsFolder") ## ----derivating--------------------------------------------------------------- hrv.data = BuildNIHR(hrv.data) ## ----filtering---------------------------------------------------------------- hrv.data = FilterNIHR(hrv.data) ## ----interpolating------------------------------------------------------------ # Note that it is not necessary to specify freqhr since it matches with # the default value: 4 Hz hrv.data = InterpolateNIHR(hrv.data, freqhr = 4) ## ----plottingHR, fig.align="center",fig.width=5,fig.height=4------------------ PlotNIHR(hrv.data, main = "niHR") ## ----timeAnalysis, eval=FALSE------------------------------------------------- # hrv.data = CreateTimeAnalysis(hrv.data, size = 300, # interval = 7.8125) ## ----completeTimeAnalysis----------------------------------------------------- hrv.data = CreateHRVData() hrv.data = SetVerbose(hrv.data,FALSE) hrv.data = LoadBeatAscii(hrv.data,"example.beats","beatsFolder") hrv.data = BuildNIHR(hrv.data) hrv.data = FilterNIHR(hrv.data) hrv.data = SetVerbose(hrv.data,TRUE) hrv.data = CreateTimeAnalysis(hrv.data,size=300,interval = 7.8125) # We can access "raw" data... let's print separately, the SDNN # parameter cat("The SDNN has a value of ",hrv.data$TimeAnalysis[[1]]$SDNN," msec.\n") ## ----creatingFreq------------------------------------------------------------- hrv.data = CreateFreqAnalysis(hrv.data) ## ----STFTanalysis------------------------------------------------------------- hrv.data = CreateHRVData( ) hrv.data = SetVerbose(hrv.data,FALSE) hrv.data = LoadBeatAscii(hrv.data,"example.beats","beatsFolder") hrv.data = BuildNIHR(hrv.data) hrv.data = FilterNIHR(hrv.data) hrv.data = InterpolateNIHR (hrv.data, freqhr = 4) hrv.data = CreateFreqAnalysis(hrv.data) hrv.data = SetVerbose(hrv.data,TRUE) # Note that it is not necessary to write the boundaries # for the frequency bands, since they match # the default values hrv.data = CalculatePowerBand(hrv.data , indexFreqAnalysis = 1, size = 300, shift = 30, type = "fourier", ULFmin = 0, ULFmax = 0.03, VLFmin = 0.03, VLFmax = 0.05, LFmin = 0.05, LFmax = 0.15, HFmin = 0.15, HFmax = 0.4 ) ## ----STFTanalysis2, eval= FALSE----------------------------------------------- # hrv.data = CalculatePowerBand(hrv.data, indexFreqAnalysis= 1, # size = 300, shift = 30) ## ----waveletAnalysis---------------------------------------------------------- hrv.data = CreateHRVData( ) hrv.data = SetVerbose(hrv.data,FALSE) hrv.data = LoadBeatAscii(hrv.data,"example.beats","beatsFolder") hrv.data = BuildNIHR(hrv.data) hrv.data = FilterNIHR(hrv.data) hrv.data = InterpolateNIHR (hrv.data, freqhr = 4) hrv.data = CreateFreqAnalysis(hrv.data) hrv.data = SetVerbose(hrv.data,TRUE) # Note that it is not necessary to write the boundaries # for the frequency bands, since they match the default values hrv.data = CalculatePowerBand( hrv.data , indexFreqAnalysis = 1, type = "wavelet", wavelet = "la8", bandtolerance = 0.01, relative = FALSE, ULFmin = 0, ULFmax = 0.03, VLFmin = 0.03, VLFmax = 0.05, LFmin = 0.05, LFmax = 0.15, HFmin = 0.15, HFmax = 0.4 ) ## ----echo=FALSE--------------------------------------------------------------- hrv.data = CreateHRVData( ) hrv.data = SetVerbose(hrv.data, FALSE) hrv.data = LoadBeatAscii(hrv.data,"example.beats","beatsFolder") hrv.data = BuildNIHR(hrv.data) hrv.data = FilterNIHR(hrv.data) hrv.data = InterpolateNIHR(hrv.data, freqhr = 4) ## ----bothAnalysis,message=FALSE----------------------------------------------- # ... # create structure, load beats, filter and interpolate hrv.data = CreateFreqAnalysis(hrv.data) hrv.data = SetVerbose(hrv.data, FALSE) # use freqAnalysis number 1 for perfoming # Fourier analysis. This time, we do not # write the band's boundaries hrv.data = CalculatePowerBand(hrv.data , indexFreqAnalysis = 1, size = 300, shift = 30, sizesp = 2048, type = "fourier") # use freqAnalysis number 2 for perfoming # wavelet analysis. Note the indexFreqAnalysis = 2!!! hrv.data = CreateFreqAnalysis(hrv.data) hrv.data = CalculatePowerBand(hrv.data, indexFreqAnalysis= 2, type = "wavelet", wavelet = "la8", bandtolerance = 0.01, relative = FALSE) ## ----plottingFreqFourier,fig.align="center", fig.width=6,fig.height=6--------- # Plotting Fourier analysis PlotPowerBand(hrv.data, indexFreqAnalysis = 1, ymax = 200, ymaxratio = 1.7) ## ----plottingFreqWavelet,fig.align="center", fig.width=6, fig.height=6-------- # Plotting wavelet analysis PlotPowerBand(hrv.data, indexFreqAnalysis = 2, ymax = 700, ymaxratio = 50)