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| author | ecology |
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| date | Mon, 09 Jan 2023 13:37:37 +0000 |
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# ============================================================================== = # prosail # Lib_spectralindices.R # ============================================================================== = # PROGRAMMERS: # Jean-Baptiste FERET <jb.feret@teledetection.fr> # Florian de BOISSIEU <fdeboiss@gmail.com> # Copyright 2019/11 Jean-Baptiste FERET # ============================================================================== = # This Library includes aims at computing spectral indices from reflectance data # ============================================================================== = #" This function computes Area under curve for continuum removed reflectances #" See Malenovský et al. (2013) for details #" http://dx.doi.org/10.1016/j.rse.2012.12.015 #" #" @param refl RasterBrick, RasterStack or list. Raster bands in the order of sensorbands. #" @param sensorbands numeric. vector containing central wavelength for each spectral band in the image #" @param aucminmax list. wavelengths of lower and upper boundaries ("CRmin" and "CRmax") #" @param reflfactor numeric. multiplying factor used to write reflectance in image (==10000 for S2) #" #" @return aucval raster #" @export auc <- function(refl, sensorbands, aucminmax, reflfactor = 1) { aucbands <- list() aucbands[["CRmin"]] <- sensorbands[get_closest_bands(sensorbands, aucminmax[["CRmin"]])] aucbands[["CRmax"]] <- sensorbands[get_closest_bands(sensorbands, aucminmax[["CRmax"]])] bands <- get_closest_bands(sensorbands, aucbands) for (i in bands[["CRmin"]]:bands[["CRmax"]]) { if (is.na(match(i, bands))) { aucbands[[paste("B", i, sep = "")]] <- sensorbands[i] } } # compute continuum removal for all spectral bands cr <- cr_wl(refl = refl, sensorbands = sensorbands, crbands = aucbands, reflfactor = reflfactor) wl <- sort(unlist(aucbands), decreasing = FALSE) aucval <- 0.5 * (1 - cr[[1]]) * (wl[2] - wl[1]) for (i in 2:length(cr)) { aucval <- aucval + 0.5 * (2 - cr[[i - 1]] - cr[[i]]) * (wl[i + 1] - wl[i]) } aucval <- aucval + 0.5 * (1 - cr[[length(cr)]]) * (wl[i + 2] - wl[i + 1]) return(aucval) } #" This function extracts boundaries to be used to compute continuum from reflectance data #" #" @param refl RasterBrick, RasterStack or list. Raster bands in the order of sensorbands. #" @param sensorbands numeric. vector containing central wavelength for each spectral band in the image #" @param crbands list. list of spectral bands (central wavelength) including CRmin and CRmax #" @param reflfactor numeric. multiplying factor used to write reflectance in image ( == 10000 for S2) #" #" @return crminmax list. list of rasters corresponding to minimum and maximum wavelengths #" @export crbound <- function(refl, sensorbands, crbands, reflfactor = 1) { # get closest spectral bands from CR1 and CR2 bands <- get_closest_bands(sensorbands, list(crbands[["CRmin"]], crbands[["CRmax"]])) wl <- sensorbands[bands] # get equation for line going from CR1 to CR2 crminmax <- readrasterbands(refl = refl, bands = bands, reflfactor = reflfactor) names(crminmax) <- paste("wl_", as.character(wl), sep = "") return(crminmax) } #" This function extracts boundaries to be used to compute continuum from reflectance data #" #" @param refl RasterBrick, RasterStack or list. Raster bands in the order of sensorbands. #" @param sensorbands numeric. vector containing central wavelength for each spectral band in the image #" @param crbands list. list of spectral bands (central wavelength) including CRmin and CRmax #" @param reflfactor numeric. multiplying factor used to write reflectance in image ( == 10000 for S2) #" #" @return outlier_iqr numeric. band numbers of original sensor corresponding to S2 #" @importFrom progress progress_bar #" @export cr_wl <- function(refl, sensorbands, crbands, reflfactor = 1) { # Make sure CRmin and CRmax are correctly defined if (is.na(match("CRmin", names(crbands))) || is.na(match("CRmax", names(crbands)))) { stop("Please define CRmin and CRmax (CRmin<CRmax) as spectral bands in crbands") } if (crbands[["CRmax"]] < crbands[["CRmin"]]) { stop("Please define CRmin < CRmax in crbands") } # extract CRmin and CRmax crminmax <- crbound(refl, sensorbands, crbands, reflfactor = reflfactor) # extract other bands and compute CR crmin <- sensorbands[get_closest_bands(sensorbands, crbands[["CRmin"]])] crmax <- sensorbands[get_closest_bands(sensorbands, crbands[["CRmax"]])] crbands[["CRmin"]] <- NULL crbands[["CRmax"]] <- NULL cr <- list() # initiate progress bar pgbarlength <- length(crbands) pb <- progress_bar$new( format = "Computing continuum removal [:bar] :percent in :elapsedfull, estimated time remaining :eta", total = pgbarlength, clear = FALSE, width = 100) # computation for each band for (band in crbands) { pb$tick() bandrank <- get_closest_bands(sensorbands, band) raster2cr <- readrasterbands(refl = refl, bands = bandrank, reflfactor = reflfactor) cr[[as.character(band)]] <- computecr(wlmin = crmin, wlmax = crmax, wltarget = band, boundaries = crminmax, target = raster2cr) } return(cr) } #" This function computes continuum removal value for a spectral band of interest, #" based on lower and upper wavelengths corresponding to boundaries of the continuum #" #" @param wlmin numeric. wavelength of the spectral band corresponding to minimum boundary #" @param wlmax numeric. wavelength of the spectral band corresponding to maximum boundary #" @param wltarget numeric. wavelength of the spectral band for which cr is computed #" @param boundaries list. raster objects corresponding to minimum and maximum wavelengths #" @param target list. raster object corresponding target wavelength #" #" @return cr list. raster object corresponding to continuum removed value #" @export computecr <- function(wlmin, wlmax, wltarget, boundaries, target) { cr <- target / (boundaries[[1]] + (wltarget - wlmin) * (boundaries[[2]] - boundaries[[1]]) / (wlmax - wlmin)) return(cr) } #" this function produces a spectral index from an expression defining a spectral index #" #" @param refl RasterBrick, RasterStack or list. Raster bands in the order of sensorbands. #" @param sensorbands numeric. wavelength in nanometers of the spectral bands of refl. #" @param expressindex character. expression corresponding to the spectral index to compute #" @param listbands list. list of spectral bands defined in the "expressindex" variable #" @param reflfactor numeric. multiplying factor used to write reflectance in image ( == 10000 for S2) #" @param nameindex character. name for the index to be computed, provided in the raster layer #" #" @return numeric. band numbers of original sensor corresponding to S2 #" @export spectralindices_fromexpression <- function(refl, sensorbands, expressindex, listbands, reflfactor = 1, nameindex = NULL) { # define which bands to be used in the spectral index bands <- get_closest_bands(sensorbands, listbands) classraster <- class(refl) if (classraster == "RasterBrick" || classraster == "RasterStack" || classraster == "stars") { # if !reflfactor == 1 then apply a reflectance factor if (classraster == "stars") { refl <- refl[bands] } else { refl <- raster::subset(refl, bands) } if (!reflfactor == 1) { refl <- refl / reflfactor } } else if (is.list(refl)) { refl <- raster::stack(refl[bands]) # checks that all rasters have same crs/extent if (!reflfactor == 1) { refl <- refl / reflfactor } } else { stop("refl is expected to be a RasterStack, RasterBrick, Stars object or a list of rasters") } names(refl) <- gsub(pattern = "B", replacement = "Band", x = names(bands)) nbbands <- unique(as.numeric(gsub(pattern = "B", replacement = "", x = unlist(regmatches(expressindex, gregexpr("B[[:digit:]] + ", expressindex)))))) sortband <- sort(nbbands, index.return = TRUE, decreasing = TRUE) matches <- unique(unlist(regmatches(expressindex, gregexpr("B[[:digit:]] + ", expressindex))))[sortband$ix] replaces <- paste("refl[['Band", gsub(pattern = "B", replacement = "", x = matches), "']]", sep = "") expressindex_final <- expressindex for (bb in 1:seq_along(matches)) { expressindex_final <- gsub(pattern = matches[bb], replacement = replaces[bb], x = expressindex_final) } si <- eval(parse(text = expressindex_final)) if (!is.null(nameindex)) { names(si) <- nameindex } return(si) } #" this function aims at computing spectral indices from Sensor reflectance data in raster object #" it computes the spectral indices based on their computation with Sentinel-2 #" and assumes that the bands of the S2 data follow this order #" wavelength = {496.6, 560.0, 664.5, 703.9, 740.2, 782.5, 835.1, 864.8, 1613.7, 2202.4} #" Full description of the indices can be found here: #" https://www.sentinel-hub.com/eotaxonomy/indices #" #" @param refl RasterBrick, RasterStack or list. Raster bands in the order of sensorbands. #" @param sensorbands numeric. wavelength in nanometers of the spectral bands of refl. #" @param sel_indices list. list of spectral indices to be computed #" @param stackout logical. If TRUE returns a stack, otherwise a list of rasters. #" @param reflfactor numeric. multiplying factor used to write reflectance in image ( == 10000 for S2) #" #" @return list. includes #" - spectralindices: List of spectral indices computed from the reflectance initially provided #" - listindices: list of spectral indices computable with the function #" @importFrom methods is #" @importFrom raster stack brick #" @export computespectralindices_raster <- function(refl, sensorbands, sel_indices = "ALL", stackout = TRUE, reflfactor = 1) { s2bands <- c("B2" = 496.6, "B3" = 560.0, "B4" = 664.5, "B5" = 703.9, "B6" = 740.2, "B7" = 782.5, "B8" = 835.1, "B8A" = 864.8, "B11" = 1613.7, "B12" = 2202.4) spectralindices <- list() sen2s2 <- get_closest_bands(sensorbands, s2bands) classraster <- class(refl) if (classraster == "RasterBrick" || classraster == "RasterStack" || classraster == "stars") { # if !reflfactor == 1 then apply a reflectance factor if (classraster == "stars") { refl <- refl[sen2s2] } else { refl <- raster::subset(refl, sen2s2) } if (!reflfactor == 1) { refl <- refl / reflfactor } } else if (is.list(refl)) { refl <- raster::stack(refl[sen2s2]) # checks that all rasters have same crs/extent if (!reflfactor == 1) { refl <- refl / reflfactor } } else { stop("refl is expected to be a RasterStack, RasterBrick, Stars object or a list of rasters") } names(refl) <- names(sen2s2) indexall <- list() # inelegant but meeeeh listindices <- list("ARI1", "ARI2", "ARVI", "BAI", "BAIS2", "CCCI", "CHL_RE", "CRI1", "CRI2", "EVI", "EVI2", "GRVI1", "GNDVI", "IRECI", "LAI_SAVI", "MCARI", "mNDVI705", "MSAVI2", "MSI", "mSR705", "MTCI", "nBR_RAW", "NDI_45", "NDII", "NDSI", "NDVI", "NDVI_G", "NDVI705", "NDWI1", "NDWI2", "PSRI", "PSRI_NIR", "RE_NDVI", "RE_NDWI", "S2REP", "SAVI", "SIPI", "SR", "CR_SWIR") if (sel_indices[1] == "ALL") { sel_indices <- listindices } if ("ARI1" %in% sel_indices) { ari1 <- (1 / refl[["B3"]]) - (1 / refl[["B5"]]) spectralindices$ARI1 <- ari1 } if ("ARI2" %in% sel_indices) { ari2 <- (refl[["B8"]] / refl[["B2"]]) - (refl[["B8"]] / refl[["B3"]]) spectralindices$ARI2 <- ari2 } if ("ARVI" %in% sel_indices) { arvi <- (refl[["B8"]] - (2 * refl[["B4"]] - refl[["B2"]])) / (refl[["B8"]] + (2 * refl[["B4"]] - refl[["B2"]])) spectralindices$ARVI <- arvi } if ("BAI" %in% sel_indices) { bai <- (1 / ((0.1 - refl[["B4"]])**2 + (0.06 - refl[["B8"]])**2)) spectralindices$BAI <- bai } if ("BAIS2" %in% sel_indices) { bais2 <- (1 - ((refl[["B6"]] * refl[["B7"]] * refl[["B8A"]]) / refl[["B4"]])**0.5) * ((refl[["B12"]] - refl[["B8A"]]) / ((refl[["B12"]] + refl[["B8A"]])**0.5) + 1) spectralindices$BAIS2 <- bais2 } if ("CCCI" %in% sel_indices) { ccci <- ((refl[["B8"]] - refl[["B5"]]) / (refl[["B8"]] + refl[["B5"]])) / ((refl[["B8"]] - refl[["B4"]]) / (refl[["B8"]] + refl[["B4"]])) spectralindices$CCCI <- ccci } if ("CHL_RE" %in% sel_indices) { chl_re <- refl[["B5"]] / refl[["B8"]] spectralindices$CHL_RE <- chl_re } if ("CRI1" %in% sel_indices) { cri1 <- (1 / refl[["B2"]]) - (1 / refl[["B3"]]) spectralindices$CRI1 <- cri1 } if ("CRI2" %in% sel_indices) { cri2 <- (1 / refl[["B2"]]) - (1 / refl[["B5"]]) spectralindices$CRI2 <- cri2 } if ("EVI" %in% sel_indices) { evi <- 2.5 * (refl[["B8"]] - refl[["B4"]]) / ((refl[["B8"]] + 6 * refl[["B4"]] - 7.5 * refl[["B2"]] + 1)) spectralindices$EVI <- evi } if ("EVI2" %in% sel_indices) { evi2 <- 2.5 * (refl[["B8"]] - refl[["B4"]]) / (refl[["B8"]] + 2.4 * refl[["B4"]] + 1) spectralindices$EVI2 <- evi2 } if ("GRVI1" %in% sel_indices) { grvi1 <- (refl[["B4"]] - refl[["B3"]]) / (refl[["B4"]] + refl[["B3"]]) spectralindices$GRVI1 <- grvi1 } if ("GNDVI" %in% sel_indices) { gndvi <- (refl[["B8"]] - refl[["B3"]]) / (refl[["B8"]] + refl[["B3"]]) spectralindices$GNDVI <- gndvi } if ("IRECI" %in% sel_indices) { ireci <- (refl[["B7"]] - refl[["B4"]]) * (refl[["B6"]] / (refl[["B5"]])) spectralindices$IRECI <- ireci } if ("LAI_SAVI" %in% sel_indices) { lai_savi <- - log(0.371 + 1.5 * (refl[["B8"]] - refl[["B4"]]) / (refl[["B8"]] + refl[["B4"]] + 0.5)) / 2.4 spectralindices$LAI_SAVI <- lai_savi } if ("MCARI" %in% sel_indices) { mcari <- (1 - 0.2 * (refl[["B5"]] - refl[["B3"]]) / (refl[["B5"]] - refl[["B4"]])) spectralindices$MCARI <- mcari } if ("mNDVI705" %in% sel_indices) { mndvi705 <- (refl[["B6"]] - refl[["B5"]]) / (refl[["B6"]] + refl[["B5"]] - 2 * refl[["B2"]]) spectralindices$mNDVI705 <- mndvi705 } if ("MSAVI2" %in% sel_indices) { msavi2 <- ((refl[["B8"]] + 1) - 0.5 * sqrt(((2 * refl[["B8"]]) - 1)**2 + 8 * refl[["B4"]])) spectralindices$MSAVI2 <- msavi2 } if ("MSI" %in% sel_indices) { msi <- refl[["B11"]] / refl[["B8A"]] spectralindices$MSI <- msi } if ("mSR705" %in% sel_indices) { msr705 <- (refl[["B6"]] - refl[["B2"]]) / (refl[["B5"]] - refl[["B2"]]) spectralindices$mSR705 <- msr705 } if ("MTCI" %in% sel_indices) { mtci <- (refl[["B6"]] - refl[["B5"]]) / (refl[["B5"]] + refl[["B4"]]) spectralindices$MTCI <- mtci } if ("nBR_RAW" %in% sel_indices) { nbr_raw <- (refl[["B8"]] - refl[["B12"]]) / (refl[["B8"]] + refl[["B12"]]) spectralindices$nBR_RAW <- nbr_raw } if ("NDI_45" %in% sel_indices) { ndi_45 <- (refl[["B5"]] - refl[["B4"]]) / (refl[["B5"]] + refl[["B4"]]) spectralindices$NDI_45 <- ndi_45 } if ("NDII" %in% sel_indices) { ndii <- (refl[["B8A"]] - refl[["B11"]]) / (refl[["B8A"]] + refl[["B11"]]) spectralindices$NDII <- ndii } if ("NDSI" %in% sel_indices) { ndsi <- (refl[["B3"]] - refl[["B11"]]) / (refl[["B3"]] + refl[["B11"]]) spectralindices$NDSI <- ndsi } if ("NDVI" %in% sel_indices) { ndvi <- (refl[["B8"]] - refl[["B4"]]) / (refl[["B8"]] + refl[["B4"]]) spectralindices$NDVI <- ndvi } if ("NDVI_G" %in% sel_indices) { ndvi_g <- refl[["B3"]] * (refl[["B8"]] - refl[["B4"]]) / (refl[["B8"]] + refl[["B4"]]) spectralindices$NDVI_G <- ndvi_g } if ("NDVI705" %in% sel_indices) { ndvi705 <- (refl[["B6"]] - refl[["B5"]]) / (refl[["B6"]] + refl[["B5"]]) spectralindices$NDVI705 <- ndvi705 } if ("NDWI" %in% sel_indices) { ndwi <- (refl[["B3"]] - refl[["B8"]]) / (refl[["B3"]] + refl[["B8"]]) spectralindices$NDWI <- ndwi } if ("NDWI1" %in% sel_indices) { ndwi1 <- (refl[["B8A"]] - refl[["B11"]]) / (refl[["B8A"]] + refl[["B11"]]) spectralindices$NDWI1 <- ndwi1 } if ("NDWI2" %in% sel_indices) { ndwi2 <- (refl[["B8A"]] - refl[["B12"]]) / (refl[["B8A"]] + refl[["B12"]]) spectralindices$NDWI2 <- ndwi2 } if ("PSRI" %in% sel_indices) { psri <- (refl[["B4"]] - refl[["B2"]]) / (refl[["B5"]]) spectralindices$PSRI <- psri } if ("PSRI_NIR" %in% sel_indices) { psri_nir <- (refl[["B4"]] - refl[["B2"]]) / (refl[["B8"]]) spectralindices$PSRI_NIR <- psri_nir } if ("RE_NDVI" %in% sel_indices) { re_ndvi <- (refl[["B8"]] - refl[["B6"]]) / (refl[["B8"]] + refl[["B6"]]) spectralindices$RE_NDVI <- re_ndvi } if ("RE_NDWI" %in% sel_indices) { re_ndwi <- (refl[["B4"]] - refl[["B6"]]) / (refl[["B4"]] + refl[["B6"]]) spectralindices$RE_NDWI <- re_ndwi } if ("S2REP" %in% sel_indices) { s2rep <- 705 + 35 * (0.5 * (refl[["B8"]] + refl[["B5"]]) - refl[["B6"]]) / (refl[["B7"]] - refl[["B6"]]) spectralindices$S2REP <- s2rep } if ("SAVI" %in% sel_indices) { savi <- 1.5 * (refl[["B8"]] - refl[["B5"]]) / (refl[["B8"]] + refl[["B5"]] + 0.5) spectralindices$SAVI <- savi } if ("SIPI" %in% sel_indices) { sipi <- (refl[["B8"]] - refl[["B2"]]) / (refl[["B8"]] - refl[["B4"]]) spectralindices$SIPI <- sipi } if ("SR" %in% sel_indices) { sr <- refl[["B8"]] / refl[["B4"]] spectralindices$SR <- sr } if ("TCARI" %in% sel_indices) { sr <- refl[["B8"]] / refl[["B4"]] spectralindices$SR <- sr } if ("CR_SWIR" %in% sel_indices) { cr_swir <- refl[["B11"]] / (refl[["B8A"]] + (s2bands["B11"] - s2bands["B8A"]) * (refl[["B12"]] - refl[["B8A"]]) / (s2bands["B12"] - s2bands["B8A"])) spectralindices$CR_SWIR <- cr_swir } if (stackout) spectralindices <- raster::stack(spectralindices) res <- list("spectralindices" = spectralindices, "listindices" = listindices) return(res) } #" this function aims at computing spectral indices from Sensor reflectance data. #" it computes the spectral indices based on their computation with Sentinel-2 #" and assumes that the bands of the S2 data follow this order #" wavelength = {496.6, 560.0, 664.5, 703.9, 740.2, 782.5, 835.1, 864.8, 1613.7, 2202.4} #" Full description of the indices can be found here: #" https://www.sentinel-hub.com/eotaxonomy/indices #" #" @param refl numeric. reflectance dataset defined in matrix #" @param sel_indices list. list of spectral indices to be computed #" @param sensorbands numeric. wavelength of the spectral bands corresponding to the spectral index #" #" @return list. includes #" - spectralindices: List of spectral indices computed from the reflectance initially provided #" - listindices: list of spectral indices computable with the function #" @export computespectralindices_hs <- function(refl, sensorbands, sel_indices = "ALL") { spectralindices <- list() s2bands <- data.frame("B2" = 496.6, "B3" = 560.0, "B4" = 664.5, "B5" = 703.9, "B6" = 740.2, "B7" = 782.5, "B8" = 835.1, "B8A" = 864.8, "B11" = 1613.7, "B12" = 2202.4) sen2s2 <- get_closest_bands(sensorbands, s2bands) indexall <- list() # set zero vaues to >0 in order to avoid problems selzero <- which(refl == 0) refl[selzero] <- 0.005 if (dim(refl)[1] == length(sensorbands)) { refl <- t(refl) } # inelegant but meeeeh listindices <- list("ARI1", "ARI2", "ARVI", "BAI", "BAIS2", "CHL_RE", "CRI1", "CRI2", "EVI", "EVI2", "GRVI1", "GNDVI", "IRECI", "LAI_SAVI", "MCARI", "mNDVI705", "MSAVI2", "MSI", "mSR705", "MTCI", "nBR_RAW", "NDI_45", "NDII", "NDVI", "NDVI_G", "NDVI705", "NDWI1", "NDWI2", "PSRI", "PSRI_NIR", "RE_NDVI", "RE_NDWI", "S2REP", "SAVI", "SIPI", "SR", "CR_SWIR") if (sel_indices == "ALL") { sel_indices <- listindices } if ("ARI1" %in% sel_indices) { ari1 <- (1 / refl[, sen2s2[["B3"]]]) - (1 / refl[, sen2s2[["B5"]]]) spectralindices$ARI1 <- ari1 } if ("ARI2" %in% sel_indices) { ari2 <- (refl[, sen2s2[["B8"]]] / refl[, sen2s2[["B2"]]]) - (refl[, sen2s2[["B8"]]] / refl[, sen2s2[["B3"]]]) spectralindices$ARI2 <- ari2 } if ("ARVI" %in% sel_indices) { arvi <- (refl[, sen2s2[["B8"]]] - (2 * refl[, sen2s2[["B4"]]] - refl[, sen2s2[["B2"]]])) / (refl[, sen2s2[["B8"]]] + (2 * refl[, sen2s2[["B4"]]] - refl[, sen2s2[["B2"]]])) spectralindices$ARVI <- arvi } if ("BAI" %in% sel_indices) { bai <- (1 / ((0.1 - refl[, sen2s2[["B4"]]])**2 + (0.06 - refl[, sen2s2[["B8"]]])**2)) spectralindices$BAI <- bai } if ("BAIS2" %in% sel_indices) { bais2 <- (1 - ((refl[, sen2s2[["B6"]]] * refl[, sen2s2[["B7"]]] * refl[, sen2s2[["B8A"]]]) / refl[, sen2s2[["B4"]]])**0.5) * ((refl[, sen2s2[["B12"]]] - refl[, sen2s2[["B8A"]]]) / ((refl[, sen2s2[["B12"]]] + refl[, sen2s2[["B8A"]]])**0.5) + 1) spectralindices$BAIS2 <- bais2 } if ("CCCI" %in% sel_indices) { ccci <- ((refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B5"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B5"]]])) / ((refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B4"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B4"]]])) spectralindices$CCCI <- ccci } if ("CHL_RE" %in% sel_indices) { chl_re <- refl[, sen2s2[["B5"]]] / refl[, sen2s2[["B8"]]] spectralindices$CHL_RE <- chl_re } if ("CRI1" %in% sel_indices) { cri1 <- (1 / refl[, sen2s2[["B2"]]]) - (1 / refl[, sen2s2[["B3"]]]) spectralindices$CRI1 <- cri1 } if ("CRI2" %in% sel_indices) { cri2 <- (1 / refl[, sen2s2[["B2"]]]) - (1 / refl[, sen2s2[["B5"]]]) spectralindices$CRI2 <- cri2 } if ("EVI" %in% sel_indices) { evi <- 2.5 * (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B4"]]]) / ((refl[, sen2s2[["B8"]]] + 6 * refl[, sen2s2[["B4"]]] - 7.5 * refl[, sen2s2[["B2"]]] + 1)) spectralindices$EVI <- evi } if ("EVI2" %in% sel_indices) { evi2 <- 2.5 * (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B4"]]]) / (refl[, sen2s2[["B8"]]] + 2.4 * refl[, sen2s2[["B4"]]] + 1) spectralindices$EVI2 <- evi2 } if ("GRVI1" %in% sel_indices) { grvi1 <- (refl[, sen2s2[["B4"]]] - refl[, sen2s2[["B3"]]]) / (refl[, sen2s2[["B4"]]] + refl[, sen2s2[["B3"]]]) spectralindices$GRVI1 <- grvi1 } if ("GNDVI" %in% sel_indices) { gndvi <- (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B3"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B3"]]]) spectralindices$GNDVI <- gndvi } if ("IRECI" %in% sel_indices) { ireci <- (refl[, sen2s2[["B7"]]] - refl[, sen2s2[["B4"]]]) * (refl[, sen2s2[["B6"]]] / (refl[, sen2s2[["B5"]]])) spectralindices$IRECI <- ireci } if ("LAI_SAVI" %in% sel_indices) { lai_savi <- - log(0.371 + 1.5 * (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B4"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B4"]]] + 0.5)) / 2.4 spectralindices$LAI_SAVI <- lai_savi } if ("MCARI" %in% sel_indices) { mcari <- (1 - 0.2 * (refl[, sen2s2[["B5"]]] - refl[, sen2s2[["B3"]]]) / (refl[, sen2s2[["B5"]]] - refl[, sen2s2[["B4"]]])) spectralindices$MCARI <- mcari } if ("mNDVI705" %in% sel_indices) { mndvi705 <- (refl[, sen2s2[["B6"]]] - refl[, sen2s2[["B5"]]]) / (refl[, sen2s2[["B6"]]] + refl[, sen2s2[["B5"]]] - 2 * refl[, sen2s2[["B2"]]]) spectralindices$mNDVI705 <- mndvi705 } if ("MSAVI2" %in% sel_indices) { msavi2 <- ((refl[, sen2s2[["B8"]]] + 1) - 0.5 * sqrt(((2 * refl[, sen2s2[["B8"]]]) - 1)**2 + 8 * refl[, sen2s2[["B4"]]])) spectralindices$MSAVI2 <- msavi2 } if ("MSI" %in% sel_indices) { msi <- refl[, sen2s2[["B11"]]] / refl[, sen2s2[["B8"]]] spectralindices$MSI <- msi } if ("mSR705" %in% sel_indices) { msr705 <- (refl[, sen2s2[["B6"]]] - refl[, sen2s2[["B2"]]]) / (refl[, sen2s2[["B5"]]] - refl[, sen2s2[["B2"]]]) spectralindices$mSR705 <- msr705 } if ("MTCI" %in% sel_indices) { mtci <- (refl[, sen2s2[["B6"]]] - refl[, sen2s2[["B5"]]]) / (refl[, sen2s2[["B5"]]] + refl[, sen2s2[["B4"]]]) spectralindices$MTCI <- mtci } if ("nBR_RAW" %in% sel_indices) { nbr_raw <- (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B12"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B12"]]]) spectralindices$nBR_RAW <- nbr_raw } if ("NDI_45" %in% sel_indices) { ndi_45 <- (refl[, sen2s2[["B5"]]] - refl[, sen2s2[["B4"]]]) / (refl[, sen2s2[["B5"]]] + refl[, sen2s2[["B4"]]]) spectralindices$NDI_45 <- ndi_45 } if ("NDII" %in% sel_indices) { ndii <- (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B11"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B11"]]]) spectralindices$NDII <- ndii } if ("NDSI" %in% sel_indices) { ndisi <- (refl[, sen2s2[["B3"]]] - refl[, sen2s2[["B11"]]]) / (refl[, sen2s2[["B3"]]] + refl[, sen2s2[["B11"]]]) spectralindices$NDSI <- ndsi } if ("NDVI" %in% sel_indices) { ndvi <- (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B4"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B4"]]]) spectralindices$NDVI <- ndvi } if ("NDVI_G" %in% sel_indices) { ndvi_g <- refl[, sen2s2[["B3"]]] * (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B4"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B4"]]]) spectralindices$NDVI_G <- ndvi_g } if ("NDVI705" %in% sel_indices) { ndvi705 <- (refl[, sen2s2[["B6"]]] - refl[, sen2s2[["B5"]]]) / (refl[, sen2s2[["B6"]]] + refl[, sen2s2[["B5"]]]) spectralindices$NDVI705 <- ndvi705 } if ("NDWI1" %in% sel_indices) { ndwi1 <- (refl[, sen2s2[["B8A"]]] - refl[, sen2s2[["B11"]]]) / (refl[, sen2s2[["B8A"]]] + refl[, sen2s2[["B11"]]]) spectralindices$NDWI1 <- ndwi1 } if ("NDWI2" %in% sel_indices) { ndwi2 <- (refl[, sen2s2[["B8A"]]] - refl[, sen2s2[["B12"]]]) / (refl[, sen2s2[["B8A"]]] + refl[, sen2s2[["B12"]]]) spectralindices$NDWI2 <- ndwi2 } if ("PSRI" %in% sel_indices) { psri <- (refl[, sen2s2[["B4"]]] - refl[, sen2s2[["B2"]]]) / (refl[, sen2s2[["B5"]]]) spectralindices$PSRI <- psri } if ("PSRI_NIR" %in% sel_indices) { psri_nir <- (refl[, sen2s2[["B4"]]] - refl[, sen2s2[["B2"]]]) / (refl[, sen2s2[["B8"]]]) spectralindices$PSRI_NIR <- psri_nir } if ("RE_NDVI" %in% sel_indices) { re_ndvi <- (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B6"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B6"]]]) spectralindices$RE_NDVI <- re_ndvi } if ("RE_NDWI" %in% sel_indices) { re_ndwi <- (refl[, sen2s2[["B4"]]] - refl[, sen2s2[["B6"]]]) / (refl[, sen2s2[["B4"]]] + refl[, sen2s2[["B6"]]]) spectralindices$RE_NDWI <- re_ndwi } if ("S2REP" %in% sel_indices) { s2rep <- 705 + 35 * (0.5 * (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B5"]]]) - refl[, sen2s2[["B6"]]]) / (refl[, sen2s2[["B7"]]] - refl[, sen2s2[["B6"]]]) spectralindices$S2REP <- s2rep } if ("SAVI" %in% sel_indices) { savi <- 1.5 * (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B5"]]]) / (refl[, sen2s2[["B8"]]] + refl[, sen2s2[["B5"]]] + 0.5) spectralindices$SAVI <- savi } if ("SIPI" %in% sel_indices) { sipi <- (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B2"]]]) / (refl[, sen2s2[["B8"]]] - refl[, sen2s2[["B4"]]]) spectralindices$SIPI <- sipi } if ("SR" %in% sel_indices) { sr <- refl[, sen2s2[["B8"]]] / refl[, sen2s2[["B4"]]] spectralindices$SR <- sr } if ("CR_SWIR" %in% sel_indices) { cr_swir <- refl[, sen2s2[["B11"]]] / (refl[, sen2s2[["B8A"]]] + (s2bands$B11 - s2bands$B8A) * (refl[, sen2s2[["B12"]]] - refl[, sen2s2[["B8A"]]]) / (s2bands$B12 - s2bands$B8A)) spectralindices$CR_SWIR <- cr_swir } res <- list("spectralindices" = spectralindices, "listindices" = listindices) return(res) } #" this function identifies the bands of a given sensor with closest match to its spectral characteristics #" #" @param sensorbands numeric. wavelength in nanometer of the sensor of interest #" @param listbands numeric or list. Named vector or list of spectral bands corresponding to sensor #" #" @return numeric. band numbers of original sensor #" @export get_closest_bands <- function(sensorbands, listbands) { sapply(listbands, function(x) { b <- which.min(abs(sensorbands - x)) names(b) <- "" b }) } #" This function computes interquartile range (IQR) criterion, which can be used #" as a criterion for outlier detection #" #" @param distval numeric. vector of distribution of values #" @param weightirq numeric. weighting factor appplied to IRQ to define lower and upper boudaries for outliers #" #" @return outlier_iqr numeric. band numbers of original sensor corresponding to S2 #" @importFrom stats IQR quantile #" @export iqr_outliers <- function(distval, weightirq = 1.5) { iqr <- IQR(distval, na.rm = TRUE) range_iqr <- c(quantile(distval, 0.25, na.rm = TRUE), quantile(distval, 0.75, na.rm = TRUE)) outlier_iqr <- c(range_iqr[1] - weightirq * iqr, range_iqr[2] + weightirq * iqr) return(outlier_iqr) } #" This function selects bands from a raster or stars object #" #" @param refl RasterBrick, RasterStack or list. Raster bands in the order of sensorbands. #" @param bands numeric. rank of bands to be read in refl #" @param reflfactor numeric. multiplying factor used to write reflectance in image ( == 10000 for S2) #" #" @return robj list. R object (default is raster, stars if refl is stars object) #" @importFrom raster subset stack #" @export readrasterbands <- function(refl, bands, reflfactor = 1) { # get equation for line going from CR1 to CR2 classraster <- class(refl) if (classraster == "RasterBrick" || classraster == "RasterStack" || classraster == "stars") { # if !reflfactor == 1 then apply a reflectance factor if (classraster == "stars") { robj <- refl[bands] } else { robj <- raster::subset(refl, bands) } if (!reflfactor == 1) { robj <- robj / reflfactor } } else if (is.list(refl)) { robj <- raster::stack(refl[bands]) # checks that all rasters have same crs/extent if (!reflfactor == 1) { robj <- robj / reflfactor } } else { stop("refl is expected to be a RasterStack, RasterBrick, Stars object or a list of rasters") } return(robj) }