#' @title Create the indices database
#' @description The internal function checks if indices.json (the
#' database of spectral indices) already exists; if not, it
#' downloads source files and creates it.
#' Since this function depends on `xsltproc` executable (available
#' only for Linux), this function can be used only from from
#' Linux. It is not necessary, since a indices.json file is
#' present in the package.
#' @param xslt_path (optional) The path where to install `xsltml`,
#' an external `xsltproc` script used to convert MathML index formulas
#' to LaTeX (default: a subdirectory of the package).
#' @param json_path (optional) The path of the output JSON file.
#' *Warning*: to create a file which will be usable by the package,
#' this option must be left to NA (default location is within the
#' package installation). Edit this only to create the file in another
#' place for external use.
#' @param force (optional) Logical: if FALSE (default), the db is created only
#' if missing or not updated; if TRUE, it is created in any case.
#' @return NULL (the function is called for its side effects)
#' @author Luigi Ranghetti, phD (2019)
#' @references L. Ranghetti, M. Boschetti, F. Nutini, L. Busetto (2020).
#' "sen2r": An R toolbox for automatically downloading and preprocessing
#' Sentinel-2 satellite data. _Computers & Geosciences_, 139, 104473.
#' \doi{10.1016/j.cageo.2020.104473}, URL: \url{https://sen2r.ranghetti.info/}.
#' @note License: GPL 3.0
#' @import data.table
#' @importFrom XML htmlTreeParse xmlRoot readHTMLTable xmlAttrs saveXML
#' @importFrom jsonlite toJSON fromJSON
#' @importFrom stats runif
#' @importFrom utils capture.output download.file unzip packageVersion
#' @keywords internal
create_indices_db <- function(xslt_path = NA,
json_path = NA,
force = FALSE) {
# to avoid NOTE on check
. <- n_index <- name <- longname <- s2_formula <- type <- checked <- link <- a <- NULL
# check if indices.json already exists, and if the version is updated
# we assume that a new version of indices.json is created at every new ackage update
if (is.na(json_path)) {
json_path <- file.path(system.file("extdata/settings",package="sen2r"),"indices.json")
}
if (system.file("extdata/settings/indices.json", package="sen2r") == json_path) {
if (force == FALSE) {
return(invisible(NULL))
}
}
# check the presence of xsltproc
if (Sys.which("xsltproc")=="") {
print_message(
type="error",
"\"xsltproc\" was not found in your system; ",
"please install it or update your system PATH.")
}
# set XSLT path
if (is.na(xslt_path)) {
xslt_path <- file.path(dirname(attr(load_binpaths(), "path")),"xslt")
}
# if missing, download xsltml to convert from MathML to LaTeX: http://fhoerni.free.fr/comp/xslt.html
if (any(!file.exists(file.path(xslt_path,c("cmarkup.xsl","entities.xsl","glayout.xsl","mmltex.xsl","scripts.xsl","tables.xsl","tokens.xsl"))))) {
dir.create(xslt_path, recursive=FALSE, showWarnings=FALSE)
download.file("https://netix.dl.sourceforge.net/project/xsltml/xsltml/v.2.1.2/xsltml_2.1.2.zip",
file.path(xslt_path,"xsltml_2.1.2.zip"),
quiet = TRUE)
unzip(file.path(xslt_path,"xsltml_2.1.2.zip"), exdir=xslt_path)
unlink(file.path(xslt_path,"xsltml_2.1.2.zip"))
}
# Read HTML indices database from indexdatabase.de
idb_url <- "http://www.indexdatabase.de"
idb_s2indices_url <- file.path(idb_url,"db/is.php?sensor_id=96")
download.file(idb_s2indices_url, s2_path <- tempfile(), quiet = TRUE)
s2_html <- xmlRoot(htmlTreeParse(s2_path, useInternalNodes = FALSE))
s2_htmlinternal <- xmlRoot(htmlTreeParse(s2_path, useInternalNodes = TRUE))
s2_html_table <- s2_html[["body"]][["div"]][["table"]]
s2_htmlinternal_table <- s2_htmlinternal[["body"]][["div"]][["table"]]
unlink(s2_path)
s2_table <- data.table(readHTMLTable(s2_htmlinternal_table, header=TRUE, stringsAsFactors=FALSE)[,1:3])
setnames(s2_table, c( "Nr.\r\n ", "Name\r\n ","Abbrev.\r\n "),
c("n_index","longname","name"))
s2_table$link <- paste0(idb_url, sapply(seq_along(s2_html_table)[-1], function(x) {
xmlAttrs(s2_html_table[[x]][[2]][[1]])["href"]
}))
s2_formula_mathml <- lapply(seq_along(s2_html_table)[-1], function(x) {
s2_html_table[[x]][[5]][[1]]
})
s2_formula_mathml_general <- lapply(seq_along(s2_html_table)[-1], function(x) {
s2_html_table[[x]][[4]][[1]]
}) # this is used for automatic band substitution
# Build table
s2_table$s2_formula <- as.character(NA)
s2_table[,n_index:=as.integer(n_index)]
if (any(s2_table$n_index != seq_len(nrow(s2_table)))) {
print_message(
type="error",
"The index numbering in Index DataBase is altered; ",
"please report this to a maintainer.")
}
# clean database
n_index_toremove <- c()
# change name to some indices
s2_table[grep("MIR/NIR Normalized Difference",s2_table$longname),name:="NDVI2"]
s2_table[longname=="Transformed Soil Adjusted Vegetation Index 2",name:="TSAVI2"]
s2_table[longname=="Modified Soil Adjusted Vegetation Index",name:="MSAVI2"]
# Change names containing "/"
s2_table[,name:=gsub("/","-",name)]
# remove indices without name
n_index_toremove <- c(n_index_toremove, s2_table[name=="",n_index])
# replacing duplicated indices
n_index_toremove <- c(
n_index_toremove,
s2_table[longname %in% c(
"RDVI",
"RDVI2",
"Normalized Difference NIR/Green Green NDVI",
"Enhanced Vegetation Index 2"
),n_index])
# (duplicated_indices <- unique(s2_table$name[duplicated(s2_table$name)]))
# removing indices with incorrect formulas
n_index_toremove <- c(
n_index_toremove,
s2_table[name %in% c(
"CRI550","CRI700","GEMI","IR550","IR700","LWCI","mCRIG","mCRIRE","CCCI","Ctr6",
"ND800:680","NLI","RARSa1","RARSa2","RARSa3","RARSa4","RARSc3","RARSc4",
"mARI","NDVIc","RSR","SRSWIRI:NIR","SARVI","SQRT(IR:R)","TNDVI"
),n_index]) # TODO some indices can be reintegrated
# clean
n_index_toremove <- sort(as.integer(n_index_toremove))
s2_formula_mathml <- s2_formula_mathml[!s2_table$n_index %in% n_index_toremove]
s2_formula_mathml_general <- s2_formula_mathml_general[!s2_table$n_index %in% n_index_toremove]
s2_table <- s2_table[!n_index %in% n_index_toremove,]
## Convert MathML to LaTeX on each row, using external tool
parent_regex <- "\\{((?>[^{}]+)|(?R))*\\}"
max_iter = 7 # maximum numbero of iterations for nested fractions
for (sel_row in seq_len(nrow(s2_table))) {
saveXML(s2_formula_mathml[[sel_row]],
tmp_infile <- tempfile())
system(
paste0(
Sys.which("xsltproc")," ",
file.path(xslt_path,"mmltex.xsl")," ",
"\"",tmp_infile,"\" > ",
"\"",tmp_outfile <- tempfile(),"\""),
intern = Sys.info()["sysname"] == "Windows"
)
# convert manually from latex to formula
tmp_latex <- suppressWarnings(readLines(tmp_outfile))
tmp_latex <- gsub("^\\$ *(.*) *\\$$","\\1",tmp_latex) # remove math symbols
tmp_latex <- gsub("\\\\textcolor\\[rgb\\]\\{[0-9\\.\\,]+\\}", "\\\\var", tmp_latex) # RGB indications are variable names
tmp_latex <- gsub(paste0("\\\\mathrm",parent_regex), "\\1", tmp_latex, perl=TRUE) # remove mathrm
tmp_latex <- gsub("\\\\left\\|([^|]+)\\\\right\\|", "abs(\\1)", tmp_latex) # abs
tmp_latex <- gsub("\u00B7", "*", tmp_latex) # replace muddle point
tmp_latex <- gsub("\\\\times", "*", tmp_latex) # replace times
tmp_latex <- gsub("\\\\⁢", "*", tmp_latex) # remove invisibles multiplications
tmp_latex <- gsub("\u0096", "-band_", tmp_latex) # unicode START OF GUARDED AREA as "-"
tmp_latex <- gsub("\\\\var\\{([0-9][0-9a]?)\\}", "band\\_\\1", tmp_latex) # recognise band names
tmp_latex <- gsub("\\\\var\\{([^}]+)\\}", "par\\_\\1", tmp_latex) # recognise other elements as parameters
tmp_latex <- gsub("par\\_([^0-9A-Za-z])", "\\1", tmp_latex) # error in two indices
tmp_latex <- gsub("\\\\left\\(", "(", tmp_latex) # parenthesis
tmp_latex <- gsub("\\\\right\\)", ")", tmp_latex) # parenthesis
# remove temporary files
unlink(tmp_infile)
unlink(tmp_outfile)
n_iter <- 1
while (length(grep("[{}]", tmp_latex))>0 & n_iter<=max_iter) {
tmp_latex <- gsub(paste0("\\\\frac",parent_regex,parent_regex), "(\\1)/(\\2)", tmp_latex, perl=TRUE) # convert fractions
tmp_latex <- gsub(paste0("\\\\sqrt",parent_regex), "sqrt(\\1)", tmp_latex, perl=TRUE) # convert sqrt
tmp_latex <- gsub(paste0(parent_regex,"\\^",parent_regex),"power\\(\\1,\\2\\)", tmp_latex, perl=TRUE) # square
n_iter <- n_iter+1
}
s2_table[sel_row,"s2_formula"] <- tmp_latex
# print(sel_row)
}
# last manual corrections on names
s2_table[,s2_formula:=gsub("par\\_([0-9])", "band_\\1", s2_table$s2_formula)] # some bands were wrongly classified as parameters
s2_table$name[s2_table$name=="TCI"] <- "TCIdx" # in order not to mess with TCI True Color Image product
s2_table$name[s2_table$name=="NDSI"] <- "NDSaI" # in order not to mess with Normalized Difference Snow Index
# last manual corrections on formulas
s2_table[name=="ARVI", s2_formula := gsub("band_8a", "band_8", s2_formula)] # revert manual change on IDB
s2_table[name=="WDRVI", s2_formula := gsub("0.1", "par_a", s2_formula)] # set 0.1 as parameter
# rename parameters (A, B, ...)
s2_table[,s2_formula:=gsub("par\\_([aALyY]r?)", "par_a", s2_table$s2_formula)] # first parameters (a, A, ar, y, Y, L) -> "a"
s2_table[,s2_formula:=gsub("par\\_([bB])", "par_b", s2_table$s2_formula)] # second parameters (b, B) -> "b"
s2_table[,s2_formula:=gsub("par\\_([X])", "par_c", s2_table$s2_formula)] # third parameters ("X") -> "c"
## Test expressions
# build a data.frame with random values
test_df <- runif(17,0,1)
names(test_df) <- c(paste0("band_",c(1:12,"8a")),"par_a","par_b","par_c","par_d")
test_df <- as.data.frame(t(test_df))
# define power() as in numpy
power <- function(x,y){x^y}
test_results <-with(test_df,
sapply(s2_table$s2_formula,
function(x) {
tryCatch(eval(parse(text=x)),
error = function(y){return(y)},
warning = function(y){return(y)})
}
))
test_type <-with(test_df,
sapply(s2_table$s2_formula,
function(x) {
tryCatch(ifelse(is.numeric(eval(parse(text=x))),return("ok")),
error = function(y){return("error")},
warning = function(y){return("warning")})
}
))
test_out <- data.table("formula"=s2_table$s2_formula,
"n_index"=s2_table$n_index,
"index"=s2_table$name,
"output"=ifelse(test_type=="ok",test_results,NA),
"type"=test_type)
# # These indices contain errors:
# test_out[type=="error",]
# # for now, remove them.
# # TODO check them and correct manually
# # TODO2 check all the aoutmatic parsings (maybe expression do not provide errors but they are different from originals)
n_index_toremove <- test_out[type%in%c("error","warning"),n_index]
s2_formula_mathml <- s2_formula_mathml[!s2_table$n_index %in% n_index_toremove]
s2_formula_mathml_general <- s2_formula_mathml_general[!s2_table$n_index %in% n_index_toremove]
s2_table <- s2_table[!n_index %in% n_index_toremove,]
## Check indices manually
# (this is necessary because most of the indices is associated to wrong
# Sentinel-2 bands, and because parameter values are missing)
# logical: FALSE for not checked, TRUE for checked
s2_table$checked <- FALSE
# numerics: values for index parameters
s2_table$d <- s2_table$c <- s2_table$b <- s2_table$a <- as.numeric(NA)
# by default, make all these changes
# (only bands named as "RED", "BLUE" and "NIR" are changed, because
# these are the wrong ones, while normally bands named in other ways
# - like "700nm" - are correctly associated)
s2_table[grepl("RED",s2_formula_mathml_general),
s2_formula := gsub("band_5","band_4",s2_formula)] # B5 to B4 (Red)
s2_table[grepl("NIR",s2_formula_mathml_general),
s2_formula := gsub("band_9","band_8",s2_formula)] # B9 to B8 (NIR)
s2_table[grepl("BLUE",s2_formula_mathml_general),
s2_formula := gsub("band_1","band_2",s2_formula)] # B2 to B1 (Blue)
# set as checked for indices ok after previous changes
s2_table[name %in% c(
"NDVI","SAVI","MCARI","MCARI2","TCARI","ARVI","NDRE",
"BNDVI","GNDVI","NDII","TCIdx","MSAVI2","OSAVI",
"NBR","NDMI","WDRVI",#"EVI2",
"SIPI1", "PSSRb1", "NDII", "MSI", "EVI", "Chlred-edge", "ARI", # sentinel-hub
"MTVI2","MCARI-MTVI2","TCARI-OSAVI"
),checked:=TRUE]
# set default parameter values
s2_table[name=="SAVI", a:=0.5] # default value for L (here "a") parameter
s2_table[name=="ARVI", a:=1] # default value for gamma (here "a") parameter
s2_table[name=="WDRVI", a:=0.1] # default value for weighting coefficient "a" (0.1-0.2)
# add missing indices
s2_table_new <- rbindlist(list(
"NDFI" = data.frame(
n_index = 301,
longname = "Normalized Difference Flood Index B1B7",
name = "NDFI",
link = "https://doi.org/10.1371/journal.pone.0088741",
s2_formula = "(band_4-band_12)/(band_4+band_12)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">RED</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">SWIR2</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">RED</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">SWIR2</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"NDFI2" = data.frame(
n_index = 302,
longname = "Normalized Difference Flood Index B1B6",
name = "NDFI2",
link = "https://doi.org/10.1371/journal.pone.0088741",
s2_formula = "(band_4-band_11)/(band_4+band_11)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">RED</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">RED</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"NDSI" = data.frame(
n_index = 303,
longname = "Normalize Difference Snow Index",
name = "NDSI",
link = "https://doi.org/10.1007/978-90-481-2642-2_376",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">GREEN</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">GREEN</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
s2_formula = "(band_3-band_11)/(band_3+band_11)",
checked = TRUE
),
"NBR2" = data.frame(
n_index = 304,
longname = "Normalized Burn Ratio 2",
name = "NBR2",
link = "https://landsat.usgs.gov/sites/default/files/documents/si_product_guide.pdf",
s2_formula = "(band_11-band_12)/(band_11+band_12)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">SWIR2</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">SWIR2</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"MIRBI" = data.frame(
n_index = 305,
longname = "Mid-Infrared Burn Index",
name = "MIRBI",
link = "https://doi.org/10.1080/01431160110053185",
s2_formula = "(1E-3*band_12)-(9.8E-4*band_11)+2E-4",
checked = TRUE
),
"CSI" = data.frame(
n_index = 306,
longname = "Char Soil Index",
name = "CSI",
link = "https://doi.org/10.1016/j.rse.2005.04.014",
s2_formula = "(band_8)/(band_12)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">NIR</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">SWIR</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"CRred" = data.frame(
n_index = 307,
longname = "Continuum Removal in the red",
name = "CRred",
link = "Panigada et al. 2019 (in press)",
s2_formula = "clip((band_4)/(band_3+par_a*(band_6-band_3)),0,1)",
checked = TRUE
),
"CRred-2A" = data.frame(
n_index = 308,
longname = "Continuum Removal in the red (Sentinel-2A reflectances)",
name = "CRred-2A",
link = "Panigada et al. 2019 (in press)",
s2_formula = "clip((band_4)/(band_3+par_a*(band_6-band_3)),0,1)",
checked = FALSE,
a = ((664.6-559.8)/(740.5-559.8)) # reflectances for S2A
),
"CRred-2B" = data.frame(
n_index = 309,
longname = "Continuum Removal in the red (Sentinel-2B reflectances)",
name = "CRred-2B",
link = "Panigada et al. 2019 (in press)",
s2_formula = "clip((band_4)/(band_3+par_a*(band_6-band_3)),0,1)",
checked = FALSE,
a = ((664.9-559.0)/(739.1-559.0)) # reflectances for S2B
),
"CRred-0" = data.frame(
n_index = 310,
longname = "Continuum Removal in the red (standard reflectances)",
name = "CRred-0",
link = "Panigada et al. 2019 (in press)",
s2_formula = "clip((band_4)/(band_3+par_a*(band_6-band_3)),0,1)",
checked = FALSE,
a = ((665-560)/(740-560)) # standard reflectances
),
"BDred" = data.frame(
n_index = 311,
longname = "Band Depth in the red",
name = "BDred",
link = "Panigada et al. 2019 (in press)",
s2_formula = "clip(1-(band_4)/(band_3+par_a*(band_6-band_3)),0,1)",
checked = TRUE
),
"BDred-2A" = data.frame(
n_index = 312,
longname = "Band Depth in the red (Sentinel-2A reflectances)",
name = "BDred-2A",
link = "Panigada et al. 2019 (in press)",
s2_formula = "clip(1-(band_4)/(band_3+par_a*(band_6-band_3)),0,1)",
checked = FALSE,
a = ((664.6-559.8)/(740.5-559.8)) # reflectances for S2A
),
"BDred-2B" = data.frame(
n_index = 313,
longname = "Band Depth in the red (Sentinel-2B reflectances)",
name = "BDred-2B",
link = "Panigada et al. 2019 (in press)",
s2_formula = "clip(1-(band_4)/(band_3+par_a*(band_6-band_3)),0,1)",
checked = FALSE,
a = ((664.9-559.0)/(739.1-559.0)) # reflectances for S2B
),
"BDred-0" = data.frame(
n_index = 314,
longname = "Band Depth in the red (standard reflectances)",
name = "BDred-0",
link = "Panigada et al. 2019 (in press)",
s2_formula = "clip(1-(band_4)/(band_3+par_a*(band_6-band_3)),0,1)",
checked = FALSE,
a = ((665-560)/(740-560)) # standard reflectances
),
"CRred2" = data.frame(
n_index = 315,
longname = "Continuum Removal in the red 2",
name = "CRred2",
link = "",
s2_formula = "clip((((par_b-par_a)*(band_4+band_3)+(par_c-par_b)*(band_5+band_4)+(par_d-par_c)*(band_6+band_5))/((par_d-par_a)*(band_6+band_3))),0,1)",
checked = FALSE
),
"CRred2-2A" = data.frame(
n_index = 316,
longname = "Continuum Removal in the red 2 (Sentinel-2A reflectances)",
name = "CRred2-2A",
link = "",
s2_formula = "clip((((par_b-par_a)*(band_4+band_3)+(par_c-par_b)*(band_5+band_4)+(par_d-par_c)*(band_6+band_5))/((par_d-par_a)*(band_6+band_3))),0,1)",
checked = FALSE,
a = 559.8, b = 664.6, c = 704.1, d = 740.5 # reflectances for S2A
),
"CRred2-2B" = data.frame(
n_index = 317,
longname = "Continuum Removal in the red 2 (Sentinel-2B reflectances)",
name = "CRred2-2B",
link = "",
s2_formula = "clip((((par_b-par_a)*(band_4+band_3)+(par_c-par_b)*(band_5+band_4)+(par_d-par_c)*(band_6+band_5))/((par_d-par_a)*(band_6+band_3))),0,1)",
checked = FALSE,
a = 559.0, b = 664.9, c = 703.8, d = 739.1 # reflectances for S2B
),
"CRred2-0" = data.frame(
n_index = 318,
longname = "Continuum Removal in the red 2 (standard reflectances)",
name = "CRred2-0",
link = "",
s2_formula = "clip((((par_b-par_a)*(band_4+band_3)+(par_c-par_b)*(band_5+band_4)+(par_d-par_c)*(band_6+band_5))/((par_d-par_a)*(band_6+band_3))),0,1)",
checked = FALSE,
a = 560, b = 665, c = 704, d = 740 # standard reflectances
),
"NDWI" = data.frame(
n_index = 319,
longname = "Normalized Difference Water Index",
name = "NDWI",
link = "https://www.sentinel-hub.com/eoproducts/ndwi-normalized-difference-water-index",
s2_formula = "(band_8-band_11)/(band_8+band_11)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">NIR</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">NIR</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"NDWI2" = data.frame(
n_index = 320,
longname = "Normalized Difference Water Index 2",
name = "NDWI2",
link = "https://www.tandfonline.com/doi/abs/10.1080/01431169608948714",
s2_formula = "(band_3-band_8)/(band_3+band_8)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">GREEN</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">NIR</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">GREEN</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">NIR</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"NDVIre" = data.frame(
n_index = 321,
longname = "Red-edge-based Normalized Difference Vegetation Index",
name = "NDVIre",
link = "https://doi.org/10.1016/S0034-4257(03)00131-7",
s2_formula = "(band_5-band_4)/(band_5+band_4)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">Rededge1</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">RED</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">Rededge1</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">RED</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"NDBI" = data.frame(
n_index = 322,
longname = "Normalized Difference Built-up Index",
name = "NDBI",
link = "https://doi.org/10.1080/01431160304987",
s2_formula = "(band_11-band_8)/(band_11+band_8)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">NIR</mi>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">NIR</mi>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"Rcc" = data.frame(
n_index = 323,
longname = "Red Chromatic Coordinate",
name = "Rcc",
link = "https://doi.org/10.1016/j.agrformet.2011.09.009",
s2_formula = "band_4 / (band_2 + band_3 + band_4)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mi mathcolor=\"#443399\">RED</mi>\n </mrow>\n <mrow>\n <mi mathcolor=\"#443399\">RED</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">GREEN</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">BLUE</mi>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"Gcc" = data.frame(
n_index = 324,
longname = "Green Chromatic Coordinate",
name = "Gcc",
link = "https://doi.org/10.1016/j.agrformet.2011.09.009",
s2_formula = "band_3 / (band_2 + band_3 + band_4)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mi mathcolor=\"#443399\">GREEN</mi>\n </mrow>\n <mrow>\n <mi mathcolor=\"#443399\">RED</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">GREEN</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">BLUE</mi>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"Bcc" = data.frame(
n_index = 325,
longname = "Blue Chromatic Coordinate",
name = "Bcc",
link = "https://doi.org/10.1016/j.agrformet.2011.09.009",
s2_formula = "band_2 / (band_2 + band_3 + band_4)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mi mathcolor=\"#443399\">BLUE</mi>\n </mrow>\n <mrow>\n <mi mathcolor=\"#443399\">RED</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">GREEN</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">BLUE</mi>\n </mrow>\n </mfrac>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"ExG" = data.frame(
n_index = 326,
longname = "Excess Green",
name = "ExG",
link = "https://doi.org/10.1016/j.agrformet.2011.09.009",
s2_formula = "2 * band_3 - (band_2 + band_4)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mn>2</mn>\n <mo>&InvisibleTimes;</mo>\n <mi mathcolor=\"#443399\">GREEN</mi>\n <mo>-</mo>\n <mo>(</mo>\n <mi mathcolor=\"#443399\">RED</mi>\n <mo>+</mo>\n <mi mathcolor=\"#443399\">BLUE</mi>\n <mo>)</mo>\n </mrow>\n</math>",
checked = TRUE,
a = NA, b = NA, x = NA
),
"NMDI" = data.frame(
n_index = 327,
longname = "Normalized Multi-band Drought Index",
name = "NMDI",
link = "https://doi.org/10.1029/2007GL031021",
s2_formula = "(band_8 - band_11 + band_12) / (band_8 + band_11 - band_12)",
s2_formula_mathml = "<math xmlns=\"http://www.w3.org/1998/Math/MathML\">\n <mrow>\n <mfrac>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">NIR</mi>\n <mo>-</mo>\n <mrow>\n <mo>(</mo>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">SWIR2</mi>\n </mrow>\n </mrow>\n <mo>)</mo>\n </mrow>\n </mrow>\n </mrow>\n </mrow>\n <mrow>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">NIR</mi>\n <mo>+</mo>\n <mrow>\n <mo>(</mo>\n <mrow>\n <mrow>\n <mi mathcolor=\"#443399\">SWIR1</mi>\n <mo>-</mo>\n <mi mathcolor=\"#443399\">SWIR2</mi>\n </mrow>\n </mrow>\n <mo>)</mo>\n </mrow>\n </mrow>\n </mrow>\n </mrow>\n </mfrac>\n </mrow>\n</math>\n",
checked = TRUE,
a = NA, b = NA, x = NA
)
), fill=TRUE)
s2_table_new[,n_index:=as.integer(n_index)]
s2_table_new[,longname:=as.character(longname)]
s2_table_new[,name:=as.character(name)]
s2_table_new[,link:=as.character(link)]
s2_table_new[,s2_formula:=as.character(s2_formula)]
s2_table_new[,s2_formula_mathml:=as.character(s2_formula_mathml)]
s2_table <- rbind(s2_table, s2_table_new, fill=TRUE)
# add empty elements in MathML formulas
for (i in length(s2_formula_mathml) + seq_len(nrow(s2_table) - length(s2_formula_mathml))) {
s2_formula_mathml[[i]] <- if (!is.na(s2_table$s2_formula_mathml[i])) {
xmlRoot(
htmlTreeParse(s2_table$s2_formula_mathml[i], useInternalNodes = FALSE)
)[["body"]][["math"]]
} else {
NA
}
s2_formula_mathml_general[[i]] <- s2_formula_mathml[[i]]
}
## Convert in JSON
# convert MathML to character
s2_table$s2_formula_mathml <- sapply(
s2_formula_mathml_general, # replaced from s2_formula_mathml in order not to show uncorrect band numbers
function(x) {
if (is(x, "XMLNode")) {
paste(capture.output(print(x)), collapse="\n")
} else {
""
}
}
)
json_table <- list(
"indices" = s2_table,
"pkg_version" = as.character(packageVersion("sen2r")),
"creation_date" = as.character(Sys.time())
)
writeLines(jsonlite::toJSON(json_table, digits=NA, pretty=TRUE), json_path)
return(invisible(NULL))
}
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