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% Generated by roxygen2: do not edit by hand
% Please edit documentation in R/readBrukerFlexFile-functions.R
\name{readBrukerFlexFile}
\alias{readBrukerFlexFile}
\title{Reads mass spectrometry data in Bruker Daltonics XMASS format.}
\usage{
readBrukerFlexFile(fidFile, removeMetaData = FALSE, useHpc = TRUE,
filterZeroIntensities = FALSE, keepNegativeIntensities = FALSE,
verbose = FALSE)
}
\arguments{
\item{fidFile}{\code{character}, path to \emph{fid} file which should be
read.}
\item{removeMetaData, }{\code{logical}, to calculate mass data a lot of meta
data are needed. To save memory they could be deleted after calculation.}
\item{useHpc}{\code{logical}, should Bruker Daltonics' High Precision
Calibration be used if available?
(see also: \code{\link[readBrukerFlexData]{.hpc}})}
\item{filterZeroIntensities}{\code{logical}, don't change it.
If \code{TRUE} all intensities equal \code{0.0} are removed.
(see also: \sQuote{Details} section)}
\item{keepNegativeIntensities}{\code{logical}, don't change it.
If \code{FALSE} all intensities less than zero are replaced by
zero.
(see also: \sQuote{Details} section)}
\item{verbose}{\code{logical}, print verbose messages?}
}
\value{
A \code{list} of spectra and metadata.
\itemize{
\item{\code{spectrum$mass}: }{A vector of calculated mass.}
\item{\code{spectrum$tof}: }{A vector of time-of-flight data.}
\item{\code{spectrum$intensity}: }{A vector of intensity values.}
\item{\code{metaData}: }{A list of metaData depending on read spectrum.}
}
}
\description{
This function reads mass spectrometry data in Bruker Daltonics XMASS format
used by Bruker Daltonics mass spectrometer of *flex series (autoflex,
microflex, ultraflex).
}
\details{
\code{readBrukerFlexFile} has to import the following data to calculating
mass from \emph{acqu} file:\cr
\tabular{lll}{
acqu-value \tab becomes metaData \tab description \cr
$BYTORDA \tab metaData$byteOrder \tab endianness of fid file \cr
$TD \tab metaData$number \tab total number of measured time periods \cr
$DELAY \tab metaData$timeDelay \tab first measured intensity after
\emph{metaData$timeDelay} ns \cr
$DW \tab metaData$timeDelta \tab ns between measured time periods \cr
$ML1 \tab metaData$calibrationConstants[1] \tab mass calibration constant \cr
$ML2 \tab metaData$calibrationConstants[2] \tab mass calibration constant \cr
$ML3 \tab metaData$calibrationConstants[3] \tab mass calibration constant \cr
}
If High Precision Calibration (HPC) is used, \code{readBrukerFlexFile} needs:
\tabular{lll}{
acqu-value \tab becomes metaData \tab description \cr
$HPClBHi \tab metaData$hpc$limits[\dQuote{maxMass}] \tab upper mass
threshold \cr
$HPClBLo \tab metaData$hpc$limits[\dQuote{minMass}] \tab lower mass
threshold \cr
$HPClOrd \tab metaData$hpc$order \tab polynomial order \cr
$HPClUse \tab metaData$hpc$use \tab maybe using of HPC? (seems to be always
\dQuote{yes} in our test data) \cr
$HPCStr \tab metaData$hpc$coefficients \tab polynomial coefficients in a
string \cr
}
\code{readBrukerFlexFile} tries also to import [optional]: \cr
\tabular{lll}{
acqu-value \tab becomes metaData \tab description \cr
DATATYPE \tab metaData$dataType \tab e.g CONTINUOUS MASS SPECTRUM \cr
SPECTROMETER/DATASYSTEM \tab metaData$dataSystem \tab
e.g. Bruker Flex Series \cr
.SPECTROMETER TYPE \tab metaData$spectrometerType \tab e.g. TOF \cr
.INLET \tab metaData$inlet \tab DIRECT \cr
.IONIZATION MODE \tab metaData$ionizationMode \tab e.g. LD+ \cr
$DATE \tab metaData$date \tab same as $AQ_DATE but often only "0" \cr
$ACQMETH \tab metaData$acquisitionMethod \tab path to method file \cr
$AQ_DATE \tab metaData$acquisitionDate \tab acquisition date \cr
$AQ_mod \tab metaData$acquisitionMode \tab acquisition mode \cr
$AQOP_m \tab metaData$acquisitionOperatorMode, metaData$tofMode \tab
LINEAR / REFLECTOR \cr
$ATTEN \tab metaData$laserAttenuation \tab laser beam attenuation \cr
$CMT[1:4] \tab metaData$comments \tab comments \cr
$DEFLON \tab metaData$deflection \tab deflection ON/OFF \cr
$DIGTYP \tab metaData$digitizerType \tab type of digitizer \cr
$DPCAL1 \tab metaData$deflectionPulserCal1 \tab deflection pulser cal 1 \cr
$DPMASS \tab metaData$deflectionPulserMass \tab deflection pulser mass \cr
$FCVer \tab metaData$flexControlVersion \tab Version of
Bruker Daltonics FlexControl software \cr
$ID_raw \tab metaData$id \tab spectrum id \cr
$INSTRUM \tab metaData$instrument \tab e.g. AUTOFLEX \cr
$InstrID \tab metaData$instrumentId \tab ID of mass spectrometer \cr
$InstTyp \tab metaData$instrumentType \tab instrument type \cr
$Lift1 \tab metaData$lift[1] \tab LIFT constant? \cr
$Lift2 \tab metaData$lift[2] \tab LIFT constant? \cr
$Masserr \tab metaData$massError \tab initial mass error in ppm \cr
$NoSHOTS \tab metaData$laserShots \tab number of applied laser shots \cr
$PATCHNO \tab metaData$patch \tab sample postion on target \cr
$PATH \tab metaData$path \tab original file path
(on Bruker *flex series controller PC) \cr
$REPHZ \tab metaData$laserRepetition \tab laser repetition rate in Hz \cr
$SPOTNO \tab metaData$spot \tab same as \emph{$PATCHNO}
(in older files often empty, that's why \code{readBrukerFlexFile}
uses \emph{$PATHNO} instead) \cr
$SPType \tab metaData$spectrumType \tab e.g. TOF \cr
$TgIDS \tab metaData$target$id \tab target ids \cr
$TgCount \tab metaData$target$count \tab number of measurements
with this target \cr
$TgSer \tab metaData$target$serialNumber \tab target serial number \cr
$TgTyp \tab metaData$target$typeNumber \tab target type number \cr
$TLift \tab metaData$tlift \tab LIFT constant? \cr
}
import from file path:
\tabular{lll}{
value \tab becomes metaData \tab description \cr
full current path to fid file \tab metaData$file \tab
path on local machine \cr
sample name \tab metaData$sampleName \tab - \cr
}
\code{filterZeroIntensities}: Change default value is \bold{not recommended}!
If \code{TRUE} all intensities equal zero are removed.
This parameter exists only to be compatible to
Bruker Daltonics CompassXport's mzXML export function. For details see:
\sQuote{Release Notes for CompassXport 3.0.3},
cap. 6 \sQuote{Filtering of Zero Intensities}:
\dQuote{Bruker Daltonics' Acquisition Software will compress Analysis raw
data. To save on operation time and to keep export file sizes small,
CompassXport 3.0.3 will filter out zero (0.0) intensities
when exporting to mzXML or mzData \ldots}
\code{keepNegativeIntensities}: Change default value is
\bold{not recommended}! If \code{TRUE} negative intensity values are not
replaced by zero. This parameter exists only to be compatible to
Bruker Daltonics CompassXport.
}
\examples{
## load library
library("readBrukerFlexData")
## get examples directory
exampleDirectory <- system.file("Examples", package="readBrukerFlexData")
## read example spectrum
spec <- readBrukerFlexFile(file.path(exampleDirectory,
"2010_05_19_Gibb_C8_A1/0_A1/1/1SLin/fid"))
## print metaData
print(spec$metaData)
## plot spectrum
plot(spec$spectrum$mass, spec$spectrum$intensity, type="l", col="red")
}
\seealso{
\url{https://github.com/sgibb/readBrukerFlexData/wiki},
\code{\link[MALDIquantForeign]{importBrukerFlex}},
\code{\link[readBrukerFlexData]{readBrukerFlexDir}},
\code{\link[readBrukerFlexData]{.hpc}}
}
\keyword{IO}
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