Assemble data into a ctd object. This function is complicated (spanning approximately 500 lines of code) because it tries to handle many special cases, and tries to make sensible defaults for unspecified parameters. If odd results are found, users might find it helpful to call this function with the first argument being a simple vector of Practical Salinity values, in which case the processing of the other arguments is relatively straightforward.
as.ctd(
salinity,
temperature = NULL,
pressure = NULL,
conductivity = NULL,
scan = NULL,
time = NULL,
units = NULL,
flags = NULL,
missingValue = NULL,
type = "",
serialNumber = NULL,
ship = NULL,
cruise = NULL,
station = NULL,
startTime = NULL,
longitude = NULL,
latitude = NULL,
deploymentType = "unknown",
pressureAtmospheric = 0,
sampleInterval = NULL,
profile = NULL,
debug = getOption("oceDebug")
)
A ctd object.
may be (1) a numeric vector holding Practical Salinity,
(2) a list or data frame holding salinity
and other
hydrographic variables or (3) an oce-class
object that holds
hydrographic information. If salinity
is not provided,
then conductivity
must be provided, so that swSCTp()
can be used to compute salinity.
a numeric vector containing in-situ temperature in
\(^\circ\)C on the ITS-90 scale; see “Temperature units” in the
documentation for swRho()
.
a numeric vector containing sea pressure values, in decibars.
Typically, this vector has the same length as salinity
and temperature
,
but it also possible to supply just one value, which will be repeated
to get the right length. Note that as.ctd()
stores the
sum of pressure
and pressureAtmospheric
in the returned object,
although the default value for pressureAtmospheric
is zero, so
in the default case, pressure
is stored directly.
an optional numeric vector containing electrical conductivity ratio through the water column. To convert from raw conductivity in milliSeimens per centimeter divide by 42.914 to get conductivity ratio (see Culkin and Smith, 1980).
optional numeric vector holding scan number. If not provided,
this is set to seq_along(salinity)
.
optional vector of times of observation.
an optional list containing units. If not supplied,
defaults are set for pressure
, temperature
, salinity
,
and conductivity
. Since these are simply guesses, users
are advised strongly to supply units
. See “Examples”.
if supplied, this is a list containing data-quality flags. The elements of this list must have names that match the data provided to the object.
optional missing value, indicating data that should be
taken as NA
. Set to NULL
to turn off this feature.
optional type of CTD, e.g. "SBE"
optional serial number of instrument
optional string containing the ship from which the observations were made.
optional string containing a cruise identifier.
optional string containing a station identifier.
optional indication of the start time for the profile,
which is used in some several plotting functions. This is best given as a
POSIXt time, but it may also be a character string
that can be converted to a time with as.POSIXct()
,
using UTC
as the timezone.
optional numerical value containing longitude in decimal
degrees, positive in the eastern hemisphere. If this is a single number,
then it is stored in the metadata
slot of the returned value; if it
is a vector of numbers, then they are stored in the data
slot.
optional numerical value containing the latitude in decimal
degrees, positive in the northern hemisphere. See the note on length, for
the longitude
argument.
character string indicating the type of deployment. Use
"unknown"
if this is not known, "profile"
for a profile (in
which the data were acquired during a downcast, while the device was lowered
into the water column, perhaps also including an upcast; "moored"
if
the device is installed on a fixed mooring, "thermosalinograph"
(or
"tsg"
) if the device is mounted on a moving vessel, to record
near-surface properties, or "towyo"
if the device is repeatedly
lowered and raised.
A numerical value (a constant or a vector),
that is subtracted from pressure before storing it in the return value.
(This altered pressure is also used in calculating salinity
, if
that is to be computed from conductivity
, etc., using
swSCTp()
; see salinity
above.)
optional numerical value indicating the time between samples in the profile.
optional positive integer specifying the number of the profile
to extract from an object that has data in matrices, such as for some
argo
objects. Currently the profile
argument is only utilized for
argo objects.
an integer specifying whether debugging information is
to be printed during the processing. This is a general parameter that
is used by many oce
functions. Generally, setting debug=0
turns off the printing, while higher values suggest that more information
be printed. If one function calls another, it usually reduces the value of
debug
first, so that a user can often obtain deeper debugging
by specifying higher debug
values.
Dan Kelley
The following sections provide an some notes on how as.ctd()
handles
certain object types given as the first parameter.
Converting argo objects
If the salinity
argument is an object of argo, then that
object is dismantled and reassembled as a ctd object in ways that
are mostly straightforward, although the handling of time depends
on the information in the original netcdf data file that was used
by read.argo()
to create the argo object.
All Argo data files contain an item called juld
from which the profile
time can be computed, and some also contain an additional item named MTIME
,
from which the times of individual measurements can also be computed. Both
cases are handled by as.ctd()
, using a scheme outlined in
Note 4 of the Details section of the read.argo()
documentation.
Converting rsk objects
If the salinity
argument is an object of rsk,
then as.ctd
passes it,
pressureAtmospheric
,
longitude
,
latitude
ship
,
cruise
,
station
and
deploymentType
to rsk2ctd()
, which builds the ctd object that is
returned by as.ctd
. The other arguments to as.ctd
are ignored in this instance, because rsk
objects already
contain their information. If required, any data or metadata
element can be added to the value returned by as.ctd
using oceSetData()
or oceSetMetadata()
,
respectively.
The returned rsk object contains pressure in a form that
may need to be adjusted, because rsk
objects may contain
either absolute pressure or sea pressure. This adjustment is handled
automatically by as.ctd
, by examination of the metadata item
named pressureType
(described in the documentation for
read.rsk()
). Once the sea pressure is determined,
adjustments may be made with the pressureAtmospheric
argument,
although in that case it is better considered a pressure adjustment
than the atmospheric pressure.
rsk objects may store sea pressure or absolute pressure (the
sum of sea pressure and atmospheric pressure), depending on how the object was
created with as.rsk()
or read.rsk()
. However,
ctd objects store sea pressure, which is needed for
plotting, calculating density, etc. This poses no difficulties, however,
because as.ctd
automatically converts absolute pressure to sea pressure,
if the metadata in the rsk object indicates that this is
appropriate. Further alteration of the pressure can be accomplished with the
pressureAtmospheric
argument, as noted above.
Culkin, F., and Norman D. Smith, 1980. Determination of the concentration of potassium chloride solution having the same electrical conductivity, at 15 C and infinite frequency, as standard seawater of salinity 35.0000 ppt (Chlorinity 19.37394 ppt). IEEE Journal of Oceanic Engineering, volume 5, pages 22-23.
Other things related to ctd data:
CTD_BCD2014666_008_1_DN.ODF.gz
,
[[,ctd-method
,
[[<-,ctd-method
,
cnvName2oceName()
,
ctd-class
,
ctd.cnv.gz
,
ctdDecimate()
,
ctdFindProfilesRBR()
,
ctdFindProfiles()
,
ctdRaw
,
ctdRepair()
,
ctdTrim()
,
ctd_aml.csv.gz
,
ctd
,
d200321-001.ctd.gz
,
d201211_0011.cnv.gz
,
handleFlags,ctd-method
,
initialize,ctd-method
,
initializeFlagScheme,ctd-method
,
oceNames2whpNames()
,
oceUnits2whpUnits()
,
plot,ctd-method
,
plotProfile()
,
plotScan()
,
plotTS()
,
read.ctd.aml()
,
read.ctd.itp()
,
read.ctd.odf()
,
read.ctd.odv()
,
read.ctd.sbe()
,
read.ctd.ssda()
,
read.ctd.woce.other()
,
read.ctd.woce()
,
read.ctd()
,
setFlags,ctd-method
,
subset,ctd-method
,
summary,ctd-method
,
woceNames2oceNames()
,
woceUnit2oceUnit()
,
write.ctd()
library(oce)
# 1. fake data, with default units
pressure <- 1:50
temperature <- 10 - tanh((pressure - 20) / 5) + 0.02*rnorm(50)
salinity <- 34 + 0.5*tanh((pressure - 20) / 5) + 0.01*rnorm(50)
ctd <- as.ctd(salinity, temperature, pressure)
# Add a new column
fluo <- 5 * exp(-pressure / 20)
ctd <- oceSetData(ctd, name="fluorescence", value=fluo,
unit=list(unit=expression(mg/m^3), scale=""))
summary(ctd)
# 2. fake data, with supplied units (which are the defaults, actually)
ctd <- as.ctd(salinity, temperature, pressure,
units=list(salinity=list(unit=expression(), scale="PSS-78"),
temperature=list(unit=expression(degree*C), scale="ITS-90"),
pressure=list(unit=expression(dbar), scale="")))
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