Generally, the [[
method lets users extract information from oce
objects, without having to know the details of the internal storage. For
many oce
sub-classes, [[
can also return quantities that are computed
from the object's contents.
# S4 method for landsat
[[(x, i, j, ...)
a landsat object.
character value indicating the name of an item to extract.
optional additional information on the i
item.
ignored.
If i
is "?"
, then the return value is a list
containing four items, each of which is a character vector
holding the names of things that can be accessed with [[
.
The data
and metadata
items hold the names of
entries in the object's data and metadata
slots, respectively. The data
entries are difficult
to deal with directly, and so users are advised to
use dataDerived
instead.
Accessing band data. The data may be accessed with e.g.
landsat[["panchromatic"]]
, for the panchromatic band. If a new
``band'' is added with landsatAdd()
, it may be referred by
name. In all cases, a second argument can be provided, to govern
decimation. If this is missing, all the relevant data are returned. If
this is present and equal to TRUE
, then the data will be
automatically decimated (subsampled) to give approximately 800 elements in
the longest side of the matrix. If this is present and numerical, then its
value governs decimation. For example,
landsat[["panchromatic",TRUE]]
will auto-decimate, typically
reducing the grid width and height from 16000 to about 800. Similarly,
landsat[["panchromatic",10]]
will reduce width and height to about
1600. On machines with limited RAM (e.g. under about 6GB), decimation is a
good idea in almost all processing steps. It also makes sense for
plotting, and in fact is done through the `decimate` argument of
plot,landsat-method()
.
Accessing derived data. One may retrieve several derived quantities
that are calculated from data stored in the object:
landsat[["longitude"]]
and landsat[["latitude"]]
give pixel
locations. Accessing landsat[["temperature"]]
creates an estimate
of ground temperature as follows (see reference 4). First, the ``count value'' in
band 10, denoted \(b_{10}\) say, is scaled with coefficients stored
in the image metadata using
\(\lambda_L=b_{10}M_L+A_L\) where \(M_L\)
and \(A_L\) are values stored in the metadata (e.g. the first in
landsat@metadata$header$radiance_mult_band_10
) Then the result is
used, again with coefficients in the metadata, to compute Celcius
temperature \(T=K_2/ln(\epsilon
K_1/\lambda_L+1)-273.15\).
The value of the emissivity \(\epsilon\) is set to unity by
read.landsat()
, although it can be changed easily later, by
assigning a new value to `landsat@metadata$emissivity`. The default
emissivity value set by read.landsat()
is from reference 11, and is
within the oceanic range suggested by reference 5. Adjustment is as simple as
altering `landsat@metadata$emissivity`. This value can be a single
number meant to apply for the whole image, or a matrix with dimensions
matching those of band 10. The matrix case is probably more useful for
images of land, where one might wish to account for the different
emissivities of soil and vegetation, etc.; for example, Table 4 of
reference 9 lists 0.9668 for soil and 0.9863 for vegetation,
while Table 5 of reference 10 lists 0.971 and 0.987 for the same quantities.
Accessing metadata. Anything in the metadata can be accessed by
name, e.g. landsat[["time"]]
. Note that some items are simply
copied over from the source data file and are not altered by e.g.
decimation. An exception is the lat-lon box, which is altered by
landsatTrim()
.
Note: the text of this section is identical for all oce
subclasses, and so
some of what you read here may not be relevant to the class being described
in this help page.
If the specialized method produces no matches, the following generalized
method is applied. As with the specialized method, the procedure hinges first
on the values of i
and, optionally, j
. The work proceeds in steps, by
testing a sequence of possible conditions in sequence.
A check is made as to whether i
names one of the standard oce
slots.
If so, [[
returns the slot contents of that slot. Thus, x[["metadata"]]
will retrieve the metadata
slot, while x[["data"]]
and
x[["processingLog"]]
return those slots.
If i
is a string ending in the "Unit"
, then the characters preceding
that string are taken to be the name of an item in the data object, and a
list containing the unit is returned (or NULL
if there is no such unit).
This list consists of an item named unit
, which is an expression()
, and
an item named scale
, which is a string describing the measurement scale.
If the string ends in " unit"
, e.g. x[["temperature unit"]]
(note the
space), then just the expression is returned, and if it ends in " scale"
,
then just the scale is returned.
If i
is a string ending in "Flag"
, then the corresponding data-quality
flag is returned (or NULL
if there is no such flag).
If the object holds hydrographic information (pressure, salinity,
temperature, longitude and latitude) then another set of possibilities
arises. If i
is "sigmaTheta"
, then the value of swSigmaTheta()
is
called with x
as the sole argument, and the results are returned.
Similarly, swSigma0()
is used if i="sigma0"
, and swSpice()
is used if
i="spice"
. Of course, these actions only make sense for objects that
contain the relevant items within their data
slot.
After these possibilities are eliminated, the action depends on whether
j
has been provided. If j
is not provided, or is the string ""
, then
i
is sought in the metadata
slot, and then in the data
slot, returning
whichever is found first. In other words, if j
is not provided, the
metadata
slot takes preference over the data
slot. However, if j
is
provided, then it must be either the string "metadata"
or "data"
, and it
directs where to look.
If none of the above-listed conditions holds, then NULL
is returned.
Dan Kelley
A two-step process is used to try to find the requested information. First, a
class-specific function is used (see “Details of the Specialized
Method”). If this yields nothing, then a general method is used (see
“Details of the General Method”). If both methods fail, then [[
returns NULL.
Some understanding of the subclass is required to know what can be retrieved
with [[
. When dealing with an unfamiliar subclass, it can be useful to
first use x[["?"]]
to get a listing of the retrievable items. See
“Details of the Specialized Method” for more information.
Other functions that extract parts of oce objects:
[[,adp-method
,
[[,adv-method
,
[[,amsr-method
,
[[,argo-method
,
[[,bremen-method
,
[[,cm-method
,
[[,coastline-method
,
[[,ctd-method
,
[[,echosounder-method
,
[[,g1sst-method
,
[[,gps-method
,
[[,ladp-method
,
[[,lisst-method
,
[[,lobo-method
,
[[,met-method
,
[[,oce-method
,
[[,odf-method
,
[[,rsk-method
,
[[,sealevel-method
,
[[,section-method
,
[[,tidem-method
,
[[,topo-method
,
[[,windrose-method
,
[[,xbt-method
,
[[<-,adv-method
Other things related to landsat data:
[[<-,landsat-method
,
landsat-class
,
landsatAdd()
,
landsatTrim()
,
landsat
,
plot,landsat-method
,
read.landsat()
,
summary,landsat-method