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NAME
r.series - Makes each output cell value a function of the values assigned to the corresponding cells in the input raster map layers.
KEYWORDS
raster,
aggregation,
series
SYNOPSIS
r.series
r.series --help
r.series [-nz] [input=name[,name,...]] [file=name] output=name[,name,...] method=string[,string,...] [quantile=float[,float,...]] [weights=float[,float,...]] [range=lo,hi] [--overwrite] [--help] [--verbose] [--quiet] [--ui]
Flags:
- -n
- Propagate NULLs
- -z
- Do not keep files open
- --overwrite
- Allow output files to overwrite existing files
- --help
- Print usage summary
- --verbose
- Verbose module output
- --quiet
- Quiet module output
- --ui
- Force launching GUI dialog
Parameters:
- input=name[,name,...]
- Name of input raster map(s)
- file=name
- Input file with one raster map name and optional one weight per line, field separator between name and weight is |
- output=name[,name,...] [required]
- Name for output raster map
- method=string[,string,...] [required]
- Aggregate operation
- Options: average, count, median, mode, minimum, min_raster, maximum, max_raster, stddev, range, sum, variance, diversity, slope, offset, detcoeff, tvalue, quart1, quart3, perc90, quantile, skewness, kurtosis
- quantile=float[,float,...]
- Quantile to calculate for method=quantile
- Options: 0.0-1.0
- weights=float[,float,...]
- Weighting factor for each input map, default value is 1.0 for each input map
- range=lo,hi
- Ignore values outside this range
r.series makes each output cell value a function of the values
assigned to the corresponding cells in the input raster map layers.
Following methods are available:
- average: average value
- count: count of non-NULL cells
- median: median value
- mode: most frequently occurring value
- minimum: lowest value
- min_raster: raster map number with the minimum time-series value
- maximum: highest value
- max_raster: raster map number with the maximum time-series value
- stddev: standard deviation
- range: range of values (max - min)
- sum: sum of values
- variance: statistical variance
- diversity: number of different values
- slope: linear regression slope
- offset: linear regression offset
- detcoeff: linear regression coefficient of determination
- tvalue: linear regression t-value
- quart1: first quartile
- quart3: third quartile
- perc90: ninetieth percentile
- quantile: arbitrary quantile
- skewness: skewness
- kurtosis: kurtosis
Note that most parameters accept multiple answers, allowing multiple
aggregates to be computed in a single run, e.g.:
r.series input=map1,...,mapN \
output=map.mean,map.stddev \
method=average,stddev
or:
r.series input=map1,...,mapN \
output=map.p10,map.p50,map.p90 \
method=quantile,quantile,quantile \
quantile=0.1,0.5,0.9
The same number of values must be provided for all options.
With
-n flag, any cell for which any of the corresponding
input cells are NULL is automatically set to NULL (NULL propagation).
The aggregate function is not called, so all methods behave this way
with respect to the
-n flag.
Without -n flag, the complete list of inputs for each cell
(including NULLs) is passed to the aggregate function. Individual
aggregates can handle data as they choose. Mostly, they just compute
the aggregate over the non-NULL values, producing a NULL result only if
all inputs are NULL.
The
min_raster and
max_raster methods generate a map
with the number of the raster map that holds the minimum/maximum value
of the time-series. The numbering starts at
0 up to
n
for the first and the last raster listed in
input=,
respectively.
If the
range= option is given, any values which fall outside
that range will be treated as if they were NULL. The
range
parameter can be set to
low,high thresholds: values outside of
this range are treated as NULL (i.e., they will be ignored by most
aggregates, or will cause the result to be NULL if -n is given). The
low,high thresholds are floating point, so use
-inf
or
inf for a single threshold (e.g.,
range=0,inf to
ignore negative values, or
range=-inf,-200.4 to ignore values
above -200.4).
Linear regression (slope, offset, coefficient of determination,
t-value) assumes equal time intervals. If the data have irregular time
intervals, NULL raster maps can be inserted into time series to make
time intervals equal (see example).
r.series can calculate arbitrary quantiles.
Memory usage is not an issue, as
r.series only needs to hold
one row from each map at a time.
The maximum number of raster maps that can be processed is given by the
user-specific limit of the operating system. For example, the soft limits
for users are typically 1024 files. The soft limit can be changed with e.g.
ulimit -n 4096 (UNIX-based operating systems) but it cannot be
higher than the hard limit. If the latter is too low, you can as superuser
add an entry in:
/etc/security/limits.conf
# <domain> <type> <item> <value>
your_username hard nofile 4096
This will raise the hard limit to 4096 files. Also have a look at the
overall limit of the operating system
cat /proc/sys/fs/file-max
which on modern Linux systems is several 100,000 files.
For each map a weighting factor can be specified using the
weights option. Using weights can be meaningful when computing
the sum or average of maps with different temporal extent. The default
weight is 1.0. The number of weights must be identical to the number
of input maps and must have the same order. Weights can also be
specified in the input file.
Use the -z flag to analyze large amounts of raster maps without
hitting open files limit and the file option to avoid hitting
the size limit of command line arguments.
Note that the computation using the file option is slower
than with the input option.
For every single row in the output map(s) all input maps are
opened and closed. The amount of RAM will rise linearly with the number
of specified input maps. The input and file options are
mutually exclusive: the former is a comma separated list of raster map
names and the latter is a text file with a new line separated list of
raster map names and optional weights. As separator between the map name
and the weight the character "|" must be used.
Using
r.series with wildcards:
r.series input="`g.list pattern='insitu_data.*' sep=,`" \
output=insitu_data.stddev method=stddev
Note the g.list script also supports regular expressions for
selecting map names.
Using r.series with NULL raster maps (in order to consider a
"complete" time series):
r.mapcalc "dummy = null()"
r.series in=map2001,map2002,dummy,dummy,map2005,map2006,dummy,map2008 \
out=res_slope,res_offset,res_coeff meth=slope,offset,detcoeff
Example for multiple aggregates to be computed in one run (3 resulting aggregates
from two input maps):
r.series in=one,two out=result_avg,res_slope,result_count meth=sum,slope,count
Example to use the file option of r.series:
cat > input.txt << EOF
map1
map2
map3
EOF
r.series file=input.txt out=result_sum meth=sum
Example to use the file option of r.series including weights. The
weight 0.75 should be assigned to map2. As the other maps do not have
weights we can leave it out:
cat > input.txt << EOF
map1
map2|0.75
map3
EOF
r.series file=input.txt out=result_sum meth=sum
Example for counting the number of days above a certain temperature using
daily average maps ('???' as DOY wildcard):
# Approach for shell based systems
r.series input=`g.list rast pattern="temp_2003_???_avg" separator=comma` \
output=temp_2003_days_over_25deg range=25.0,100.0 method=count
# Approach in two steps (e.g., for Windows systems)
g.list rast pattern="temp_2003_???_avg" output=mapnames.txt
r.series file=mapnames.txt \
output=temp_2003_days_over_25deg range=25.0,100.0 method=count
g.list,
g.region,
r.quantile,
r.series.accumulate,
r.series.interp,
r.univar
Hints for large raster data processing
Glynn Clements
SOURCE CODE
Available at:
r.series source code
(history)
Latest change: Thu Feb 3 11:10:06 2022 in commit: 73413160a81ed43e7a5ca0dc16f0b56e450e9fef
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© 2003-2022
GRASS Development Team,
GRASS GIS 8.0.3dev Reference Manual