NAME
t.rast.algebra - Apply temporal and spatial operations on space time raster datasets using temporal raster algebra.
KEYWORDS
temporal,
algebra,
raster,
time
SYNOPSIS
t.rast.algebra
t.rast.algebra --help
t.rast.algebra [-sngd] expression=string basename=string [suffix=string] [nprocs=integer] [--help] [--verbose] [--quiet] [--ui]
Flags:
- -s
- Check the spatial topology of temporally related maps and process only spatially related maps
- -n
- Register Null maps
- -g
- Use granularity sampling instead of the temporal topology approach
- -d
- Perform a dry run, compute all dependencies and module calls but don't run them
- --help
- Print usage summary
- --verbose
- Verbose module output
- --quiet
- Quiet module output
- --ui
- Force launching GUI dialog
Parameters:
- expression=string [required]
- r.mapcalc expression for temporal and spatial analysis of space time raster datasets
- basename=string [required]
- Basename of the new generated output maps
- A numerical suffix separated by an underscore will be attached to create a unique identifier
- suffix=string
- Suffix to add at basename: set 'gran' for granularity, 'time' for the full time format, 'num' for numerical suffix with a specific number of digits (default %05)
- Default: num
- nprocs=integer
- Number of r.mapcalc processes to run in parallel
- Default: 1
t.rast.algebra performs temporal and spatial map algebra operations on
space time raster datasets (STRDS) using the temporal raster algebra.
The module expects an expression as input parameter in the
following form:
"result = expression"
The statement structure is similar to that of r.mapcalc.
In this statement, result represents the name of the space time
raster dataset (STRDS) that will contain the result of the calculation
that is given as expression on the right side of the equality sign.
These expressions can be any valid or nested combination of temporal
operations and spatial overlay or buffer functions that are provided by
the temporal algebra.
The temporal raster algebra works only with space time raster datasets
(STRDS). The algebra provides methods for map selection based on their
temporal relations. It is also possible to temporally shift maps, to
create temporal buffer and to snap time instances to create a valid
temporal topology. Furthermore, expressions can be nested and evaluated
in conditional statements (if, else statements). Within if-statements,
the algebra provides temporal variables like start time, end time, day
of year, time differences or number of maps per time interval to build
up conditions.
In addition the algebra provides a subset of the spatial operations
from r.mapcalc. All these operations can be
assigned to STRDS or to the map lists resulting of operations between
STRDS.
By default, only temporal topological relations among space time datasets
(STDS) are evaluated. The -s flag can be used to additionally
activate the evaluation of the spatial topology based on the spatial
extent of maps.
The expression option must be passed as quoted expression, for
example:
t.rast.algebra expression="C = A + B" basename=result
Where
C is the new space time raster dataset that will contain
maps with the basename "result" and a numerical suffix separated by an
underscore that represent the sum of maps from the STRDS
A and temporally equal maps (i.e., maps with equal temporal
topology relation) from the STRDS
B.
The map basename for the result STRDS must always be specified.
The temporal algebra provides a wide range of temporal operators and
functions that will be presented in the following section.
Several temporal topology relations are supported between maps registered
in space time datasets:
equals A ------
B ------
during A ----
B ------
contains A ------
B ----
starts A ----
B ------
started A ------
B ----
finishes A ----
B ------
finished A ------
B ----
precedes A ----
B ----
follows A ----
B ----
overlapped A ------
B ------
overlaps A ------
B ------
over both overlaps and overlapped
The relations must be read as: A is related to B, like - A equals B - A
is during B - A contains B.
Topological relations must be specified with curly brackets {}.
The temporal algebra defines temporal operators that can be combined with
other operators to perform spatio-temporal operations.
The temporal operators process the time instances and intervals of two
temporally related maps and calculate the resulting temporal extent in
five possible different ways.
LEFT REFERENCE l Use the time stamp of the left space time dataset
INTERSECTION i Intersection
DISJOINT UNION d Disjoint union
UNION u Union
RIGHT REFERENCE r Use the time stamp of the right space time dataset
The temporal selection simply selects parts of a space time dataset without
processing any raster or vector data. The algebra provides a selection
operator
: that by default selects parts of a space time dataset
that are temporally equal to parts of a second space time dataset. The
following expression
means: select all parts of space time dataset A that are equal to B and
store them in space time dataset C. These parts are time stamped maps.
In addition, the inverse selection operator !: is defined as the
complement of the selection operator, hence the following expression
means: select all parts of space time time dataset A that are not equal
to B and store them in space time dataset C.
To select parts of a STRDS using different topological relations
regarding to other STRDS, the temporal topology selection operator
can be used. This operator consists of the temporal selection operator,
the topological relations that must be separated by the logical OR
operator | and, the temporal extent operator. All three parts
are separated by comma and surrounded by curly brackets as follows:
{"temporal selection operator", "topological relations", "temporal operator"}.
Examples:
C = A {:,equals} B
C = A {!:,equals} B
We can now define arbitrary topological relations using the OR operator "|"
to connect them:
C = A {:,equals|during|overlaps} B
Select all parts of A that are equal to B, during B or overlaps B.
In addition, we can define the temporal extent of the resulting STRDS by
adding the temporal operator.
Select all parts of A that are during B and use the temporal extents
from B for C.
The selection operator is implicitly contained in the temporal topology
selection operator, so that the following statements are exactly the same:
C = A : B
C = A {:} B
C = A {:,equal} B
C = A {:,equal,l} B
Same for the complementary selection:
C = A !: B
C = A {!:} B
C = A {!:,equal} B
C = A {!:,equal,l} B
Selection operations can be evaluated within conditional statements as
showed below. Note that A and B can be either space time datasets or
expressions. The temporal relationship between the conditions and the
conclusions can be defined at the beginning of the if statement (third
and fourth examples below). The relationship between then and else
conclusion must be always equal.
if statement decision option temporal relations
if(if, then, else)
if(conditions, A) A if conditions are True; temporal topological relation between if and then is equal.
if(conditions, A, B) A if conditions are True, B otherwise; temporal topological relation between if, then and else is equal.
if(topologies, conditions, A) A if conditions are True; temporal topological relation between if and then is explicitly specified by topologies.
if(topologies, conditions, A, B) A if conditions are True, B otherwise; temporal topological relation between if, then and else is explicitly specified by topologies.
The conditions are comparison expressions that are used to evaluate
space time datasets. Specific values of temporal variables are
compared by logical operators and evaluated for each map of the STRDS.
Important: The conditions are evaluated from left to right.
Logical operators
Symbol description
== equal
!= not equal
> greater than
>= greater than or equal
< less than
<= less than or equal
&& and
|| or
Temporal functions
The following temporal functions are evaluated only for the STDS that
must be given in parenthesis.
td(A) Returns a list of time intervals of STDS A
start_time(A) Start time as HH::MM:SS
start_date(A) Start date as yyyy-mm-DD
start_datetime(A) Start datetime as yyyy-mm-DD HH:MM:SS
end_time(A) End time as HH:MM:SS
end_date(A) End date as yyyy-mm-DD
end_datetime(A) End datetime as yyyy-mm-DD HH:MM
start_doy(A) Day of year (doy) from the start time [1 - 366]
start_dow(A) Day of week (dow) from the start time [1 - 7], the start of the week is Monday == 1
start_year(A) The year of the start time [0 - 9999]
start_month(A) The month of the start time [1 - 12]
start_week(A) Week of year of the start time [1 - 54]
start_day(A) Day of month from the start time [1 - 31]
start_hour(A) The hour of the start time [0 - 23]
start_minute(A) The minute of the start time [0 - 59]
start_second(A) The second of the start time [0 - 59]
end_doy(A) Day of year (doy) from the end time [1 - 366]
end_dow(A) Day of week (dow) from the end time [1 - 7], the start of the week is Monday == 1
end_year(A) The year of the end time [0 - 9999]
end_month(A) The month of the end time [1 - 12]
end_week(A) Week of year of the end time [1 - 54]
end_day(A) Day of month from the start time [1 - 31]
end_hour(A) The hour of the end time [0 - 23]
end_minute(A) The minute of the end time [0 - 59]
end_second(A) The second of the end time [0 - 59]
In order to use the numbers returned by the functions in the last block above, an
offset value needs to be added. For example, start_doy(A, 0) would return the
DOY of the current map in STDS A. end_hour(A, -1) would return the end hour of
the previous map in STDS A.
Comparison operator
As mentioned above, the conditions are comparison expressions that are
used to evaluate space time datasets. Specific values of temporal
variables are compared by logical operators and evaluated for each map
of the STDS and (optionally) related maps.
For complex relations, the comparison operator can be used to combine
conditions.
The structure is similar to the select operator with the addition of an
aggregation operator:
{"comparison operator", "topological relations", aggregation operator, "temporal operator"}
This aggregation operator (| or &) defines the behaviour when a map is
related to more than one map, e.g. for the topological relation 'contains'.
Should all (&) conditions for the related maps be true or is it sufficient
to have any (|) condition that is true. The resulting boolean value is
then compared to the first condition by the comparison operator (|| or &&).
By default, the aggregation operator is related to the comparison
operator:
comparison operator -> aggregation operator:
Examples:
Condition 1 {||, equal, r} Condition 2
Condition 1 {&&, equal|during, l} Condition 2
Condition 1 {&&, equal|contains, |, l} Condition 2
Condition 1 {&&, equal|during, l} Condition 2 && Condition 3
Condition 1 {&&, equal|during, l} Condition 2 {&&,contains, |, r} Condition 3
Hash operator
Additionally, the number of maps in intervals can be computed and used in
conditional statements with the hash (#) operator.
This expression computes the number of maps from space time dataset B
which are during the time intervals of maps from space time dataset A.
A list of integers (scalars) corresponding to the maps of A that contain
maps from B will be returned.
C = if({equal}, A {#, contains} B > 2, A {:, contains} B)
This expression selects all maps from A that temporally contain at least 2
maps from B and stores them in space time dataset C. The leading equal
statement in the if condition specifies the temporal relation between
the if and then part of the if expression. This is very important, so we
do not need to specify a global time reference (a space time dataset)
for temporal processing.
Furthermore, the temporal algebra allows temporal buffering, shifting
and snapping with the functions buff_t(), tshift() and tsnap(),
respectively.
buff_t(A, size) Buffer STDS A with granule ("1 month" or 5)
tshift(A, size) Shift STDS A with granule ("1 month" or 5)
tsnap(A) Snap time instances and intervals of STDS A
Single map with temporal extent
The temporal algebra can also handle single maps with time stamps in the
tmap() function.
For example:
C = A {:, during} tmap(event)
This statement selects all maps from space time data set A that are during
the temporal extent of the single map 'event'
The module supports the following raster operations:
Symbol description precedence
% modulus 1
/ division 1
* multiplication 1
+ addition 2
- subtraction 2
And raster functions:
abs(x) return absolute value of x
float(x) convert x to foating point
int(x) convert x to integer [ truncates ]
log(x) natural log of x
sqrt(x) square root of x
tan(x) tangent of x (x is in degrees)
round(x) round x to nearest integer
sin(x) sine of x (x is in degrees)
isnull(x) check if x = NULL
isntnull(x) check if x is not NULL
null set null value
exist(x) Check if x is in the current mapset
Single raster map
The temporal raster algebra features also a function to integrate single
raster maps without time stamps into the expressions.
For example:
C = A * map(constant_value)
This statement multiplies all raster maps from space time raster data
set A with the raster map 'constant_value'
The user can combine the temporal topology relations, the temporal
operators and the spatial/select operators to create spatio-temporal
operators as follows:
{"spatial or select operator", "list of temporal relations", "temporal operator"}
For multiple topological relations or several related maps the spatio-temporal
operators feature implicit aggregation.
The algebra evaluates the stated STDS by their temporal topologies and apply
the given spatio-temporal operators in a aggregated form.
If we have two STDS A and B, B has three maps: b1, b2, b3 that are all during
the temporal extent of the single map a1 of A, then the following arithmetic
calculations would implicitly aggregate all maps of B into one result map for
a1 of A:
C = A {+, contains} B --> c1 = a1 + b1 + b2 + b3
Important: the aggregation behaviour is not symmetric
C = B {+, during} A --> c1 = b1 + a1
c2 = b2 + a1
c3 = b3 + a1
The neighbourhood modifier of
r.mapcalc is extended for the temporal
raster algebra with the temporal dimension. The format is strds[t,r,c],
where t is the temporal offset, r is the row offset and c is the column
offset. A single neighborhood modifier is interpreted as temporal offset [t],
while two neighborhood modifiers are interpreted as row and column offsets [r,c].
strds[2]
refers to the second successor of the current map.
strds[1,2]
refers to the cell one row below and two columns to the right of the current
cell in the current map.
strds[1,-2,-1]
refers to the cell two rows above and one column to the left of the current
cell of the first successor map.
strds[-2,0,1]
refers to the cell one column to the right of the current cell in the
second predecessor map.
# Sentinel-2 bands are stored separately in two STDRS "S2_b4" and "S2_b8"
g.region raster=sentinel2_B04_10m -p
t.rast.list S2_b4
t.rast.list S2_b8
t.rast.algebra basename=ndvi expression="ndvi = float(S2_b8 - S2_b4) / ( S2_b8 + S2_b4 )"
t.rast.colors input=ndvi color=ndvi
Sum maps from STRDS A with maps from STRDS B which have equal time stamps
and are temporally before Jan. 1. 2005 and store them in STRDS D:
D = if(start_date(A) < "2005-01-01", A + B)
Create the sum of all maps from STRDS A and B that have equal time stamps
and store the new maps in STRDS C:
Same expression with explicit definition of the temporal topology relation
and temporal operators:
Select all cells from STRDS B with equal temporal relations to STRDS A, if
the cells of A are in the range [100.0, 1600] of time intervals that have
more than 30 days (Jan, Mar, May, Jul, Aug, Oct, Dec):
C = if(A > 100 && A < 1600 && td(A) > 30, B)
Same expression with explicit definition of the temporal topology relation
and temporal operators:
C = if({equal}, A > 100 && A < 1600 {&&,equal} td(A) > 30, B)
Compute the recharge in meters per second for all cells of precipitation
STRDS "Prec" if the mean temperature specified in STRDS "Temp" is higher
than 10 degrees. Computation is performed if STRDS "Prec" and "Temp" have
equal time stamps. The number of days or fraction of days per interval is
computed using the td() function that has as argument the STRDS "Prec":
C = if(Temp > 10.0, Prec / 3600.0 / 24.0 / td(Prec))
Same expression with explicit definition of the temporal topology relation
and temporal operators:
C = if({equal}, Temp > 10.0, Prec / 3600.0 / 24.0 {/,equal,l} td(Prec))
Compute the mean value of all maps from STRDS A that are located during time
intervals of STRDS B if more than one map of A is contained in an interval
of B, use A otherwise. The resulting time intervals are either from B or A:
C = if(B {#,contain} A > 1, (B {+,contain,l} A - B) / (B {#,contain} A), A)
Same expression with explicit definition of the temporal topology relation
and temporal operators:
C = if({equal}, B {#,contain} A > 1, (B {+,contain,l} A {-,equal,l} B) {equal,=/} (B {#,contain} A), A)
Compute the DOY for all maps from STRDS A where conditions are met at three
consecutive time intervals (e.g. temperature > 0):
B = if(A > 0.0 && A[-1] > 0.0 && A[-2] > 0.0, start_doy(A, -1), 0)"
r.mapcalc,
t.vect.algebra,
t.rast3d.algebra,
t.select,
t.rast3d.mapcalc,
t.rast.mapcalc
Temporal data processing Wiki
The use of this module requires the following software to be installed:
PLY(Python-Lex-Yacc)
# Ubuntu/Debian
sudo apt-get install python3-ply
# Fedora
sudo dnf install python3-ply
# MS-Windows (OSGeo4W: requires "python3-pip" package to be installed)
python3-pip install ply
Related publications:
- Gebbert, S., Pebesma, E. 2014. TGRASS: A temporal GIS for field based environmental modeling.
Environmental Modelling & Software 53, 1-12 (DOI)
- preprint PDF
- Gebbert, S., Pebesma, E. 2017. The GRASS GIS temporal framework. International Journal of
Geographical Information Science 31, 1273-1292 (DOI)
- Gebbert, S., Leppelt, T., Pebesma, E., 2019. A topology based spatio-temporal map algebra for big data analysis.
Data 4, 86. (DOI)
v.overlay,
v.buffer,
v.patch,
r.mapcalc
Thomas Leppelt, Sören Gebbert, Thünen Institute of Climate-Smart Agriculture
SOURCE CODE
Available at:
t.rast.algebra source code
(history)
Latest change: Tuesday Dec 17 20:17:20 2024 in commit: d962e90c026708a4815ea2b9f46c0e84c17de22d
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© 2003-2024
GRASS Development Team,
GRASS GIS 8.4.1dev Reference Manual