Note: This document is for an older version of GRASS GIS that will be discontinued soon. You should upgrade, and read the current manual page.
NAME
t.vect.algebra - Apply temporal and spatial operations on space time vector datasets using temporal vector algebra.
KEYWORDS
temporal,
algebra,
vector,
time
SYNOPSIS
t.vect.algebra
t.vect.algebra --help
t.vect.algebra [-s] expression=expression basename=basename [--help] [--verbose] [--quiet] [--ui]
Flags:
- -s
- Check the spatial topology of temporally related maps and process only spatially related maps
- --help
- Print usage summary
- --verbose
- Verbose module output
- --quiet
- Quiet module output
- --ui
- Force launching GUI dialog
Parameters:
- expression=expression [required]
- Spatio-temporal mapcalc expression
- basename=basename [required]
- Basename of the new generated output maps
- A numerical suffix separated by an underscore will be attached to create a unique identifier
t.vect.algebra performs temporal and spatial overlay and
buffer functions on space time vector datasets (STVDS) by using the
temporal vector algebra. New STVDS can be created, which are
expressions of existing STVDS.
The module expects an
expression as input parameter in the following form:
The statement structure is similar to r.mapcalc, see
r.mapcalc.
Where
result represents the name of a space time dataset (STVDS) that will
contain the result of the calculation that is given as
expression
on the right side of the equality sign.
These expression can be any valid or nested combination of temporal
operations and functions that are provided by the temporal vector
algebra.
The algebra provides methods for map selection from STDS 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. These operations can be assigned to space time datasets
or to the results of operations between space time datasets.
As default, topological relationships between space time datasets
will be evaluated only temporal. Use the s flag to activate the
additionally spatial topology evaluation.
The expression option
must be passed as quoted expression, for example:
t.select expression="C = A : B"
Where
C is the new space time raster dataset that will contain
maps from
A that are selected by equal temporal relationships to
the existing dataset
B in this case.
The temporal algebra provides a wide range of temporal operators and
functions that will be presented in the following section.
Several temporal topology relations between registered maps of space
time datasets are supported:
equals A ------
B ------
during A ----
B ------
contains A ------
B ----
starts A ----
B ------
started A ------
B ----
finishs A ----
B ------
finished A ------
B ----
precedes A ----
B ----
follows A ----
B ----
overlapped A ------
B ------
overlaps A ------
B ------
over booth 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 in {} parentheses.
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
temporal related maps and calculate the result temporal extent by five
different possibilities.
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 raster or vector data.
The algebra provides a selection operator
: that selects parts
of a space time dataset that are temporally equal to parts of a second one
by default. The following expression
means: Select all parts of space time dataset A that are equal to B and
store it in space time dataset C. The 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 it in space time dataset (STDS) C.
To select parts of a STDS by different topological relations to other
STDS, the temporal topology selection operator can be used. The
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 braces:
{"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 result STDS 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.
Note A and B can either be space time datasets or expressions. The temporal
relationship between the conditions and the conclusions can be defined at the
beginning of the if statement. 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 explicit specified by topologies.
if(topologies, conditions, A, B) A if conditions are True, B otherwise; temporal topological relation between if, then and else is explicit specified by topologies.
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 function 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]
Comparison operator
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
the related maps.
For complex relations the comparison operator can be used to combine conditions:
The structure is similar to the select operator with the extension of an aggregation operator:
{"comparison operator", "topological relations", aggregation operator, "temporal operator"}
This aggregation operator (| or &) define the behaviour if a map is related the more
than one map, e.g for the topological relations '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 &&).
As 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 contains 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 select all maps from space time data set A that are
during the temporal extent of single map 'event'
The module supports the following boolean vector operations:
Boolean Name Operator Meaning Precedence Correspondent function
----------------------------------------------------------------------------------
AND & Intersection 1 (v.overlay operator=and)
OR | Union 1 (v.overlay operator=or)
DISJOINT OR + Disjoint union 1 (v.patch)
XOR ^ Symmetric difference 1 (v.overlay operator=xor)
NOT ~ Complement 1 (v.overlay operator=not)
And vector functions:
buff_p(A, size) Buffer the points of vector map layer A with size
buff_l(A, size) Buffer the lines of vector map layer A with size
buff_a(A, size) Buffer the areas of vector map layer A with size
We combine the temporal topology relations, the temporal operators and
the spatial/select operators to create spatio-temporal vector
operators:
{"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 overlay
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
Keep attention that the aggregation behaviour is not symmetric:
C = B {&, during} A --> c1 = b1 & a1
c2 = b2 & a1
c3 = b3 & a1
Spatio-temporal intersect all maps from space time dataset A with all
maps from space time dataset B which have equal time stamps and are
temporary before Jan. 1. 2005 and store them in space time dataset D.
D = if(start_date(A) < "2005-01-01", A & B)
Buffer all vector points from space time vector dataset A and B with a
distance of one and intersect the results with overlapping, containing,
during and equal temporal relations to store the result in space time
vector dataset D with intersected time stamps.
D = buff_p(A, 1) {&,overlaps|overlapped|equal|during|contains,i} buff_p(B, 1)
Select all maps from space time dataset B which are during the temporal
buffered space time dataset A with a map interval of three days, else
select maps from C and store them in space time dataset D.
D = if(contains, td(buff_t(A, "1 days")) == 3, B, C)
PLY(Python-Lex-Yacc)
t.select
Thomas Leppelt, Soeren Gebbert, Thünen Institute of Climate-Smart Agriculture
SOURCE CODE
Available at:
t.vect.algebra source code
(history)
Latest change: Wed Nov 25 02:25:37 2020 in commit: 44c12764d2a84ebe36ab199d115395d095730390
Note: This document is for an older version of GRASS GIS that will be discontinued soon. You should upgrade, and read the current manual page.
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