Planimeter -- compute the area of geodesic polygons
Planimeter [
-r ] [
-s ] [
-l ] [
-e a
f ] [
-w ] [
-p prec ] [
-G |
-E |
-Q |
-R ] [
--geoconvert-input ] [
--comment-delimiter commentdelim ] [
--version |
-h |
--help ] [
--input-file infile |
--input-string instring ] [
--line-separator
linesep ] [
--output-file outfile ]
Measure the area of a geodesic polygon. Reads polygon vertices from standard
input, one per line. Vertices are be given as latitude and longitude. By
default latitude precedes longitude, however this convention is reversed with
the
-w flag and a hemisphere designator (
N,
S,
E,
W) can be used to disambiguate the coordinates. The end of input, a
blank line, or a line which can't be interpreted as a vertex signals the end
of one polygon and the start of the next. For each polygon print a summary
line with the number of points, the perimeter (in meters), and the area (in
meters^2).
The edges of the polygon are given by the
shortest geodesic (or rhumb
line) between consecutive vertices. In certain cases, there may be two or many
such shortest path, and in that case, the polygon is not uniquely specified by
its vertices. For geodesics, this only happens with very long edges (for the
WGS84 ellipsoid, any edge shorter than 19970 km is uniquely specified by its
end points). In such cases, insert an additional vertex near the middle of the
long edge to define the boundary of the polygon.
By default, polygons traversed in a counter-clockwise direction return a
positive area and those traversed in a clockwise direction return a negative
area. This sign convention is reversed if the
-r option is given.
Of course, encircling an area in the clockwise direction is equivalent to
encircling the rest of the ellipsoid in the counter-clockwise direction. The
default interpretation used by
Planimeter is the one that results in a
smaller magnitude of area; i.e., the magnitude of the area is less than or
equal to one half the total area of the ellipsoid. If the
-s option is
given, then the interpretation used is the one that results in a positive
area; i.e., the area is positive and less than the total area of the
ellipsoid.
Arbitrarily complex polygons are allowed. In the case of self-intersecting
polygons the area is accumulated "algebraically", e.g., the areas of
the 2 loops in a figure-8 polygon will partially cancel. Polygons may include
one or both poles. There is no need to close the polygon.
- -r
- toggle whether counter-clockwise traversal of the polygon
returns a positive (the default) or negative result.
- -s
- toggle whether to return a signed result (the default) or
not.
- -l
- toggle whether the vertices represent a polygon (the
default) or a polyline. For a polyline, the number of points and the
length of the path joining them is returned; the path is not closed and
the area is not reported.
-
-e a f
- specify the ellipsoid via the equatorial radius, a
and the flattening, f. Setting f = 0 results in a sphere.
Specify f < 0 for a prolate ellipsoid. A simple fraction, e.g.,
1/297, is allowed for f. By default, the WGS84 ellipsoid is used,
a = 6378137 m, f = 1/298.257223563. If entering vertices as
UTM/UPS or MGRS coordinates, use the default ellipsoid, since the
conversion of these coordinates to latitude and longitude always uses the
WGS84 parameters.
- -w
- toggle the longitude first flag (it starts off); if the
flag is on, then when reading geographic coordinates, longitude precedes
latitude (this can be overridden by a hemisphere designator, N,
S, E, W).
-
-p prec
- set the output precision to prec (default 6); the
perimeter is given (in meters) with prec digits after the decimal
point; the area is given (in meters^2) with ( prec - 5) digits
after the decimal point.
- -G
- use the series formulation for the geodesics. This is the
default option and is recommended for terrestrial applications. This
option, -G, and the following three options, -E, -Q,
and -R, are mutually exclusive.
- -E
- use "exact" algorithms (based on elliptic
integrals) for the geodesic calculations; the area is computed by applying
discrete sine transforms to the integrand in the expression for the area.
These are more accurate, albeit slower, than the (default) series
expansions for | f| > 0.02 and will give high accuracy for -99 X
f X 0.99.
- -Q
- perform the calculation on the authalic sphere. The area
calculation is accurate even if the flattening is large, provided
the edges are sufficiently short. The perimeter calculation is not
accurate.
- -R
- The lines joining the vertices are rhumb lines instead of
geodesics.
- --geoconvert-input
- The input lines are interpreted in the same way as
GeoConvert(1) allowing the coordinates for the vertices to be given
as UTM/UPS or MGRS coordinates, as well as latitude and longitude.
CAUTION: GeoConvert assumes the coordinates refer to the WGS84
ellipsoid (disregarding the -e flag) and MGRS coordinates signify
the center of the corresponding MGRS square.
-
--comment-delimiter commentdelim
- set the comment delimiter to commentdelim (e.g.,
"#" or "//"). If set, the input lines will be scanned
for this delimiter and, if found, the delimiter and the rest of the line
will be removed prior to processing. For a given polygon, the last such
string found will be appended to the output line (separated by a
space).
- --version
- print version and exit.
- -h
- print usage and exit.
- --help
- print full documentation and exit.
-
--input-file infile
- read input from the file infile instead of from
standard input; a file name of "-" stands for standard
input.
-
--input-string instring
- read input from the string instring instead of from
standard input. All occurrences of the line separator character (default
is a semicolon) in instring are converted to newlines before the
reading begins.
-
--line-separator linesep
- set the line separator character to linesep. By
default this is a semicolon.
-
--output-file outfile
- write output to the file outfile instead of to
standard output; a file name of "-" stands for standard
output.
Example (the area of the 100km MGRS square 18SWK)
Planimeter --geoconvert-input <<EOF
18n 500000 4400000
18n 600000 4400000
18n 600000 4500000
18n 500000 4500000
EOF
=> 4 400139.532959 10007388597.2
The following code takes the output from gdalinfo and reports the area covered
by the data (assuming the edges of the image are geodesics).
#! /bin/sh
egrep '^((Upper|Lower) (Left|Right)|Center) ' |
sed -e 's/d /d/g' -e "s/' /'/g" | tr -s '(),\r\t' ' ' | awk '{
if ($1 $2 == "UpperLeft")
ul = $6 " " $5;
else if ($1 $2 == "LowerLeft")
ll = $6 " " $5;
else if ($1 $2 == "UpperRight")
ur = $6 " " $5;
else if ($1 $2 == "LowerRight")
lr = $6 " " $5;
else if ($1 == "Center") {
printf "%s\n%s\n%s\n%s\n\n", ul, ll, lr, ur;
ul = ll = ur = lr = "";
}
}
' | Planimeter | cut -f3 -d' '
Using the
-G option (the default), the accuracy was estimated by
computing the error in the area for 10^7 approximately regular polygons on the
WGS84 ellipsoid. The centers and the orientations of the polygons were
uniformly distributed, the number of vertices was log-uniformly distributed in
[3, 300], and the center to vertex distance log-uniformly distributed in [0.1
m, 9000 km].
The maximum error in the perimeter was 200 nm, and the maximum error in the area
was
0.0013 m^2 for perimeter < 10 km
0.0070 m^2 for perimeter < 100 km
0.070 m^2 for perimeter < 1000 km
0.11 m^2 for all perimeters
GeoConvert(1),
GeodSolve(1).
An online version of this utility is availbable at
<
https://geographiclib.sourceforge.io/cgi-bin/Planimeter>.
The algorithm for the area of geodesic polygon is given in Section 6 of C. F. F.
Karney,
Algorithms for geodesics, J. Geodesy 87, 43-55 (2013); DOI
<
https://doi.org/10.1007/s00190-012-0578-z>; addenda:
<
https://geographiclib.sourceforge.io/geod-addenda.html>.
Planimeter was written by Charles Karney.
Planimeter was added to GeographicLib,
<
https://geographiclib.sourceforge.io>, in version 1.4.