2 tokens (output options -g, -d, or -:) given as latitude
longitude using decimal degrees or degrees, minutes, and seconds.
Latitude is given first (unless the -w option is given). See
GEOGRAPHIC COORDINATES for a description of the format. For
example, the following are all equivalent
3 tokens (output option -u) given as zone+hemisphere easting
northing or easting northing zone+hemisphere, where
hemisphere is either n (or north) or s (or south). The
zone is absent for a UPS specification. For example,
1 token (output option -m) is used to specify the center of an MGRS
grid square. For example,
-g output latitude and longitude using decimal degrees. Default output mode. -d output latitude and longitude using degrees, minutes, and seconds (DMS). -: like -d, except use : as a separator instead of the d, , and " delimiters. -u output UTM or UPS. -m output MGRS. -c output meridian convergence and scale for the corresponding UTM or UPS projection. The meridian convergence is the bearing of grid north given as degrees clockwise from true north. -z zone set the zone to zone for output. Use either 0 < zone <= 60 for a UTM zone or zone = 0 for UPS. Alternatively use a zone+hemisphere designation, e.g., 38n. See ZONE. -s use the standard UPS and UTM zones. -t similar to -s but forces UPS regions to the closest UTM zone. -S or -T behave the same as -s and -t, respectively, until the first legal conversion is performed. For subsequent points, the zone and hemisphere of that conversion are used. This enables a sequence of points to be converted into UTM or UPS using a consistent coordinate system. -n on input, MGRS coordinates refer to the south-west corner of the MGRS square instead of the center; see MGRS. -w toggle the longitude first flag (it starts off); if the flag is on, then on input and output, longitude precedes latitude (except that, on input, this can be overridden by a hemisphere designator, N, S, E, W). -p prec set the output precision to prec (default 0); prec is the precision relative to 1 m. See PRECISION. -l on output, UTM/UPS uses the long forms north and south to designate the hemisphere instead of n or s. -a on output, UTM/UPS uses the abbreviations n and s to designate the hemisphere instead of north or south; this is the default representation. --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 and subsequently 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.
prec gives precision of the output with prec = 0 giving 1 m precision, prec = 3 giving 1 mm precision, etc. prec is the number of digits after the decimal point for UTM/UPS. The number of digits per coordinate for MGRS is 5 + prec. For decimal degrees, the number of digits after the decimal point is 5 + prec. For DMS (degree, minute, seconds) output, the number of digits after the decimal point in the seconds components is 1 + prec; if this is negative then use minutes (prec = -2 or -3) or degrees (prec <= -4) as the least significant component. Print convergence, resp. scale, with 5 + prec, resp. 7 + prec, digits after the decimal point. The minimum value of prec is -5 and the maximum is 9 for UTM/UPS, 9 for decimal degrees, 10 for DMS, 6 for MGRS, and 8 for convergence and scale.
The utility accepts geographic coordinates, latitude and longitude, in a number of common formats. Latitude precedes longitude, unless the -w option is given which switches this convention. On input, either coordinate may be given first by appending or prepending N or S to the latitude and E or W to the longitude. These hemisphere designators carry an implied sign, positive for N and E and negative for S and W. This sign multiplies any +/- sign prefixing the coordinate. The coordinates may be given as decimal degree or as degrees, minutes, and seconds. d, , and " are used to denote degrees, minutes, and seconds, with the least significant designator optional. (See QUOTING for how to quote the characters and " when entering coordinates on the command line.) Alternatively, : (colon) may be used to separate the various components. Only the final component of coordinate can include a decimal point, and the minutes and seconds components must be less than 60.
It is also possible to carry out addition or subtraction operations in geographic coordinates. If the coordinate includes interior signs (i.e., not at the beginning or immediately after an initial hemisphere designator), then the coordinate is split before such signs; the pieces are parsed separately and the results summed. For example the point 15" east of 39N 70W is
WARNING: Exponential notation is not recognized for geographic coordinates; instead 7.0E+1 is parsed as (7.0E) + (+1), yielding the same result as 8.0E.
Various unicode characters (encoded with UTF-8) may also be used to denote degrees, minutes, and seconds, e.g., the degree, prime, and double prime symbols; in addition two single quotes can be used to represent ".
The other GeographicLib utilities use the same rules for interpreting geographic coordinates; in addition, azimuths and arc lengths are interpreted the same way.
Unfortunately the characters and have special meanings in many shells and have to be entered with care. However note (1) that the trailing designator is optional and that (2) you can use colons as a separator character. Thus 10d20 can be entered as 10d20 or 10:20 and 10d2030 can be entered as 10:20:30.
Unix shells (sh, bash, tsch) The characters and can be quoted by preceding them with a \ (backslash); or you can quote a string containing with a pair of s. The two alternatives are illustrated by
echo 10d20\30\" "20d3040" | GeoConvert -d -p -1 => 10d2030"N 020d3040"E
Quoting of command line arguments is similar
GeoConvert -d -p -1 --input-string "10d2030\" 20d3040" => 10d2030"N 020d3040"E
Windows command shell (cmd) The character needs no quoting; the " character can either be quoted by a ^ or can be represented by typing twice. (This quoting is usually unnecessary because the trailing designator can be omitted.) Thus
echo 10d2030 20d3040 | GeoConvert -d -p -1 => 10d2030"N 020d3040"E
Use \ to quote the " character in a command line argument
GeoConvert -d -p -1 --input-string "10d2030\" 20d3040" => 10d2030"N 020d3040"E
Input from a file No quoting need be done if the input from a file. Thus each line of the file input.txt should just contain the plain coordinates.
GeoConvert -d -p -1 < input.txt
MGRS coordinates represent a square patch of the earth, thus 38SMB4488 is in zone 38n with 444km <= easting < 445km and 3688km <= northing < 3689km. Consistent with this representation, coordinates are truncated (instead of rounded) to the requested precision. Similarly, on input an MGRS coordinate represents the center of the square (38n 444500 3688500 in the example above). However, if the -n option is given then the south-west corner of the square is returned instead (38n 444000 3688000 in the example above).
If the input is geographic, GeoConvert uses the standard rules of selecting UTM vs UPS and for assigning the UTM zone (with the Norway and Svalbard exceptions). If the input is UTM/UPS or MGRS, then the choice between UTM and UPS and the UTM zone mirrors the input. The -z zone, -s, and -t options allow these rules to be overridden with zone = 0 being used to indicate UPS. For example, the point
corresponds to possible MGRS coordinates
32CMS4324728161 (standard UTM zone = 32) 31CEM6066227959 (neighboring UTM zone = 31) BBZ1945517770 (neighboring UPS zone)
echo 79.9S 6.1E | GeoConvert -p -3 -m => 32CMS4328 echo 31CEM6066227959 | GeoConvert -p -3 -m => 31CEM6027 echo 31CEM6066227959 | GeoConvert -p -3 -m -s => 32CMS4328 echo 31CEM6066227959 | GeoConvert -p -3 -m -z 0 => BBZ1917
Is zone is specified with a hemisphere, then this is honored when printing UTM coordinates:
echo -1 3 | GeoConvert -u => 31s 500000 9889470 echo -1 3 | GeoConvert -u -z 31 => 31s 500000 9889470 echo -1 3 | GeoConvert -u -z 31s => 31s 500000 9889470 echo -1 3 | GeoConvert -u -z 31n => 31n 500000 -110530
NOTE: the letter in the zone specification for UTM is a hemisphere designator n or s and not an MGRS latitude band letter. Convert the MGRS latitude band letter to a hemisphere as follows: replace C thru M by s (or south); replace N thru X by n (or north).
echo 38SMB4488 | GeoConvert => 33.33424 44.40363 echo 38SMB4488 | GeoConvert -: -p 1 => 33:20:03.25N 044:2413.06E echo 38SMB4488 | GeoConvert -u => 38n 444500 3688500 echo E44d24 N33d20 | GeoConvert -m -p -3 => 38SMB4488
GeoConvert can be used to do simple arithmetic using degree, minutes, and seconds. For example, sometimes data is tiled in 15 second squares tagged by the DMS representation of the SW corner. The tags of the tile at 38:59:45N 077:02:00W and its 8 neighbors are then given by
t=0:0:15 for y in -$t +0 +$t; do for x in -$t +0 +$t; do echo 38:59:45N$y 077:02:00W$x done done | GeoConvert -: -p -1 | tr -d : => 385930N0770215W 385930N0770200W 385930N0770145W 385945N0770215W 385945N0770200W 385945N0770145W 390000N0770215W 390000N0770200W 390000N0770145W
An illegal line of input will print an error message to standard output beginning with ERROR: and causes GeoConvert to return an exit code of 1. However, an error does not cause GeoConvert to terminate; following lines will be converted.
UTM Universal Transverse Mercator, <https://en.wikipedia.org/wiki/Universal_Transverse_Mercator_coordinate_system>. UPS Universal Polar Stereographic, <https://en.wikipedia.org/wiki/Universal_Polar_Stereographic>. MGRS Military Grid Reference System, <https://en.wikipedia.org/wiki/Military_grid_reference_system>. WGS84 World Geodetic System 1984, <https://en.wikipedia.org/wiki/WGS84>.
An online version of this utility is availbable at <http://geographiclib.sourceforge.net/cgi-bin/GeoConvert>.
The algorithms for the transverse Mercator projection are described in C. F. F. Karney, Transverse Mercator with an accuracy of a few nanometers, J. Geodesy 85(8), 475-485 (Aug. 2011); DOI <https://dx.doi.org/10.1007/s00190-011-0445-3>; preprint <http://arxiv.org/abs/1002.1417>.
GeoConvert was written by Charles Karney.
GeoConvert was added to GeographicLib, <http://geographiclib.sourceforge.net>, in 2009-01.
|GeographicLib 1.46||GEOCONVERT (1)||2016-02-14|