Provided by: geographiclib-tools_2.4-1_amd64 bug

NAME

       IntersectTool -- perform rhumb line calculations

SYNOPSIS

       IntersectTool [ -c | -n | -i | -o | [ -R maxdist ] [ -e a f] [ -E ] [ -w ] [ -p prec ] [
       --comment-delimiter commentdelim ] [ --version | -h | --help ] [ --input-file infile |
       --input-string instring ] [ --line-separator linesep ] [ --output-file outfile ]

DESCRIPTION

       IntersectTool finds the intersection of two geodesics X and Y.  The geodesics may either
       be specified as a location and an azimuth, latX lonX aziX, or as the shortest geodesic
       segment between two locations, latX1 lonX1 and latX2 lonX2.  The intersection is then
       specified as the displacements, x and y, along the geodesics X and Y from the starting
       points to the intersection.  In the case of the intersection of geodesic segments, the
       starting point is first point specified for X or Y.

       Usually this tool returns the closest intersection defined as the one that minimizes the
       "L1" distance, |x| + |y|.  However, it is possible to specify an "origin" x0 and y0 when
       determining closeness so that the intersection which minimizes |x - x0| + |y - y0| is
       returned.

       In the case of intersecting segments the origin is taken to be the midpoints of the
       segments; x0 is half the distance from X1 to X2.  In addition a flag is returned
       specifying whether the intersection is "within" the segments.

       The tool also returns a "coincidence indicator" c.  This is typically 0.  However if the
       geodesics lie on top of one another at the point of intersection, then c is set to 1, if
       they are parallel, and -1, if they are antiparallel.

       IntersectTool operates in one of three modes:

       1.  With the -c option (the default), IntersectTool accepts lines on the standard input
           containing latX lonX aziX latY lonY aziY, specifying two geodesic lines X and Y, and
           prints the location of the closest intersection x y c on standard output.

       2.  With the -n option, IntersectTool accepts lines on the standard input containing latX
           lonX aziX aziY aziY, specifying a point where two geodesic lines X and Y intersect,
           and prints the location of the next closest intersection x y c on standard output.

       3.  With the -i option, IntersectTool accepts lines on the standard input containing latX1
           lonX1 latX2 lonX2 latY1 lonY1 latY2 lonY2, specifying two geodesic segments X1-X2 and
           Y1-Y2, and prints x y c k on standard output.  Here k is a flag in [-4,4] specifying
           whether the intersection is within the segments (0) or not (non-zero).  x and y give
           the distances from X1 and Y1 respectively.  k is set to 3 kx + ky where kx = -1 if x <
           0, 0 if 0 <= x <= sx, 1 if sx < x, and similarly for ky; sx is the length of the
           segment X1-X2.

       4.  With the -o option, IntersectTool accepts lines on the standard input containing latX
           lonX aziX latY lonY aziY x0 y0, specifying two geodesic lines X and Y and two offsets,
           and prints x y c on standard output where [x, y] is the intersection closest to [x0,
           y0].

OPTIONS

       -c  find the closest intersection (see 1 above).

       -n  find the intersection closest to a given intersection (see 2 above).

       -i  find the intersection of two geodesic segments (see 3 above).

       -o  find the closest intersection with an offset.

       -R maxdist
           modifies the four modes to return all the intersections within an L1 distance,
           maxdist, of the relevant origin: [0, 0] for -c and -n, the midpoints of the segments
           for -i, and [x0, y0] for -o.  For each intersection, x y c z is printed on standard
           output.  Here z is the L1 distance of the intersection from the origin and the
           intersections are sorted by the distances.  A line "nan nan 0 nan" is added after the
           intersections, so that the output can be associated with the correct lines of the
           input.  The number of intersections scales as (maxdist/(pi a))^2.

       -C  check the intersections.  For each computed intersection, print on standard error a
           line latX lonX latY lonY sXY giving the computed positions of the intersections points
           on X and Y and the distance between them.  If -w is specified, the longitude is given
           before the latitude.

       -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.

       -E  use "exact" algorithms (based on elliptic integrals) for the geodesic calculations.
           These are more accurate than the (default) series expansions for |f| > 0.02.

       -w  on input, 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 3); prec is the precision relative to 1 m.
           See "PRECISION".

       --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.

INPUT

       IntersectTool measures all angles in degrees and all lengths in meters.  On input angles
       (latitude, longitude, azimuth) can be as decimal degrees or degrees, minutes, seconds.
       For example, "40d30", "40d30'", "40:30", "40.5d", and 40.5 are all equivalent.  By
       default, latitude precedes longitude for each point (the -w flag switches this
       convention); however either may be given first by appending (or prepending) N or S to the
       latitude and E or W to the longitude.  Azimuths are measured clockwise from north; however
       this may be overridden with E or W.

       For details on the allowed formats for angles, see the "GEOGRAPHIC COORDINATES" section of
       GeoConvert(1).

PRECISION

       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 lengths.  The
       latitude and longitude printed to standard error with the -C option are given in decimal
       degrees with prec + 5 digits after the decimal point.  The minimum value of prec is 0 and
       the maximum is 10.

ERRORS

       An illegal line of input will print an error message to standard output beginning with
       "ERROR:" and causes IntersectTool to return an exit code of 1.  However, an error does not
       cause IntersectTool to terminate; following lines will be converted.

ACCURACY

       This tool will give nearly full double precision accuracy for |f| < 0.02.  If the -E
       option is given, full accuracy is achieved for -1/4 < f < 1/5.  The tool had not been
       tested outside this range.

EXAMPLES

       A vessel leaves Plymouth 50N 4W on a geodesic path with initial heading 147.7W.  When will
       it first cross the equator?

          echo 50N 4W 147.7W 0 0 90 | IntersectTool -c -p 0 -C

          6058049 -3311253 0
          0.00000 -29.74549 -0.00000 -29.74549 0

       Answer: after 6058km at longitude 29.7W.  When will it cross the date line, longitude
       180E?  Here we need to use -R because there a closer intersection on the prime meridian:

          echo 50N 4W 147.7W 0 180 0 | IntersectTool -c -p 0 -C -R 2.6e7

          -494582 14052230 0 14546812
          53.69260 0.00000 53.69260 0.00000 0
          19529110 -5932344 0 25461454
          -53.51867 180.00000 -53.51867 180.00000 0
          nan nan 0 nan
          nan nan nan nan nan

       We want the second result: after 19529 km at latitude 53.5S.

SEE ALSO

       GeoConvert(1), GeodSolve(1).

       This solution for intersections is described in C. F. F. Karney, Geodesic intersections,
       J. Surveying Eng. 150(3), 04024005:1-9 (2024), DOI:
       <https://doi.org/10.1061/JSUED2.SUENG-1483>; preprint <https://arxiv.org/abs/2308.00495>.
       It is based on the work of S. Baseldga and J. C. Martinez-Llario, Intersection and point-
       to-line solutions for geodesics on the ellipsoid, Stud. Geophys. Geod. 62, 353-363 (2018);
       DOI: <https://doi.org/10.1007/s11200-017-1020-z>;

AUTHOR

       IntersectTool was written by Charles Karney.

HISTORY

       IntersectTool was added to GeographicLib, <https://geographiclib.sourceforge.io>, in
       version 2.3.