/dports/astro/py-astropy/astropy-5.0/docs/wcs/ |
H A D | supported_projections.rst | 18 - ``AZP``: zenithal/azimuthal perspective 23 - ``ARC``: zenithal/azimuthal equidistant 24 - ``ZPN``: zenithal/azimuthal polynomial 25 - ``ZEA``: zenithal/azimuthal equal area
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/dports/astro/geographiclib/GeographicLib-1.52/tools/ |
H A D | GeodesicProj.cpp | 36 bool azimuthal = false, cassini = false, gnomonic = false, reverse = false, in main() local 51 cassini = azimuthal = gnomonic = false; in main() 53 azimuthal = arg == "-z"; in main() 152 if (!(azimuthal || cassini || gnomonic)) { in main() 195 else if (azimuthal) in main() 206 else if (azimuthal) in main()
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/dports/science/gnudatalanguage/gdl-1.0.1/src/pro/map/ |
H A D | map_proj_info.pro | 5 proj_names = list_of_pnames, circle=circle, conic=conic, azimuthal=azimuthal, uv_limits = uv_limits… 42 azimuthal=(property.AZI eq 1) 43 circle=azimuthal ; spheric and ~conic and ~cylindrical
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/dports/misc/vxl/vxl-3.3.2/contrib/brl/bseg/boxm2/pro/processes/ |
H A D | boxm2_compute_sun_affine_camera_process.cxx | 62 auto azimuthal = pro.get_input<float>(2); in boxm2_compute_sun_affine_camera_process() local 68 double az_rads = vnl_math::pi/180 * azimuthal; in boxm2_compute_sun_affine_camera_process() 75 sun_dir_downwards = vgl_vector_3d<double>(-std::sin(elevation)*std::cos(azimuthal), in boxm2_compute_sun_affine_camera_process() 76 -std::sin(elevation)*std::sin(azimuthal), in boxm2_compute_sun_affine_camera_process()
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/dports/misc/py-kartograph/kartograph.py-0.6.8/ |
H A D | CHANGELOG | 54 * fixed graticule for azimuthal projection 58 * bugfixed azimuthal projections 59 * refactored azimuthal projections in separate files
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/dports/astro/geographiclib/GeographicLib-1.52/dotnet/Projections/ |
H A D | ProjectionsPanel.cs | 211 AzimuthalEquidistant azimuthal = new AzimuthalEquidistant(m_geodesic); in OnValidate() 212 azimuthal = new AzimuthalEquidistant(); in OnValidate() 213 azimuthal.Forward(32.0, -86.0, 33.0, -87.0, out x, out y, out azi, out rk); in OnValidate() 214 azimuthal.Forward(32.0, -86.0, 33.0, -87.0, out x1, out y1); in OnValidate() 217 azimuthal.Reverse(32.0, -86.0, x, y, out lat, out lon, out azi, out rk); in OnValidate() 218 azimuthal.Reverse(32.0, -86.0, x, y, out x1, out y1); in OnValidate()
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/dports/devel/tcllib/tcllib-1.20/modules/mapproj/ |
H A D | mapproj.tcllib.man | 80 Converts to the stereographic (azimuthal conformal) projection. 82 Converts from the stereographic (azimuthal conformal) projection. 88 Converts to the azimuthal equidistant projection. 90 Converts from the azimuthal equidistant projection. 92 Converts to the Lambert azimuthal equal-area projection. 94 Converts from the Lambert azimuthal equal-area projection. 178 Latitude of the center of the sheet, in degrees. For the azimuthal 221 projections include the Mercator, the Albers azimuthal equal-area, 228 the sinusoidal projection, the Lambert azimuthal equal-area projection, 237 use one of the azimuthal projections. Appropriate choices are azimuthal [all …]
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/dports/devel/tcllibc/tcllib-1.20/modules/mapproj/ |
H A D | mapproj.tcllib.man | 80 Converts to the stereographic (azimuthal conformal) projection. 82 Converts from the stereographic (azimuthal conformal) projection. 88 Converts to the azimuthal equidistant projection. 90 Converts from the azimuthal equidistant projection. 92 Converts to the Lambert azimuthal equal-area projection. 94 Converts from the Lambert azimuthal equal-area projection. 178 Latitude of the center of the sheet, in degrees. For the azimuthal 221 projections include the Mercator, the Albers azimuthal equal-area, 228 the sinusoidal projection, the Lambert azimuthal equal-area projection, 237 use one of the azimuthal projections. Appropriate choices are azimuthal [all …]
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/dports/databases/grass7/grass-7.8.6/imagery/i.atcorr/test_suite/ |
H A D | ETM4.res | 40 * solar zenith angle: 35.65 deg solar azimuthal angle: 80.87 deg * 41 * view zenith angle: 0.00 deg view azimuthal angle: 0.00 deg * 42 * scattering angle: 144.35 deg azimuthal angle difference: 80.87 deg *
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/dports/astro/geographiclib/GeographicLib-1.52/matlab/geographiclib/ |
H A D | eqdazim_inv.m | 2 %EQDAZIM_INV Inverse azimuthal equidistant projection 7 % performs the inverse azimuthal equidistant projection of points (x,y) 19 % the reciprocal of the azimuthal scale. The scale in the radial
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H A D | eqdazim_fwd.m | 2 %EQDAZIM_FWD Forward azimuthal equidistant projection 7 % performs the forward azimuthal equidistant projection of points 19 % the reciprocal of the azimuthal scale. The scale in the radial
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/dports/science/eccodes/eccodes-2.23.0-Source/definitions/grib2/tables/0/ |
H A D | 3.1.table | 19 110 110 Equatorial azimuthal equidistant projection 22 140 140 Lambert azimuthal equal area projection
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/dports/science/eccodes/eccodes-2.23.0-Source/definitions/grib2/tables/1/ |
H A D | 3.1.table | 19 110 110 Equatorial azimuthal equidistant projection 22 140 140 Lambert azimuthal equal area projection
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/dports/astro/geographiclib/GeographicLib-1.52/man/ |
H A D | GeodesicProj.pod | 18 either azimuthal equidistant, Cassini-Soldner, or gnomonic coordinates. 20 the B<-c> option (for Cassini-Soldner), the B<-z> option (for azimuthal 33 the scale in the northing direction is 1/I<rk>. For azimuthal 35 and the scale in the azimuthal direction is 1/I<rk>. For azimuthal 45 use the azimuthal equidistant projection centered at latitude = I<lat0>,
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H A D | GeodesicProj.usage | 26 " to either azimuthal equidistant, Cassini-Soldner, or gnomonic\n" 29 " azimuthal equidistant), or the -g option (for gnomonic). At least one\n" 41 " direction is 1/rk. For azimuthal equidistant and gnomonic, azi is the\n" 42 " bearing of the radial direction and the scale in the azimuthal\n" 43 " direction is 1/rk. For azimuthal equidistant and gnomonic, the scales\n" 48 " use the azimuthal equidistant projection centered at latitude =\n"
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/dports/astro/wcslib/wcslib-7.7/doxygen/ |
H A D | prj_extras.dox | 4 * the <B>zenithal/azimuthal perspective (<TT>AZP</TT>)</B> 8 * a <B>zenithal/azimuthal perspective (<TT>AZP</TT>)</B> 17 * <B>zenithal/azimuthal perspective (<TT>AZP</TT>)</B> 21 * a <B>zenithal/azimuthal perspective (<TT>AZP</TT>)</B> 30 * <B>zenithal/azimuthal perspective (<TT>AZP</TT>)</B> 35 * a <B>zenithal/azimuthal perspective (<TT>AZP</TT>)</B> 245 * <B>zenithal/azimuthal polynomial (<TT>ZPN</TT>)</B> 258 * <B>zenithal/azimuthal polynomial (<TT>ZPN</TT>)</B> 271 * <B>zenithal/azimuthal polynomial (<TT>ZPN</TT>)</B> 285 * <B>zenithal/azimuthal equal area (<TT>ZEA</TT>)</B> [all …]
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/dports/devel/tcllib/tcllib-1.20/embedded/md/tcllib/files/modules/mapproj/ |
H A D | mapproj.md | 206 Converts to the stereographic \(azimuthal conformal\) projection\. 210 Converts from the stereographic \(azimuthal conformal\) projection\. 222 Converts to the azimuthal equidistant projection\. 226 Converts from the azimuthal equidistant projection\. 230 Converts to the Lambert azimuthal equal\-area projection\. 234 Converts from the Lambert azimuthal equal\-area projection\. 350 Latitude of the center of the sheet, in degrees\. For the azimuthal 402 *plate carrée*, Cassini, azimuthal equidistant, or conic equidistant\. If 405 of the azimuthal projections\. Appropriate choices are azimuthal equidistant, 406 azimuthal equal\-area, stereographic, and perhaps orthographic\. [all …]
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/dports/devel/tcllibc/tcllib-1.20/embedded/md/tcllib/files/modules/mapproj/ |
H A D | mapproj.md | 206 Converts to the stereographic \(azimuthal conformal\) projection\. 210 Converts from the stereographic \(azimuthal conformal\) projection\. 222 Converts to the azimuthal equidistant projection\. 226 Converts from the azimuthal equidistant projection\. 230 Converts to the Lambert azimuthal equal\-area projection\. 234 Converts from the Lambert azimuthal equal\-area projection\. 350 Latitude of the center of the sheet, in degrees\. For the azimuthal 402 *plate carrée*, Cassini, azimuthal equidistant, or conic equidistant\. If 405 of the azimuthal projections\. Appropriate choices are azimuthal equidistant, 406 azimuthal equal\-area, stereographic, and perhaps orthographic\. [all …]
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/dports/science/grib_api/grib_api-1.28.0-Source/definitions/grib2/tables/6/ |
H A D | 3.1.table | 28 110 110 Equatorial azimuthal equidistant projection 34 140 140 Lambert azimuthal equal area projection
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/dports/science/grib_api/grib_api-1.28.0-Source/definitions/grib2/tables/5/ |
H A D | 3.1.table | 28 110 110 Equatorial azimuthal equidistant projection 34 140 140 Lambert azimuthal equal area projection
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/dports/science/grib_api/grib_api-1.28.0-Source/definitions/grib2/tables/3/ |
H A D | 3.1.table | 28 110 110 Equatorial azimuthal equidistant projection 34 140 140 Lambert azimuthal equal area projection
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/dports/science/grib_api/grib_api-1.28.0-Source/definitions/grib2/tables/4/ |
H A D | 3.1.table | 28 110 110 Equatorial azimuthal equidistant projection 34 140 140 Lambert azimuthal equal area projection
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/dports/science/grib_api/grib_api-1.28.0-Source/definitions/grib2/tables/2/ |
H A D | 3.1.table | 28 110 110 Equatorial azimuthal equidistant projection 34 140 140 Lambert azimuthal equal area projection
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/dports/science/grib_api/grib_api-1.28.0-Source/definitions/grib2/tables/1/ |
H A D | 3.1.table | 28 110 110 Equatorial azimuthal equidistant projection 34 140 140 Lambert azimuthal equal area projection
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/dports/science/grib_api/grib_api-1.28.0-Source/definitions/grib2/tables/0/ |
H A D | 3.1.table | 28 110 110 Equatorial azimuthal equidistant projection 34 140 140 Lambert azimuthal equal area projection
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