# (C) British Crown Copyright 2013 - 2018, Met Office # # This file is part of cartopy. # # cartopy is free software: you can redistribute it and/or modify it under # the terms of the GNU Lesser General Public License as published by the # Free Software Foundation, either version 3 of the License, or # (at your option) any later version. # # cartopy is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public License # along with cartopy. If not, see . from __future__ import (absolute_import, division, print_function) import numpy as np from numpy.testing import assert_almost_equal import cartopy.crs as ccrs from .helpers import check_proj_params class TestStereographic(object): def test_default(self): stereo = ccrs.Stereographic() other_args = {'ellps=WGS84', 'lat_0=0.0', 'lon_0=0.0', 'x_0=0.0', 'y_0=0.0'} check_proj_params('stere', stereo, other_args) assert_almost_equal(np.array(stereo.x_limits), [-5e7, 5e7], decimal=4) assert_almost_equal(np.array(stereo.y_limits), [-5e7, 5e7], decimal=4) def test_eccentric_globe(self): globe = ccrs.Globe(semimajor_axis=1000, semiminor_axis=500, ellipse=None) stereo = ccrs.Stereographic(globe=globe) other_args = {'a=1000', 'b=500', 'lat_0=0.0', 'lon_0=0.0', 'x_0=0.0', 'y_0=0.0'} check_proj_params('stere', stereo, other_args) # The limits in this test are sensible values, but are by no means # a "correct" answer - they mean that plotting the crs results in a # reasonable map. assert_almost_equal(np.array(stereo.x_limits), [-7839.27971444, 7839.27971444], decimal=4) assert_almost_equal(np.array(stereo.y_limits), [-3932.82587779, 3932.82587779], decimal=4) def test_true_scale(self): # The "true_scale_latitude" parameter only makes sense for # polar stereographic projections (#339 and #455). # For now only the proj string creation is tested # See test_scale_factor for test on projection. globe = ccrs.Globe(ellipse='sphere') stereo = ccrs.NorthPolarStereo(true_scale_latitude=30, globe=globe) other_args = {'ellps=sphere', 'lat_0=90', 'lon_0=0.0', 'lat_ts=30', 'x_0=0.0', 'y_0=0.0'} check_proj_params('stere', stereo, other_args) def test_scale_factor(self): # See #455 # Use spherical Earth in North Polar Stereographic to check # equivalence between true_scale and scale_factor. # In these conditions a scale factor of 0.75 corresponds exactly to # a standard parallel of 30N. globe = ccrs.Globe(ellipse='sphere') stereo = ccrs.Stereographic(central_latitude=90., scale_factor=0.75, globe=globe) other_args = {'ellps=sphere', 'lat_0=90.0', 'lon_0=0.0', 'k_0=0.75', 'x_0=0.0', 'y_0=0.0'} check_proj_params('stere', stereo, other_args) # Now test projections lon, lat = 10, 10 projected_scale_factor = stereo.transform_point(lon, lat, ccrs.Geodetic()) # should be equivalent to North Polar Stereo with # true_scale_latitude = 30 nstereo = ccrs.NorthPolarStereo(globe=globe, true_scale_latitude=30) projected_true_scale = nstereo.transform_point(lon, lat, ccrs.Geodetic()) assert projected_true_scale == projected_scale_factor def test_eastings(self): stereo = ccrs.Stereographic() stereo_offset = ccrs.Stereographic(false_easting=1234, false_northing=-4321) other_args = {'ellps=WGS84', 'lat_0=0.0', 'lon_0=0.0', 'x_0=1234', 'y_0=-4321'} check_proj_params('stere', stereo_offset, other_args) assert (tuple(np.array(stereo.x_limits) + 1234) == stereo_offset.x_limits)