def test_polar_stereographic_b_operation__defaults():
    aeop = PolarStereographicBConversion()
    assert aeop.name == "unknown"
    assert aeop.method_name == "Polar Stereographic (variant B)"
    assert _to_dict(aeop) == {
        "Latitude of standard parallel": 0.0,
        "Longitude of origin": 0.0,
        "False easting": 0.0,
        "False northing": 0.0,
    }
def test_polar_stereographic_b_operation():
    aeop = PolarStereographicBConversion(
        latitude_standard_parallel=1,
        longitude_origin=2,
        false_easting=3,
        false_northing=4,
    )
    assert aeop.name == "unknown"
    assert aeop.method_name == "Polar Stereographic (variant B)"
    assert _to_dict(aeop) == {
        "Latitude of standard parallel": 1.0,
        "Longitude of origin": 2.0,
        "False easting": 3.0,
        "False northing": 4.0,
    }
Exemplo n.º 3
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def _polar_stereographic(cf_params):
    """
    http://cfconventions.org/cf-conventions/cf-conventions.html#polar-stereographic
    """
    if "standard_parallel" in cf_params:
        return PolarStereographicBConversion(
            latitude_standard_parallel=cf_params["standard_parallel"],
            longitude_origin=cf_params["straight_vertical_longitude_from_pole"],
            false_easting=cf_params.get("false_easting", 0.0),
            false_northing=cf_params.get("false_northing", 0.0),
        )
    return PolarStereographicAConversion(
        latitude_natural_origin=cf_params["latitude_of_projection_origin"],
        longitude_natural_origin=cf_params["straight_vertical_longitude_from_pole"],
        false_easting=cf_params.get("false_easting", 0.0),
        false_northing=cf_params.get("false_northing", 0.0),
        scale_factor_natural_origin=cf_params.get(
            "scale_factor_at_projection_origin", 1.0
        ),
    )
Exemplo n.º 4
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def test_polar_stereographic_b():
    crs = ProjectedCRS(conversion=PolarStereographicBConversion(0, 1, 2, 3))
    expected_cf = {
        "semi_major_axis": 6378137.0,
        "semi_minor_axis": crs.ellipsoid.semi_minor_metre,
        "inverse_flattening": crs.ellipsoid.inverse_flattening,
        "reference_ellipsoid_name": "WGS 84",
        "longitude_of_prime_meridian": 0.0,
        "prime_meridian_name": "Greenwich",
        "horizontal_datum_name": "World Geodetic System 1984",
        "grid_mapping_name": "polar_stereographic",
        "standard_parallel": 0.0,
        "straight_vertical_longitude_from_pole": 1.0,
        "false_easting": 2.0,
        "false_northing": 3.0,
    }
    cf_dict = crs.to_cf()
    assert cf_dict.pop("crs_wkt").startswith("PROJCRS[")
    assert cf_dict == expected_cf
    # test roundtrip
    _test_roundtrip(expected_cf, "PROJCRS[")