/usr/lib/python2.7/dist-packages/cartopy/crs.py is in python-cartopy 0.14.2+dfsg1-2build3.
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#
# 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 <https://www.gnu.org/licenses/>.
"""
The crs module defines Coordinate Reference Systems and the transformations
between them.
"""
from __future__ import (absolute_import, division, print_function)
from abc import ABCMeta, abstractproperty
import math
import warnings
import numpy as np
import shapely.geometry as sgeom
from shapely.prepared import prep
import six
from cartopy._crs import CRS, Geocentric, Geodetic, Globe, PROJ4_VERSION
import cartopy.trace
__document_these__ = ['CRS', 'Geocentric', 'Geodetic', 'Globe']
WGS84_SEMIMAJOR_AXIS = 6378137.0
WGS84_SEMIMINOR_AXIS = 6356752.3142
class RotatedGeodetic(CRS):
"""
Defines a rotated latitude/longitude coordinate system with spherical
topology and geographical distance.
Coordinates are measured in degrees.
"""
def __init__(self, pole_longitude, pole_latitude,
central_rotated_longitude=0.0, globe=None):
"""
Create a RotatedGeodetic CRS.
The class uses proj4 to perform an ob_tran operation, using the
pole_longitude to set a lon_0 then performing two rotations based on
pole_latitude and central_rotated_longitude.
This is equivalent to setting the new pole to a location defined by
the pole_latitude and pole_longitude values in the GeogCRS defined by
globe, then rotating this new CRS about it's pole using the
central_rotated_longitude value.
Args:
* pole_longitude - Pole longitude position, in unrotated degrees.
* pole_latitude - Pole latitude position, in unrotated degrees.
* central_rotated_longitude - Longitude rotation about the new
pole, in degrees.
Kwargs:
* globe - An optional :class:`cartopy.crs.Globe`.
Defaults to a "WGS84" datum.
"""
proj4_params = [('proj', 'ob_tran'), ('o_proj', 'latlon'),
('o_lon_p', central_rotated_longitude),
('o_lat_p', pole_latitude),
('lon_0', 180 + pole_longitude),
('to_meter', math.radians(1))]
globe = globe or Globe(datum='WGS84')
super(RotatedGeodetic, self).__init__(proj4_params, globe=globe)
class Projection(six.with_metaclass(ABCMeta, CRS)):
"""
Defines a projected coordinate system with flat topology and Euclidean
distance.
"""
_method_map = {
'Point': '_project_point',
'LineString': '_project_line_string',
'LinearRing': '_project_linear_ring',
'Polygon': '_project_polygon',
'MultiPoint': '_project_multipoint',
'MultiLineString': '_project_multiline',
'MultiPolygon': '_project_multipolygon',
}
@abstractproperty
def boundary(self):
pass
@abstractproperty
def threshold(self):
pass
@abstractproperty
def x_limits(self):
pass
@abstractproperty
def y_limits(self):
pass
@property
def cw_boundary(self):
try:
boundary = self._cw_boundary
except AttributeError:
boundary = sgeom.LineString(self.boundary)
self._cw_boundary = boundary
return boundary
@property
def ccw_boundary(self):
try:
boundary = self._ccw_boundary
except AttributeError:
boundary = sgeom.LineString(self.boundary.coords[::-1])
self._ccw_boundary = boundary
return boundary
@property
def domain(self):
try:
domain = self._domain
except AttributeError:
domain = self._domain = sgeom.Polygon(self.boundary)
return domain
def _as_mpl_axes(self):
import cartopy.mpl.geoaxes as geoaxes
return geoaxes.GeoAxes, {'map_projection': self}
def project_geometry(self, geometry, src_crs=None):
"""
Projects the given geometry into this projection.
:param geometry: The geometry to (re-)project.
:param src_crs: The source CRS, or geodetic CRS if None.
:rtype: Shapely geometry.
If src_crs is None, the source CRS is assumed to be a geodetic
version of the target CRS.
"""
if src_crs is None:
src_crs = self.as_geodetic()
elif not isinstance(src_crs, CRS):
raise TypeError('Source CRS must be an instance of CRS'
' or one of its subclasses, or None.')
geom_type = geometry.geom_type
method_name = self._method_map.get(geom_type)
if not method_name:
raise ValueError('Unsupported geometry '
'type {!r}'.format(geom_type))
return getattr(self, method_name)(geometry, src_crs)
def _project_point(self, point, src_crs):
return sgeom.Point(*self.transform_point(point.x, point.y, src_crs))
def _project_line_string(self, geometry, src_crs):
return cartopy.trace.project_linear(geometry, src_crs, self)
def _project_linear_ring(self, linear_ring, src_crs):
"""
Projects the given LinearRing from the src_crs into this CRS and
returns a list of LinearRings and a single MultiLineString.
"""
debug = False
# 1) Resolve the initial lines into projected segments
# 1abc
# def23ghi
# jkl41
multi_line_string = cartopy.trace.project_linear(linear_ring,
src_crs, self)
# Threshold for whether a point is close enough to be the same
# point as another.
threshold = max(np.abs(self.x_limits + self.y_limits)) * 1e-5
# 2) Simplify the segments where appropriate.
if len(multi_line_string) > 1:
# Stitch together segments which are close to continuous.
# This is important when:
# 1) The first source point projects into the map and the
# ring has been cut by the boundary.
# Continuing the example from above this gives:
# def23ghi
# jkl41abc
# 2) The cut ends of segments are too close to reliably
# place into an order along the boundary.
line_strings = list(multi_line_string)
any_modified = False
i = 0
if debug:
first_coord = np.array([ls.coords[0] for ls in line_strings])
last_coord = np.array([ls.coords[-1] for ls in line_strings])
print('Distance matrix:')
np.set_printoptions(precision=2)
x = first_coord[:, np.newaxis, :]
y = last_coord[np.newaxis, :, :]
print(np.abs(x - y).max(axis=-1))
while i < len(line_strings):
modified = False
j = 0
while j < len(line_strings):
if i != j and np.allclose(line_strings[i].coords[0],
line_strings[j].coords[-1],
atol=threshold):
if debug:
print('Joining together {} and {}.'.format(i, j))
last_coords = list(line_strings[j].coords)
first_coords = list(line_strings[i].coords)[1:]
combo = sgeom.LineString(last_coords + first_coords)
if j < i:
i, j = j, i
del line_strings[j], line_strings[i]
line_strings.append(combo)
modified = True
any_modified = True
break
else:
j += 1
if not modified:
i += 1
if any_modified:
multi_line_string = sgeom.MultiLineString(line_strings)
# 3) Check for rings that have been created by the projection stage.
rings = []
line_strings = []
for line in multi_line_string:
if len(line.coords) > 3 and np.allclose(line.coords[0],
line.coords[-1],
atol=threshold):
result_geometry = sgeom.LinearRing(line.coords[:-1])
rings.append(result_geometry)
else:
line_strings.append(line)
# If we found any rings, then we should re-create the multi-line str.
if rings:
multi_line_string = sgeom.MultiLineString(line_strings)
return rings, multi_line_string
def _project_multipoint(self, geometry, src_crs):
geoms = []
for geom in geometry.geoms:
geoms.append(self._project_point(geom, src_crs))
if geoms:
return sgeom.MultiPoint(geoms)
else:
return sgeom.MultiPoint()
def _project_multiline(self, geometry, src_crs):
geoms = []
for geom in geometry.geoms:
r = self._project_line_string(geom, src_crs)
if r:
geoms.extend(r.geoms)
if geoms:
return sgeom.MultiLineString(geoms)
else:
return []
def _project_multipolygon(self, geometry, src_crs):
geoms = []
for geom in geometry.geoms:
r = self._project_polygon(geom, src_crs)
if r:
geoms.extend(r.geoms)
if geoms:
result = sgeom.MultiPolygon(geoms)
else:
result = sgeom.MultiPolygon()
return result
def _project_polygon(self, polygon, src_crs):
"""
Returns the projected polygon(s) derived from the given polygon.
"""
# Determine orientation of polygon.
# TODO: Consider checking the internal rings have the opposite
# orientation to the external rings?
if src_crs.is_geodetic():
is_ccw = True
else:
is_ccw = polygon.exterior.is_ccw
# Project the polygon exterior/interior rings.
# Each source ring will result in either a ring, or one or more
# lines.
rings = []
multi_lines = []
for src_ring in [polygon.exterior] + list(polygon.interiors):
p_rings, p_mline = self._project_linear_ring(src_ring, src_crs)
if p_rings:
rings.extend(p_rings)
if len(p_mline) > 0:
multi_lines.append(p_mline)
# Convert any lines to rings by attaching them to the boundary.
if multi_lines:
rings.extend(self._attach_lines_to_boundary(multi_lines, is_ccw))
# Resolve all the inside vs. outside rings, and convert to the
# final MultiPolygon.
return self._rings_to_multi_polygon(rings, is_ccw)
def _attach_lines_to_boundary(self, multi_line_strings, is_ccw):
"""
Returns a list of LinearRings by attaching the ends of the given lines
to the boundary, paying attention to the traversal directions of the
lines and boundary.
"""
debug = False
debug_plot_edges = False
# Accumulate all the boundary and segment end points, along with
# their distance along the boundary.
edge_things = []
# Get the boundary as a LineString of the correct orientation
# so we can compute distances along it.
if is_ccw:
boundary = self.ccw_boundary
else:
boundary = self.cw_boundary
def boundary_distance(xy):
return boundary.project(sgeom.Point(*xy))
# Squash all the LineStrings into a single list.
line_strings = []
for multi_line_string in multi_line_strings:
line_strings.extend(multi_line_string)
# Record the positions of all the segment ends
for i, line_string in enumerate(line_strings):
first_dist = boundary_distance(line_string.coords[0])
thing = _BoundaryPoint(first_dist, False,
(i, 'first', line_string.coords[0]))
edge_things.append(thing)
last_dist = boundary_distance(line_string.coords[-1])
thing = _BoundaryPoint(last_dist, False,
(i, 'last', line_string.coords[-1]))
edge_things.append(thing)
# Record the positions of all the boundary vertices
for xy in boundary.coords[:-1]:
point = sgeom.Point(*xy)
dist = boundary.project(point)
thing = _BoundaryPoint(dist, True, point)
edge_things.append(thing)
if debug_plot_edges:
import matplotlib.pyplot as plt
current_fig = plt.gcf()
fig = plt.figure()
# Reset the current figure so we don't upset anything.
plt.figure(current_fig.number)
ax = fig.add_subplot(1, 1, 1)
# Order everything as if walking around the boundary.
# NB. We make line end-points take precedence over boundary points
# to ensure that end-points are still found and followed when they
# coincide.
edge_things.sort(key=lambda thing: (thing.distance, thing.kind))
remaining_ls = dict(enumerate(line_strings))
prev_thing = None
for edge_thing in edge_things[:]:
if (prev_thing is not None and
not edge_thing.kind and
not prev_thing.kind and
edge_thing.data[0] == prev_thing.data[0]):
j = edge_thing.data[0]
# Insert a edge boundary point in between this geometry.
mid_dist = (edge_thing.distance + prev_thing.distance) * 0.5
mid_point = boundary.interpolate(mid_dist)
new_thing = _BoundaryPoint(mid_dist, True, mid_point)
if debug:
print('Artificially insert boundary: {}'.format(new_thing))
ind = edge_things.index(edge_thing)
edge_things.insert(ind, new_thing)
prev_thing = None
else:
prev_thing = edge_thing
if debug:
print()
print('Edge things')
for thing in edge_things:
print(' ', thing)
if debug_plot_edges:
for thing in edge_things:
if isinstance(thing.data, sgeom.Point):
ax.plot(*thing.data.xy, marker='o')
else:
ax.plot(*thing.data[2], marker='o')
ls = line_strings[thing.data[0]]
coords = np.array(ls.coords)
ax.plot(coords[:, 0], coords[:, 1])
ax.text(coords[0, 0], coords[0, 1], thing.data[0])
ax.text(coords[-1, 0], coords[-1, 1],
'{}.'.format(thing.data[0]))
processed_ls = []
while remaining_ls:
# Rename line_string to current_ls
i, current_ls = remaining_ls.popitem()
if debug:
import sys
sys.stdout.write('+')
sys.stdout.flush()
print()
print('Processing: %s, %s' % (i, current_ls))
# We only want to consider boundary-points, the starts-and-ends of
# all other line-strings, or the start-point of the current
# line-string.
def filter_fn(t):
return (t.kind or
t.data[0] != i or
t.data[1] != 'last')
edge_things = list(filter(filter_fn, edge_things))
added_linestring = set()
while True:
# Find out how far around this linestring's last
# point is on the boundary. We will use this to find
# the next point on the boundary.
d_last = boundary_distance(current_ls.coords[-1])
if debug:
print(' d_last: {!r}'.format(d_last))
next_thing = _find_first_gt(edge_things, d_last)
# Remove this boundary point from the edge.
edge_things.remove(next_thing)
if debug:
print(' next_thing:', next_thing)
if next_thing.kind:
# We've just got a boundary point, add it, and keep going.
if debug:
print(' adding boundary point')
boundary_point = next_thing.data
combined_coords = (list(current_ls.coords) +
[(boundary_point.x, boundary_point.y)])
current_ls = sgeom.LineString(combined_coords)
elif next_thing.data[0] == i and next_thing.data[1] == 'first':
# We've gone all the way around and are now back at the
# first boundary thing.
if debug:
print(' close loop')
processed_ls.append(current_ls)
if debug_plot_edges:
coords = np.array(current_ls.coords)
ax.plot(coords[:, 0], coords[:, 1], color='black',
linestyle='--')
break
else:
if debug:
print(' adding line')
j = next_thing.data[0]
line_to_append = line_strings[j]
if j in remaining_ls:
remaining_ls.pop(j)
coords_to_append = list(line_to_append.coords)
if next_thing.data[1] == 'last':
coords_to_append = coords_to_append[::-1]
# Build up the linestring.
current_ls = sgeom.LineString((list(current_ls.coords) +
coords_to_append))
# Catch getting stuck in an infinite loop by checking that
# linestring only added once.
if j not in added_linestring:
added_linestring.add(j)
else:
if debug_plot_edges:
plt.show()
raise RuntimeError('Unidentified problem with '
'geometry, linestring being '
're-added. Please raise an issue.')
# filter out any non-valid linear rings
processed_ls = [linear_ring for linear_ring in processed_ls if
len(linear_ring.coords) > 2]
linear_rings = [sgeom.LinearRing(line) for line in processed_ls]
if debug:
print(' DONE')
return linear_rings
def _rings_to_multi_polygon(self, rings, is_ccw):
exterior_rings = []
interior_rings = []
for ring in rings:
if ring.is_ccw != is_ccw:
interior_rings.append(ring)
else:
exterior_rings.append(ring)
polygon_bits = []
# Turn all the exterior rings into polygon definitions,
# "slurping up" any interior rings they contain.
for exterior_ring in exterior_rings:
polygon = sgeom.Polygon(exterior_ring)
prep_polygon = prep(polygon)
holes = []
for interior_ring in interior_rings[:]:
if prep_polygon.contains(interior_ring):
holes.append(interior_ring)
interior_rings.remove(interior_ring)
elif polygon.crosses(interior_ring):
# Likely that we have an invalid geometry such as
# that from #509 or #537.
holes.append(interior_ring)
interior_rings.remove(interior_ring)
polygon_bits.append((exterior_ring.coords,
[ring.coords for ring in holes]))
# Any left over "interior" rings need "inverting" with respect
# to the boundary.
if interior_rings:
boundary_poly = self.domain
x3, y3, x4, y4 = boundary_poly.bounds
bx = (x4 - x3) * 0.1
by = (y4 - y3) * 0.1
x3 -= bx
y3 -= by
x4 += bx
y4 += by
for ring in interior_rings:
polygon = sgeom.Polygon(ring)
if polygon.is_valid:
x1, y1, x2, y2 = polygon.bounds
bx = (x2 - x1) * 0.1
by = (y2 - y1) * 0.1
x1 -= bx
y1 -= by
x2 += bx
y2 += by
box = sgeom.box(min(x1, x3), min(y1, y3),
max(x2, x4), max(y2, y4))
# Invert the polygon
polygon = box.difference(polygon)
# Intersect the inverted polygon with the boundary
polygon = boundary_poly.intersection(polygon)
if not polygon.is_empty:
polygon_bits.append(polygon)
if polygon_bits:
multi_poly = sgeom.MultiPolygon(polygon_bits)
else:
multi_poly = sgeom.MultiPolygon()
return multi_poly
def quick_vertices_transform(self, vertices, src_crs):
"""
Where possible, return a vertices array transformed to this CRS from
the given vertices array of shape ``(n, 2)`` and the source CRS.
.. important::
This method may return None to indicate that the vertices cannot
be transformed quickly, and a more complex geometry transformation
is required (see :meth:`cartopy.crs.Projection.project_geometry`).
"""
return_value = None
if self == src_crs:
x = vertices[:, 0]
y = vertices[:, 1]
x_limits = self.x_limits
y_limits = self.y_limits
if (x.min() >= x_limits[0] and x.max() <= x_limits[1] and
y.min() >= y_limits[0] and y.max() <= y_limits[1]):
return_value = vertices
return return_value
class _RectangularProjection(Projection):
"""
The abstract superclass of projections with a rectangular domain which
is symmetric about the origin.
"""
def __init__(self, proj4_params, half_width, half_height, globe=None):
self._half_width = half_width
self._half_height = half_height
super(_RectangularProjection, self).__init__(proj4_params, globe=globe)
@property
def boundary(self):
# XXX Should this be a LinearRing?
w, h = self._half_width, self._half_height
return sgeom.LineString([(-w, -h), (-w, h), (w, h), (w, -h), (-w, -h)])
@property
def x_limits(self):
return (-self._half_width, self._half_width)
@property
def y_limits(self):
return (-self._half_height, self._half_height)
class _CylindricalProjection(_RectangularProjection):
"""
The abstract class which denotes cylindrical projections where we
want to allow x values to wrap around.
"""
def _ellipse_boundary(semimajor=2, semiminor=1, easting=0, northing=0, n=201):
"""
Defines a projection boundary using an ellipse.
This type of boundary is used by several projections.
"""
t = np.linspace(0, 2 * np.pi, n)
coords = np.vstack([semimajor * np.cos(t), semiminor * np.sin(t)])
coords += ([easting], [northing])
return coords[:, ::-1]
class PlateCarree(_CylindricalProjection):
def __init__(self, central_longitude=0.0, globe=None):
proj4_params = [('proj', 'eqc'), ('lon_0', central_longitude)]
if globe is None:
globe = Globe(semimajor_axis=math.degrees(1))
a_rad = math.radians(globe.semimajor_axis or WGS84_SEMIMAJOR_AXIS)
x_max = a_rad * 180
y_max = a_rad * 90
# Set the threshold around 0.5 if the x max is 180.
self._threshold = x_max / 360.
super(PlateCarree, self).__init__(proj4_params, x_max, y_max,
globe=globe)
@property
def threshold(self):
return self._threshold
def _bbox_and_offset(self, other_plate_carree):
"""
Returns a pair of (xmin, xmax) pairs and an offset which can be used
for identification of whether data in ``other_plate_carree`` needs
to be transformed to wrap appropriately.
>>> import cartopy.crs as ccrs
>>> src = ccrs.PlateCarree(central_longitude=10)
>>> bboxes, offset = ccrs.PlateCarree()._bbox_and_offset(src)
>>> print(bboxes)
[[-180.0, -170.0], [-170.0, 180.0]]
>>> print(offset)
10.0
The returned values are longitudes in ``other_plate_carree``'s
coordinate system.
.. important::
The two CRSs must be identical in every way, other than their
central longitudes. No checking of this is done.
"""
self_lon_0 = self.proj4_params['lon_0']
other_lon_0 = other_plate_carree.proj4_params['lon_0']
lon_0_offset = other_lon_0 - self_lon_0
lon_lower_bound_0 = self.x_limits[0]
lon_lower_bound_1 = (other_plate_carree.x_limits[0] + lon_0_offset)
if lon_lower_bound_1 < self.x_limits[0]:
lon_lower_bound_1 += np.diff(self.x_limits)[0]
lon_lower_bound_0, lon_lower_bound_1 = sorted(
[lon_lower_bound_0, lon_lower_bound_1])
bbox = [[lon_lower_bound_0, lon_lower_bound_1],
[lon_lower_bound_1, lon_lower_bound_0]]
bbox[1][1] += np.diff(self.x_limits)[0]
return bbox, lon_0_offset
def quick_vertices_transform(self, vertices, src_crs):
return_value = super(PlateCarree,
self).quick_vertices_transform(vertices, src_crs)
# Optimise the PlateCarree -> PlateCarree case where no
# wrapping or interpolation needs to take place.
if return_value is None and isinstance(src_crs, PlateCarree):
self_params = self.proj4_params.copy()
src_params = src_crs.proj4_params.copy()
self_params.pop('lon_0'), src_params.pop('lon_0')
xs, ys = vertices[:, 0], vertices[:, 1]
potential = (self_params == src_params and
self.y_limits[0] <= ys.min() and
self.y_limits[1] >= ys.max())
if potential:
mod = np.diff(src_crs.x_limits)[0]
bboxes, proj_offset = self._bbox_and_offset(src_crs)
x_lim = xs.min(), xs.max()
y_lim = ys.min(), ys.max()
for poly in bboxes:
# Arbitrarily choose the number of moduli to look
# above and below the -180->180 range. If data is beyond
# this range, we're not going to transform it quickly.
for i in [-1, 0, 1, 2]:
offset = mod * i - proj_offset
if ((poly[0] + offset) <= x_lim[0] and
(poly[1] + offset) >= x_lim[1]):
return_value = vertices + [[-offset, 0]]
break
if return_value is not None:
break
return return_value
class TransverseMercator(Projection):
"""
A Transverse Mercator projection.
"""
def __init__(self, central_longitude=0.0, central_latitude=0.0,
false_easting=0.0, false_northing=0.0,
scale_factor=1.0, globe=None):
"""
Kwargs:
* central_longitude - The true longitude of the central meridian in
degrees. Defaults to 0.
* central_latitude - The true latitude of the planar origin in
degrees. Defaults to 0.
* false_easting - X offset from the planar origin in metres.
Defaults to 0.
* false_northing - Y offset from the planar origin in metres.
Defaults to 0.
* scale_factor - Scale factor at the central meridian. Defaults
to 1.
* globe - An instance of :class:`cartopy.crs.Globe`. If omitted, a
default globe is created.
"""
proj4_params = [('proj', 'tmerc'), ('lon_0', central_longitude),
('lat_0', central_latitude), ('k', scale_factor),
('x_0', false_easting), ('y_0', false_northing),
('units', 'm')]
super(TransverseMercator, self).__init__(proj4_params, globe=globe)
@property
def threshold(self):
return 1e4
@property
def boundary(self):
x0, x1 = self.x_limits
y0, y1 = self.y_limits
return sgeom.LineString([(x0, y0), (x0, y1),
(x1, y1), (x1, y0),
(x0, y0)])
@property
def x_limits(self):
return (-2e7, 2e7)
@property
def y_limits(self):
return (-1e7, 1e7)
class OSGB(TransverseMercator):
def __init__(self):
super(OSGB, self).__init__(central_longitude=-2, central_latitude=49,
scale_factor=0.9996012717,
false_easting=400000,
false_northing=-100000,
globe=Globe(datum='OSGB36', ellipse='airy'))
@property
def boundary(self):
w = self.x_limits[1] - self.x_limits[0]
h = self.y_limits[1] - self.y_limits[0]
return sgeom.LineString([(0, 0), (0, h), (w, h), (w, 0), (0, 0)])
@property
def x_limits(self):
return (0, 7e5)
@property
def y_limits(self):
return (0, 13e5)
class OSNI(TransverseMercator):
def __init__(self):
globe = Globe(semimajor_axis=6377340.189,
semiminor_axis=6356034.447938534)
super(OSNI, self).__init__(central_longitude=-8,
central_latitude=53.5,
scale_factor=1.000035,
false_easting=200000,
false_northing=250000,
globe=globe)
@property
def boundary(self):
w = self.x_limits[1] - self.x_limits[0]
h = self.y_limits[1] - self.y_limits[0]
return sgeom.LineString([(0, 0), (0, h), (w, h), (w, 0), (0, 0)])
@property
def x_limits(self):
return (18814.9667, 386062.3293)
@property
def y_limits(self):
return (11764.8481, 464720.9559)
class UTM(Projection):
"""
Universal Transverse Mercator projection.
"""
def __init__(self, zone, southern_hemisphere=False, globe=None):
"""
Kwargs:
* zone - the numeric zone of the UTM required.
* globe - An instance of :class:`cartopy.crs.Globe`. If omitted, a
default globe is created.
* southern_hemisphere - set to True if the zone is in the southern
hemisphere, defaults to False.
"""
proj4_params = [('proj', 'utm'),
('units', 'm'),
('zone', zone)]
if southern_hemisphere:
proj4_params.append(('south', None))
super(UTM, self).__init__(proj4_params, globe=globe)
@property
def boundary(self):
x0, x1 = self.x_limits
y0, y1 = self.y_limits
return sgeom.LineString([(x0, y0), (x0, y1),
(x1, y1), (x1, y0),
(x0, y0)])
@property
def threshold(self):
return 1e2
@property
def x_limits(self):
easting = 5e5
# allow 50% overflow
return (0 - easting/2, 2 * easting + easting/2)
@property
def y_limits(self):
northing = 1e7
# allow 50% overflow
return (0 - northing, 2 * northing + northing/2)
class EuroPP(UTM):
"""
UTM Zone 32 projection for EuroPP domain.
Ellipsoid is International 1924, Datum is ED50.
"""
def __init__(self):
globe = Globe(ellipse='intl')
super(EuroPP, self).__init__(32, globe=globe)
@property
def x_limits(self):
return (-1.4e6, 2e6)
@property
def y_limits(self):
return (4e6, 7.9e6)
class Mercator(Projection):
"""
A Mercator projection.
"""
def __init__(self, central_longitude=0.0,
min_latitude=-80.0, max_latitude=84.0,
globe=None):
"""
Kwargs:
* central_longitude - the central longitude. Defaults to 0.
* min_latitude - the maximum southerly extent of the projection.
Defaults to -80 degrees.
* max_latitude - the maximum northerly extent of the projection.
Defaults to 84 degrees.
* globe - A :class:`cartopy.crs.Globe`.
If omitted, a default globe is created.
"""
proj4_params = [('proj', 'merc'),
('lon_0', central_longitude),
('k', 1),
('units', 'm')]
super(Mercator, self).__init__(proj4_params, globe=globe)
# Calculate limits.
limits = self.transform_points(Geodetic(),
np.array([-180,
180]) + central_longitude,
np.array([min_latitude, max_latitude]))
self._xlimits = tuple(limits[..., 0])
self._ylimits = tuple(limits[..., 1])
self._threshold = np.diff(self.x_limits)[0] / 720
def __eq__(self, other):
res = super(Mercator, self).__eq__(other)
if hasattr(other, "_ylimits") and hasattr(other, "_xlimits"):
res = res and self._ylimits == other._ylimits and \
self._xlimits == other._xlimits
return res
def __ne__(self, other):
return not self == other
def __hash__(self):
return hash((self.proj4_init, self._xlimits, self._ylimits))
@property
def threshold(self):
return self._threshold
@property
def boundary(self):
x0, x1 = self.x_limits
y0, y1 = self.y_limits
return sgeom.LineString([(x0, y0), (x0, y1),
(x1, y1), (x1, y0),
(x0, y0)])
@property
def x_limits(self):
return self._xlimits
@property
def y_limits(self):
return self._ylimits
# Define a specific instance of a Mercator projection, the Google mercator.
Mercator.GOOGLE = Mercator(min_latitude=-85.0511287798066,
max_latitude=85.0511287798066,
globe=Globe(ellipse=None,
semimajor_axis=WGS84_SEMIMAJOR_AXIS,
semiminor_axis=WGS84_SEMIMAJOR_AXIS,
nadgrids='@null'))
# Deprecated form
GOOGLE_MERCATOR = Mercator.GOOGLE
class LambertCylindrical(_RectangularProjection):
def __init__(self, central_longitude=0.0):
proj4_params = [('proj', 'cea'), ('lon_0', central_longitude)]
globe = Globe(semimajor_axis=math.degrees(1))
super(LambertCylindrical, self).__init__(proj4_params, 180,
math.degrees(1), globe=globe)
@property
def threshold(self):
return 0.5
class LambertConformal(Projection):
"""
A Lambert Conformal conic projection.
"""
def __init__(self, central_longitude=-96.0, central_latitude=39.0,
false_easting=0.0, false_northing=0.0,
secant_latitudes=None, standard_parallels=None,
globe=None, cutoff=-30):
"""
Kwargs:
* central_longitude - The central longitude. Defaults to -96.
* central_latitude - The central latitude. Defaults to 39.
* false_easting - X offset from planar origin in metres.
Defaults to 0.
* false_northing - Y offset from planar origin in metres.
Defaults to 0.
* standard_parallels - Standard parallel latitude(s).
Defaults to (33, 45).
* globe - A :class:`cartopy.crs.Globe`.
If omitted, a default globe is created.
* cutoff - Latitude of map cutoff.
The map extends to infinity opposite the central pole
so we must cut off the map drawing before then.
A value of 0 will draw half the globe. Defaults to -30.
"""
proj4_params = [('proj', 'lcc'),
('lon_0', central_longitude),
('lat_0', central_latitude),
('x_0', false_easting),
('y_0', false_northing)]
if secant_latitudes and standard_parallels:
raise TypeError('standard_parallels replaces secant_latitudes.')
elif secant_latitudes is not None:
warnings.warn('secant_latitudes has been deprecated in v0.12. '
'The standard_parallels keyword can be used as a '
'direct replacement.')
standard_parallels = secant_latitudes
elif standard_parallels is None:
# The default. Put this as a keyword arg default once
# secant_latitudes is removed completely.
standard_parallels = (33, 45)
n_parallels = len(standard_parallels)
if not 1 <= n_parallels <= 2:
raise ValueError('1 or 2 standard parallels must be specified. '
'Got {} ({})'.format(n_parallels,
standard_parallels))
proj4_params.append(('lat_1', standard_parallels[0]))
if n_parallels == 2:
proj4_params.append(('lat_2', standard_parallels[1]))
super(LambertConformal, self).__init__(proj4_params, globe=globe)
# Compute whether this projection is at the "north pole" or the
# "south pole" (after the central lon/lat have been taken into
# account).
if n_parallels == 1:
plat = 90 if standard_parallels[0] > 0 else -90
else:
# Which pole are the parallels closest to? That is the direction
# that the cone converges.
if abs(standard_parallels[0]) > abs(standard_parallels[1]):
poliest_sec = standard_parallels[0]
else:
poliest_sec = standard_parallels[1]
plat = 90 if poliest_sec > 0 else -90
self.cutoff = cutoff
n = 91
lons = [0]
lats = [plat]
lons.extend(np.linspace(central_longitude - 180 + 0.001,
central_longitude + 180 - 0.001, n))
lats.extend(np.array([cutoff] * n))
lons.append(0)
lats.append(plat)
points = self.transform_points(PlateCarree(),
np.array(lons), np.array(lats))
if plat == 90:
# Ensure clockwise
points = points[::-1, :]
self._boundary = sgeom.LineString(points)
bounds = self._boundary.bounds
self._x_limits = bounds[0], bounds[2]
self._y_limits = bounds[1], bounds[3]
def __eq__(self, other):
res = super(LambertConformal, self).__eq__(other)
if hasattr(other, "cutoff"):
res = res and self.cutoff == other.cutoff
return res
def __ne__(self, other):
return not self == other
def __hash__(self):
return hash((self.proj4_init, self.cutoff))
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return 1e5
@property
def x_limits(self):
return self._x_limits
@property
def y_limits(self):
return self._y_limits
class LambertAzimuthalEqualArea(Projection):
"""
A Lambert Azimuthal Equal-Area projection.
"""
def __init__(self, central_longitude=0.0, central_latitude=0.0,
false_easting=0.0, false_northing=0.0,
globe=None):
"""
Kwargs:
* central_longitude - The central longitude. Defaults to 0.
* central_latitude - The central latitude. Defaults to 0.
* false_easting - X offset from planar origin in metres.
Defaults to 0.
* false_northing - Y offset from planar origin in metres.
Defaults to 0.
* globe - A :class:`cartopy.crs.Globe`.
If omitted, a default globe is created.
"""
proj4_params = [('proj', 'laea'),
('lon_0', central_longitude),
('lat_0', central_latitude),
('x_0', false_easting),
('y_0', false_northing)]
super(LambertAzimuthalEqualArea, self).__init__(proj4_params,
globe=globe)
a = np.float(self.globe.semimajor_axis or WGS84_SEMIMAJOR_AXIS)
b = np.float(self.globe.semiminor_axis or WGS84_SEMIMINOR_AXIS)
lon, lat = central_longitude + 180, - central_latitude + 0.01
x, max_y = self.transform_point(lon, lat, PlateCarree())
coords = _ellipse_boundary(a * 1.9999, max_y - false_northing,
false_easting, false_northing, 61)
self._boundary = sgeom.polygon.LinearRing(coords.T)
self._x_limits = self._boundary.bounds[::2]
self._y_limits = self._boundary.bounds[1::2]
self._threshold = np.diff(self._x_limits)[0] * 1e-3
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return self._threshold
@property
def x_limits(self):
return self._x_limits
@property
def y_limits(self):
return self._y_limits
class Miller(_RectangularProjection):
def __init__(self, central_longitude=0.0):
proj4_params = [('proj', 'mill'), ('lon_0', central_longitude)]
globe = Globe(semimajor_axis=math.degrees(1))
# XXX How can we derive the vertical limit of 131.98?
super(Miller, self).__init__(proj4_params, 180, 131.98, globe=globe)
@property
def threshold(self):
return 0.5
class RotatedPole(_CylindricalProjection):
"""
Defines a rotated latitude/longitude projected coordinate system
with cylindrical topology and projected distance.
Coordinates are measured in projection metres.
"""
def __init__(self, pole_longitude=0.0, pole_latitude=90.0,
central_rotated_longitude=0.0, globe=None):
"""
Create a RotatedPole CRS.
The class uses proj4 to perform an ob_tran operation, using the
pole_longitude to set a lon_0 then performing two rotations based on
pole_latitude and central_rotated_longitude.
This is equivalent to setting the new pole to a location defined by
the pole_latitude and pole_longitude values in the GeogCRS defined by
globe, then rotating this new CRS about it's pole using the
central_rotated_longitude value.
Args:
* pole_longitude - Pole longitude position, in unrotated degrees.
* pole_latitude - Pole latitude position, in unrotated degrees.
* central_rotated_longitude - Longitude rotation about the new
pole, in degrees.
Kwargs:
* globe - An optional :class:`cartopy.crs.Globe`.
Defaults to a "WGS84" datum.
"""
proj4_params = [('proj', 'ob_tran'), ('o_proj', 'latlon'),
('o_lon_p', central_rotated_longitude),
('o_lat_p', pole_latitude),
('lon_0', 180 + pole_longitude),
('to_meter', math.radians(1))]
super(RotatedPole, self).__init__(proj4_params, 180, 90, globe=globe)
@property
def threshold(self):
return 0.5
class Gnomonic(Projection):
def __init__(self, central_latitude=0.0, globe=None):
proj4_params = [('proj', 'gnom'), ('lat_0', central_latitude)]
super(Gnomonic, self).__init__(proj4_params, globe=globe)
self._max = 5e7
@property
def boundary(self):
return sgeom.Point(0, 0).buffer(self._max).exterior
@property
def threshold(self):
return 1e5
@property
def x_limits(self):
return (-self._max, self._max)
@property
def y_limits(self):
return (-self._max, self._max)
class Stereographic(Projection):
def __init__(self, central_latitude=0.0, central_longitude=0.0,
false_easting=0.0, false_northing=0.0,
true_scale_latitude=None, globe=None):
proj4_params = [('proj', 'stere'), ('lat_0', central_latitude),
('lon_0', central_longitude),
('x_0', false_easting), ('y_0', false_northing)]
if true_scale_latitude:
proj4_params.append(('lat_ts', true_scale_latitude))
super(Stereographic, self).__init__(proj4_params, globe=globe)
# TODO: Let the globe return the semimajor axis always.
a = np.float(self.globe.semimajor_axis or WGS84_SEMIMAJOR_AXIS)
b = np.float(self.globe.semiminor_axis or WGS84_SEMIMINOR_AXIS)
# Note: The magic number has been picked to maintain consistent
# behaviour with a wgs84 globe. There is no guarantee that the scaling
# should even be linear.
x_axis_offset = 5e7 / WGS84_SEMIMAJOR_AXIS
y_axis_offset = 5e7 / WGS84_SEMIMINOR_AXIS
self._x_limits = (-a * x_axis_offset + false_easting,
a * x_axis_offset + false_easting)
self._y_limits = (-b * y_axis_offset + false_northing,
b * y_axis_offset + false_northing)
if self._x_limits[1] == self._y_limits[1]:
point = sgeom.Point(false_easting, false_northing)
self._boundary = point.buffer(self._x_limits[1]).exterior
else:
coords = _ellipse_boundary(self._x_limits[1], self._y_limits[1],
false_easting, false_northing, 91)
self._boundary = sgeom.LinearRing(coords.T)
self._threshold = np.diff(self._x_limits)[0] * 1e-3
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return self._threshold
@property
def x_limits(self):
return self._x_limits
@property
def y_limits(self):
return self._y_limits
class NorthPolarStereo(Stereographic):
def __init__(self, central_longitude=0.0, globe=None):
super(NorthPolarStereo, self).__init__(
central_latitude=90,
central_longitude=central_longitude, globe=globe)
class SouthPolarStereo(Stereographic):
def __init__(self, central_longitude=0.0, globe=None):
super(SouthPolarStereo, self).__init__(
central_latitude=-90,
central_longitude=central_longitude, globe=globe)
class Orthographic(Projection):
def __init__(self, central_longitude=0.0, central_latitude=0.0,
globe=None):
proj4_params = [('proj', 'ortho'), ('lon_0', central_longitude),
('lat_0', central_latitude)]
super(Orthographic, self).__init__(proj4_params, globe=globe)
# TODO: Let the globe return the semimajor axis always.
a = np.float(self.globe.semimajor_axis or WGS84_SEMIMAJOR_AXIS)
b = np.float(self.globe.semiminor_axis or a)
if b != a:
warnings.warn('The proj4 "ortho" projection does not appear to '
'handle elliptical globes.')
# To stabilise the projection of geometries, we reduce the boundary by
# a tiny fraction at the cost of the extreme edges.
coords = _ellipse_boundary(a * 0.99999, b * 0.99999, n=61)
self._boundary = sgeom.polygon.LinearRing(coords.T)
self._xlim = self._boundary.bounds[::2]
self._ylim = self._boundary.bounds[1::2]
self._threshold = np.diff(self._xlim)[0] * 0.02
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return self._threshold
@property
def x_limits(self):
return self._xlim
@property
def y_limits(self):
return self._ylim
class _WarpedRectangularProjection(Projection):
def __init__(self, proj4_params, central_longitude, globe=None):
super(_WarpedRectangularProjection, self).__init__(proj4_params,
globe=globe)
# Obtain boundary points
points = []
n = 91
geodetic_crs = self.as_geodetic()
for lat in np.linspace(-90, 90, n):
points.append(
self.transform_point(180 + central_longitude,
lat, geodetic_crs)
)
for lat in np.linspace(90, -90, n):
points.append(
self.transform_point(-180 + central_longitude,
lat, geodetic_crs)
)
points.append(
self.transform_point(180 + central_longitude, -90, geodetic_crs))
self._boundary = sgeom.LineString(points[::-1])
x = [p[0] for p in points]
y = [p[1] for p in points]
self._x_limits = min(x), max(x)
self._y_limits = min(y), max(y)
@property
def boundary(self):
return self._boundary
@property
def x_limits(self):
return self._x_limits
@property
def y_limits(self):
return self._y_limits
class Mollweide(_WarpedRectangularProjection):
def __init__(self, central_longitude=0, globe=None):
proj4_params = [('proj', 'moll'), ('lon_0', central_longitude)]
super(Mollweide, self).__init__(proj4_params, central_longitude,
globe=globe)
@property
def threshold(self):
return 1e5
class Robinson(_WarpedRectangularProjection):
def __init__(self, central_longitude=0, globe=None):
# Warn when using Robinson with proj4 4.8 due to discontinuity at
# 40 deg N introduced by incomplete fix to issue #113 (see
# https://trac.osgeo.org/proj/ticket/113).
import re
if PROJ4_VERSION != ():
if (4, 8) <= PROJ4_VERSION < (4, 9):
warnings.warn('The Robinson projection in the v4.8.x series '
'of Proj.4 contains a discontinuity at '
'40 deg latitude. Use this projection with '
'caution.')
else:
warnings.warn('Cannot determine Proj.4 version. The Robinson '
'projection may be unreliable and should be used '
'with caution.')
proj4_params = [('proj', 'robin'), ('lon_0', central_longitude)]
super(Robinson, self).__init__(proj4_params, central_longitude,
globe=globe)
@property
def threshold(self):
return 1e4
def transform_point(self, x, y, src_crs):
"""
Capture and handle any input NaNs, else invoke parent function,
:meth:`_WarpedRectangularProjection.transform_point`.
Needed because input NaNs can trigger a fatal error in the underlying
implementation of the Robinson projection.
.. note::
Although the original can in fact translate (nan, lat) into
(nan, y-value), this patched version doesn't support that.
"""
if np.isnan(x) or np.isnan(y):
result = (np.nan, np.nan)
else:
result = super(Robinson, self).transform_point(x, y, src_crs)
return result
def transform_points(self, src_crs, x, y, z=None):
"""
Capture and handle NaNs in input points -- else as parent function,
:meth:`_WarpedRectangularProjection.transform_points`.
Needed because input NaNs can trigger a fatal error in the underlying
implementation of the Robinson projection.
.. note::
Although the original can in fact translate (nan, lat) into
(nan, y-value), this patched version doesn't support that.
Instead, we invalidate any of the points that contain a NaN.
"""
input_point_nans = np.isnan(x) | np.isnan(y)
if z is not None:
input_point_nans |= np.isnan(z)
handle_nans = np.any(input_point_nans)
if handle_nans:
# Remove NaN points from input data to avoid the error.
x[input_point_nans] = 0.0
y[input_point_nans] = 0.0
if z is not None:
z[input_point_nans] = 0.0
result = super(Robinson, self).transform_points(src_crs, x, y, z)
if handle_nans:
# Result always has shape (N, 3).
# Blank out each (whole) point where we had a NaN in the input.
result[input_point_nans] = np.nan
return result
class InterruptedGoodeHomolosine(Projection):
def __init__(self, central_longitude=0, globe=None):
proj4_params = [('proj', 'igh'), ('lon_0', central_longitude)]
super(InterruptedGoodeHomolosine, self).__init__(proj4_params,
globe=globe)
# Obtain boundary points
points = []
n = 31
geodetic_crs = self.as_geodetic()
# Right boundary
for lat in np.linspace(-90, 90, n):
points.append(self.transform_point(180 + central_longitude,
lat, geodetic_crs))
# Top boundary
interrupted_lons = (-40.0,)
delta = 0.001
for lon in interrupted_lons:
for lat in np.linspace(90, 0, n):
points.append(self.transform_point(lon + delta +
central_longitude,
lat, geodetic_crs))
for lat in np.linspace(0, 90, n):
points.append(self.transform_point(lon - delta +
central_longitude,
lat, geodetic_crs))
# Left boundary
for lat in np.linspace(90, -90, n):
points.append(self.transform_point(-180 + central_longitude,
lat, geodetic_crs))
# Bottom boundary
interrupted_lons = (-100.0, -20.0, 80.0)
delta = 0.001
for lon in interrupted_lons:
for lat in np.linspace(-90, 0, n):
points.append(self.transform_point(lon - delta +
central_longitude,
lat, geodetic_crs))
for lat in np.linspace(0, -90, n):
points.append(self.transform_point(lon + delta +
central_longitude,
lat, geodetic_crs))
# Close loop
points.append(self.transform_point(180 + central_longitude, -90,
geodetic_crs))
self._boundary = sgeom.LineString(points[::-1])
x = [p[0] for p in points]
y = [p[1] for p in points]
self._x_limits = min(x), max(x)
self._y_limits = min(y), max(y)
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return 2e4
@property
def x_limits(self):
return self._x_limits
@property
def y_limits(self):
return self._y_limits
class Geostationary(Projection):
def __init__(self, central_longitude=0.0, satellite_height=35785831,
false_easting=0, false_northing=0, globe=None):
proj4_params = [('proj', 'geos'), ('lon_0', central_longitude),
('lat_0', 0), ('h', satellite_height),
('x_0', false_easting), ('y_0', false_northing),
('units', 'm')]
super(Geostationary, self).__init__(proj4_params, globe=globe)
# TODO: Let the globe return the semimajor axis always.
a = np.float(self.globe.semimajor_axis or WGS84_SEMIMAJOR_AXIS)
b = np.float(self.globe.semiminor_axis or a)
h = np.float(satellite_height)
max_x = h * math.atan(a / (a + h))
max_y = h * math.atan(b / (b + h))
coords = _ellipse_boundary(max_x, max_y,
false_easting, false_northing, 61)
self._boundary = sgeom.LinearRing(coords.T)
self._xlim = self._boundary.bounds[::2]
self._ylim = self._boundary.bounds[1::2]
self._threshold = np.diff(self._xlim)[0] * 0.02
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return self._threshold
@property
def x_limits(self):
return self._xlim
@property
def y_limits(self):
return self._ylim
class AlbersEqualArea(Projection):
"""
An Albers Equal Area projection
This projection is conic and equal-area, and is commonly used for maps of
the conterminous United States.
"""
def __init__(self, central_longitude=0.0, central_latitude=0.0,
false_easting=0.0, false_northing=0.0,
standard_parallels=(20.0, 50.0), globe=None):
"""
Kwargs:
* central_longitude - The central longitude. Defaults to 0.
* central_latitude - The central latitude. Defaults to 0.
* false_easting - X offset from planar origin in metres.
Defaults to 0.
* false_northing - Y offset from planar origin in metres.
Defaults to 0.
* standard_parallels - The one or two latitudes of correct scale.
Defaults to (20, 50).
* globe - A :class:`cartopy.crs.Globe`.
If omitted, a default globe is created.
"""
proj4_params = [('proj', 'aea'),
('lon_0', central_longitude),
('lat_0', central_latitude),
('x_0', false_easting),
('y_0', false_northing)]
if standard_parallels is not None:
try:
proj4_params.append(('lat_1', standard_parallels[0]))
try:
proj4_params.append(('lat_2', standard_parallels[1]))
except IndexError:
pass
except TypeError:
proj4_params.append(('lat_1', standard_parallels))
super(AlbersEqualArea, self).__init__(proj4_params, globe=globe)
# bounds
n = 103
lons = np.empty(2 * n + 1)
lats = np.empty(2 * n + 1)
tmp = np.linspace(central_longitude - 180, central_longitude + 180, n)
lons[:n] = tmp
lats[:n] = 90
lons[n:-1] = tmp[::-1]
lats[n:-1] = -90
lons[-1] = lons[0]
lats[-1] = lats[0]
points = self.transform_points(self.as_geodetic(), lons, lats)
self._boundary = sgeom.LineString(points)
bounds = self._boundary.bounds
self._x_limits = bounds[0], bounds[2]
self._y_limits = bounds[1], bounds[3]
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return 1e5
@property
def x_limits(self):
return self._x_limits
@property
def y_limits(self):
return self._y_limits
class AzimuthalEquidistant(Projection):
"""
An Azimuthal Equidistant projection
This projection provides accurate angles about and distances through the
central position. Other angles, distances, or areas may be distorted.
"""
def __init__(self, central_longitude=0.0, central_latitude=0.0,
false_easting=0.0, false_northing=0.0,
globe=None):
"""
Kwargs:
* central_longitude - The true longitude of the central meridian in
degrees. Defaults to 0.
* central_latitude - The true latitude of the planar origin in
degrees. Defaults to 0.
* false_easting - X offset from the planar origin in metres.
Defaults to 0.
* false_northing - Y offset from the planar origin in metres.
Defaults to 0.
* globe - An instance of :class:`cartopy.crs.Globe`. If omitted, a
default globe is created.
"""
# Warn when using Azimuthal Equidistant with proj4 < 4.9.2 due to
# incorrect transformation past 90 deg distance (see
# https://github.com/OSGeo/proj.4/issues/246).
if PROJ4_VERSION != ():
if PROJ4_VERSION < (4, 9, 2):
warnings.warn('The Azimuthal Equidistant projection in Proj.4 '
'older than 4.9.2 incorrectly transforms points '
'farther than 90 deg from the origin. Use this '
'projection with caution.')
else:
warnings.warn('Cannot determine Proj.4 version. The Azimuthal '
'Equidistant projection may be unreliable and '
'should be used with caution.')
proj4_params = [('proj', 'aeqd'), ('lon_0', central_longitude),
('lat_0', central_latitude),
('x_0', false_easting), ('y_0', false_northing)]
super(AzimuthalEquidistant, self).__init__(proj4_params, globe=globe)
# TODO: Let the globe return the semimajor axis always.
a = np.float(self.globe.semimajor_axis or WGS84_SEMIMAJOR_AXIS)
b = np.float(self.globe.semiminor_axis or a)
coords = _ellipse_boundary(a * np.pi, b * np.pi,
false_easting, false_northing, 61)
self._boundary = sgeom.LinearRing(coords.T)
bounds = self._boundary.bounds
self._x_limits = bounds[0], bounds[2]
self._y_limits = bounds[1], bounds[3]
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return 1e5
@property
def x_limits(self):
return self._x_limits
@property
def y_limits(self):
return self._y_limits
class Sinusoidal(Projection):
"""
A Sinusoidal projection.
This projection is equal-area.
"""
def __init__(self, central_longitude=0.0, false_easting=0.0,
false_northing=0.0, globe=None):
"""
Kwargs:
* central_longitude - The central longitude. Defaults to 0.
* false_easting - X offset from planar origin in metres.
Defaults to 0.
* false_northing - Y offset from planar origin in metres.
Defaults to 0.
* globe - A :class:`cartopy.crs.Globe`.
If omitted, a default globe is created.
"""
proj4_params = [('proj', 'sinu'),
('lon_0', central_longitude),
('x_0', false_easting),
('y_0', false_northing)]
super(Sinusoidal, self).__init__(proj4_params, globe=globe)
# Obtain boundary points
points = []
n = 91
geodetic_crs = self.as_geodetic()
for lat in np.linspace(-90, 90, n):
points.append(
self.transform_point(180 + central_longitude,
lat, geodetic_crs)
)
for lat in np.linspace(90, -90, n):
points.append(
self.transform_point(-180 + central_longitude,
lat, geodetic_crs)
)
points.append(
self.transform_point(180 + central_longitude, -90, geodetic_crs))
self._boundary = sgeom.LineString(points[::-1])
minx, miny, maxx, maxy = self._boundary.bounds
self._x_limits = minx, maxx
self._y_limits = miny, maxy
self._threshold = max(np.abs(self.x_limits + self.y_limits)) * 1e-5
@property
def boundary(self):
return self._boundary
@property
def threshold(self):
return self._threshold
@property
def x_limits(self):
return self._x_limits
@property
def y_limits(self):
return self._y_limits
# MODIS data products use a Sinusoidal projection of a spherical Earth
# http://modis-land.gsfc.nasa.gov/GCTP.html
Sinusoidal.MODIS = Sinusoidal(globe=Globe(ellipse=None,
semimajor_axis=6371007.181,
semiminor_axis=6371007.181))
class _BoundaryPoint(object):
def __init__(self, distance, kind, data):
"""
A representation for a geometric object which is
connected to the boundary.
Parameters
==========
distance - float
The distance along the boundary that this object
can be found.
kind - bool
Whether this object represents a point from the pre-computed
boundary.
data - point or namedtuple
The actual data that this boundary object represents.
"""
self.distance = distance
self.kind = kind
self.data = data
def __repr__(self):
return '_BoundaryPoint(%r, %r, %s)' % (self.distance, self.kind,
self.data)
def _find_first_gt(a, x):
for v in a:
if v.distance > x:
return v
# We've gone all the way around, so pick the first point again.
return a[0]
def epsg(code):
"""
Return the projection which corresponds to the given EPSG code.
The EPSG code must correspond to a "projected coordinate system",
so EPSG codes such as 4326 (WGS-84) which define a "geodetic coordinate
system" will not work.
.. note::
The conversion is performed by querying https://epsg.io/ so a
live internet connection is required.
"""
import cartopy._epsg
return cartopy._epsg._EPSGProjection(code)
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