# Licensed under a 3-clause BSD style license - see LICENSE.rst
import numpy as np
from matplotlib.patches import Polygon
from astropy import units as u
from astropy.coordinates.representation import UnitSphericalRepresentation
from astropy.coordinates.matrix_utilities import rotation_matrix, matrix_product
__all__ = ['Quadrangle', 'SphericalCircle']
# Monkey-patch the docs to fix CapStyle and JoinStyle subs.
# TODO! delete when upstream fix matplotlib/matplotlib#19839
Polygon.__init__.__doc__ = Polygon.__init__.__doc__.replace(
"`.CapStyle`", "``matplotlib._enums.CapStyle``")
Polygon.__init__.__doc__ = Polygon.__init__.__doc__.replace(
"`.JoinStyle`", "``matplotlib._enums.JoinStyle``")
Polygon.set_capstyle.__doc__ = Polygon.set_capstyle.__doc__.replace(
"`.CapStyle`", "``matplotlib._enums.CapStyle``")
Polygon.set_joinstyle.__doc__ = Polygon.set_joinstyle.__doc__.replace(
"`.JoinStyle`", "``matplotlib._enums.JoinStyle``")
def _rotate_polygon(lon, lat, lon0, lat0):
"""
Given a polygon with vertices defined by (lon, lat), rotate the polygon
such that the North pole of the spherical coordinates is now at (lon0,
lat0). Therefore, to end up with a polygon centered on (lon0, lat0), the
polygon should initially be drawn around the North pole.
"""
# Create a representation object
polygon = UnitSphericalRepresentation(lon=lon, lat=lat)
# Determine rotation matrix to make it so that the circle is centered
# on the correct longitude/latitude.
m1 = rotation_matrix(-(0.5 * np.pi * u.radian - lat0), axis='y')
m2 = rotation_matrix(-lon0, axis='z')
transform_matrix = matrix_product(m2, m1)
# Apply 3D rotation
polygon = polygon.to_cartesian()
polygon = polygon.transform(transform_matrix)
polygon = UnitSphericalRepresentation.from_cartesian(polygon)
return polygon.lon, polygon.lat
[ドキュメント]class SphericalCircle(Polygon):
"""
Create a patch representing a spherical circle - that is, a circle that is
formed of all the points that are within a certain angle of the central
coordinates on a sphere. Here we assume that latitude goes from -90 to +90
This class is needed in cases where the user wants to add a circular patch
to a celestial image, since otherwise the circle will be distorted, because
a fixed interval in longitude corresponds to a different angle on the sky
depending on the latitude.
Parameters
----------
center : tuple or `~astropy.units.Quantity` ['angle']
This can be either a tuple of two `~astropy.units.Quantity` objects, or
a single `~astropy.units.Quantity` array with two elements.
radius : `~astropy.units.Quantity` ['angle']
The radius of the circle
resolution : int, optional
The number of points that make up the circle - increase this to get a
smoother circle.
vertex_unit : `~astropy.units.Unit`
The units in which the resulting polygon should be defined - this
should match the unit that the transformation (e.g. the WCS
transformation) expects as input.
Notes
-----
Additional keyword arguments are passed to `~matplotlib.patches.Polygon`
"""
def __init__(self, center, radius, resolution=100, vertex_unit=u.degree, **kwargs):
# Extract longitude/latitude, either from a tuple of two quantities, or
# a single 2-element Quantity.
longitude, latitude = center
# Start off by generating the circle around the North pole
lon = np.linspace(0., 2 * np.pi, resolution + 1)[:-1] * u.radian
lat = np.repeat(0.5 * np.pi - radius.to_value(u.radian), resolution) * u.radian
lon, lat = _rotate_polygon(lon, lat, longitude, latitude)
# Extract new longitude/latitude in the requested units
lon = lon.to_value(vertex_unit)
lat = lat.to_value(vertex_unit)
# Create polygon vertices
vertices = np.array([lon, lat]).transpose()
super().__init__(vertices, **kwargs)
[ドキュメント]class Quadrangle(Polygon):
"""
Create a patch representing a latitude-longitude quadrangle.
The edges of the quadrangle lie on two lines of constant longitude and two
lines of constant latitude (or the equivalent component names in the
coordinate frame of interest, such as right ascension and declination).
Note that lines of constant latitude are not great circles.
Unlike `matplotlib.patches.Rectangle`, the edges of this patch will render
as curved lines if appropriate for the WCS transformation.
Parameters
----------
anchor : tuple or `~astropy.units.Quantity` ['angle']
This can be either a tuple of two `~astropy.units.Quantity` objects, or
a single `~astropy.units.Quantity` array with two elements.
width : `~astropy.units.Quantity` ['angle']
The width of the quadrangle in longitude (or, e.g., right ascension)
height : `~astropy.units.Quantity` ['angle']
The height of the quadrangle in latitude (or, e.g., declination)
resolution : int, optional
The number of points that make up each side of the quadrangle -
increase this to get a smoother quadrangle.
vertex_unit : `~astropy.units.Unit` ['angle']
The units in which the resulting polygon should be defined - this
should match the unit that the transformation (e.g. the WCS
transformation) expects as input.
Notes
-----
Additional keyword arguments are passed to `~matplotlib.patches.Polygon`
"""
def __init__(self, anchor, width, height, resolution=100, vertex_unit=u.degree, **kwargs):
# Extract longitude/latitude, either from a tuple of two quantities, or
# a single 2-element Quantity.
longitude, latitude = u.Quantity(anchor).to_value(vertex_unit)
# Convert the quadrangle dimensions to the appropriate units
width = width.to_value(vertex_unit)
height = height.to_value(vertex_unit)
# Create progressions in longitude and latitude
lon_seq = longitude + np.linspace(0, width, resolution + 1)
lat_seq = latitude + np.linspace(0, height, resolution + 1)
# Trace the path of the quadrangle
lon = np.concatenate([lon_seq[:-1],
np.repeat(lon_seq[-1], resolution),
np.flip(lon_seq[1:]),
np.repeat(lon_seq[0], resolution)])
lat = np.concatenate([np.repeat(lat_seq[0], resolution),
lat_seq[:-1],
np.repeat(lat_seq[-1], resolution),
np.flip(lat_seq[1:])])
# Create polygon vertices
vertices = np.array([lon, lat]).transpose()
super().__init__(vertices, **kwargs)