SkyCoord

class astropy.coordinates.SkyCoord(*args, copy=True, **kwargs)[source]

Bases: ShapedLikeNDArray

High-level object providing a flexible interface for celestial coordinate representation, manipulation, and transformation between systems.

The SkyCoord class accepts a wide variety of inputs for initialization. At a minimum these must provide one or more celestial coordinate values with unambiguous units. Inputs may be scalars or lists/tuples/arrays, yielding scalar or array coordinates (can be checked via SkyCoord.isscalar). Typically one also specifies the coordinate frame, though this is not required. The general pattern for spherical representations is:

SkyCoord(COORD, [FRAME], keyword_args ...)
SkyCoord(LON, LAT, [FRAME], keyword_args ...)
SkyCoord(LON, LAT, [DISTANCE], frame=FRAME, unit=UNIT, keyword_args ...)
SkyCoord([FRAME], <lon_attr>=LON, <lat_attr>=LAT, keyword_args ...)

It is also possible to input coordinate values in other representations such as cartesian or cylindrical. In this case one includes the keyword argument representation_type='cartesian' (for example) along with data in x, y, and z.

See also: https://docs.astropy.org/en/stable/coordinates/

Parameters:
frameBaseCoordinateFrame class or python:str, optional

Type of coordinate frame this SkyCoord should represent. Defaults to to ICRS if not given or given as None.

unitUnit, python:str, or python:tuple of Unit or python:str, optional

Units for supplied coordinate values. If only one unit is supplied then it applies to all values. Note that passing only one unit might lead to unit conversion errors if the coordinate values are expected to have mixed physical meanings (e.g., angles and distances).

obstimeastropy:time-like, optional

Time(s) of observation.

equinoxastropy:time-like, optional

Coordinate frame equinox time.

representation_typepython:str or BaseRepresentation class

Specifies the representation, e.g. ‘spherical’, ‘cartesian’, or ‘cylindrical’. This affects the positional args and other keyword args which must correspond to the given representation.

copybool, optional

If True (default), a copy of any coordinate data is made. This argument can only be passed in as a keyword argument.

**keyword_args

Other keyword arguments as applicable for user-defined coordinate frames. Common options include:

ra, decangle-like, optional

RA and Dec for frames where ra and dec are keys in the frame’s representation_component_names, including ICRS, FK5, FK4, and FK4NoETerms.

pm_ra_cosdec, pm_decQuantity [‘angular speed’], optional

Proper motion components, in angle per time units.

l, bangle-like, optional

Galactic l and b for for frames where l and b are keys in the frame’s representation_component_names, including the Galactic frame.

pm_l_cosb, pm_bQuantity [‘angular speed’], optional

Proper motion components in the Galactic frame, in angle per time units.

x, y, zfloat or Quantity [‘length’], optional

Cartesian coordinates values

u, v, wfloat or Quantity [‘length’], optional

Cartesian coordinates values for the Galactic frame.

radial_velocityQuantity [‘speed’], optional

The component of the velocity along the line-of-sight (i.e., the radial direction), in velocity units.

Examples

The examples below illustrate common ways of initializing a SkyCoord object. For a complete description of the allowed syntax see the full coordinates documentation. First some imports:

>>> from astropy.coordinates import SkyCoord  # High-level coordinates
>>> from astropy.coordinates import ICRS, Galactic, FK4, FK5  # Low-level frames
>>> from astropy.coordinates import Angle, Latitude, Longitude  # Angles
>>> import astropy.units as u

The coordinate values and frame specification can now be provided using positional and keyword arguments:

>>> c = SkyCoord(10, 20, unit="deg")  # defaults to ICRS frame
>>> c = SkyCoord([1, 2, 3], [-30, 45, 8], frame="icrs", unit="deg")  # 3 coords

>>> coords = ["1:12:43.2 +31:12:43", "1 12 43.2 +31 12 43"]
>>> c = SkyCoord(coords, frame=FK4, unit=(u.hourangle, u.deg), obstime="J1992.21")

>>> c = SkyCoord("1h12m43.2s +1d12m43s", frame=Galactic)  # Units from string
>>> c = SkyCoord(frame="galactic", l="1h12m43.2s", b="+1d12m43s")

>>> ra = Longitude([1, 2, 3], unit=u.deg)  # Could also use Angle
>>> dec = np.array([4.5, 5.2, 6.3]) * u.deg  # Astropy Quantity
>>> c = SkyCoord(ra, dec, frame='icrs')
>>> c = SkyCoord(frame=ICRS, ra=ra, dec=dec, obstime='2001-01-02T12:34:56')

>>> c = FK4(1 * u.deg, 2 * u.deg)  # Uses defaults for obstime, equinox
>>> c = SkyCoord(c, obstime='J2010.11', equinox='B1965')  # Override defaults

>>> c = SkyCoord(w=0, u=1, v=2, unit='kpc', frame='galactic',
...              representation_type='cartesian')

>>> c = SkyCoord([ICRS(ra=1*u.deg, dec=2*u.deg), ICRS(ra=3*u.deg, dec=4*u.deg)])

Velocity components (proper motions or radial velocities) can also be provided in a similar manner:

>>> c = SkyCoord(ra=1*u.deg, dec=2*u.deg, radial_velocity=10*u.km/u.s)

>>> c = SkyCoord(ra=1*u.deg, dec=2*u.deg, pm_ra_cosdec=2*u.mas/u.yr, pm_dec=1*u.mas/u.yr)

As shown, the frame can be a BaseCoordinateFrame class or the corresponding string alias – lower-case versions of the class name that allow for creating a SkyCoord object and transforming frames without explicitly importing the frame classes.

Attributes Summary

frame

info

Container for meta information like name, description, format.

representation

representation_type

shape

The shape of the underlying data.

Methods Summary

apply_space_motion([new_obstime, dt])

Compute the position of the source represented by this coordinate object to a new time using the velocities stored in this object and assuming linear space motion (including relativistic corrections).

contained_by(wcs[, image])

Determines if the SkyCoord is contained in the given wcs footprint.

directional_offset_by(position_angle, separation)

Computes coordinates at the given offset from this coordinate.

from_name(name[, frame, parse, cache])

Given a name, query the CDS name resolver to attempt to retrieve coordinate information for that object.

from_pixel(xp, yp, wcs[, origin, mode])

Create a new SkyCoord from pixel coordinates using a World Coordinate System.

get_constellation([short_name, ...])

Determines the constellation(s) of the coordinates this SkyCoord contains.

guess_from_table(table, **coord_kwargs)

A convenience method to create and return a new SkyCoord from the data in an astropy Table.

insert(obj, values[, axis])

Insert coordinate values before the given indices in the object and return a new Frame object.

is_equivalent_frame(other)

Checks if this object's frame as the same as that of the other object.

is_transformable_to(new_frame)

Determines if this coordinate frame can be transformed to another given frame.

match_to_catalog_3d(catalogcoord[, nthneighbor])

Finds the nearest 3-dimensional matches of this coordinate to a set of catalog coordinates.

match_to_catalog_sky(catalogcoord[, nthneighbor])

Finds the nearest on-sky matches of this coordinate in a set of catalog coordinates.

position_angle(other)

Computes the on-sky position angle (East of North) between this SkyCoord and another.

radial_velocity_correction([kind, obstime, ...])

Compute the correction required to convert a radial velocity at a given time and place on the Earth's Surface to a barycentric or heliocentric velocity.

search_around_3d(searcharoundcoords, distlimit)

Searches for all coordinates in this object around a supplied set of points within a given 3D radius.

search_around_sky(searcharoundcoords, seplimit)

Searches for all coordinates in this object around a supplied set of points within a given on-sky separation.

separation(other)

Computes on-sky separation between this coordinate and another.

separation_3d(other)

Computes three dimensional separation between this coordinate and another.

skyoffset_frame([rotation])

Returns the sky offset frame with this SkyCoord at the origin.

spherical_offsets_by(d_lon, d_lat)

Computes the coordinate that is a specified pair of angular offsets away from this coordinate.

spherical_offsets_to(tocoord)

Computes angular offsets to go from this coordinate to another.

to_pixel(wcs[, origin, mode])

Convert this coordinate to pixel coordinates using a WCS object.

to_string([style])

A string representation of the coordinates.

to_table()

Convert this SkyCoord to a QTable.

transform_to(frame[, merge_attributes])

Transform this coordinate to a new frame.

Attributes Documentation

frame
info

Container for meta information like name, description, format. This is required when the object is used as a mixin column within a table, but can be used as a general way to store meta information.

representation
representation_type
shape

Methods Documentation

apply_space_motion(new_obstime=None, dt=None)[source]

Compute the position of the source represented by this coordinate object to a new time using the velocities stored in this object and assuming linear space motion (including relativistic corrections). This is sometimes referred to as an “epoch transformation.”

The initial time before the evolution is taken from the obstime attribute of this coordinate. Note that this method currently does not support evolving coordinates where the frame has an obstime frame attribute, so the obstime is only used for storing the before and after times, not actually as an attribute of the frame. Alternatively, if dt is given, an obstime need not be provided at all.

Parameters:
new_obstimeTime, optional

The time at which to evolve the position to. Requires that the obstime attribute be present on this frame.

dtQuantity, TimeDelta, optional

An amount of time to evolve the position of the source. Cannot be given at the same time as new_obstime.

Returns:
new_coordSkyCoord

A new coordinate object with the evolved location of this coordinate at the new time. obstime will be set on this object to the new time only if self also has obstime.

contained_by(wcs, image=None, **kwargs)[source]

Determines if the SkyCoord is contained in the given wcs footprint.

Parameters:
wcsWCS

The coordinate to check if it is within the wcs coordinate.

imagearray

Optional. The image associated with the wcs object that the cooordinate is being checked against. If not given the naxis keywords will be used to determine if the coordinate falls within the wcs footprint.

**kwargs

Additional arguments to pass to to_pixel

Returns:
responsebool

True means the WCS footprint contains the coordinate, False means it does not.

directional_offset_by(position_angle, separation)[source]

Computes coordinates at the given offset from this coordinate.

Parameters:
position_angleAngle

position_angle of offset

separationAngle

offset angular separation

Returns:
newpointsSkyCoord

The coordinates for the location that corresponds to offsetting by the given position_angle and separation.

See also

position_angle

inverse operation for the position_angle component

separation

inverse operation for the separation component

Notes

Returned SkyCoord frame retains only the frame attributes that are for the resulting frame type. (e.g. if the input frame is ICRS, an equinox value will be retained, but an obstime will not.)

For a more complete set of transform offsets, use WCS. skyoffset_frame() can also be used to create a spherical frame with (lat=0, lon=0) at a reference point, approximating an xy cartesian system for small offsets. This method is distinct in that it is accurate on the sphere.

classmethod from_name(name, frame='icrs', parse=False, cache=True)[source]

Given a name, query the CDS name resolver to attempt to retrieve coordinate information for that object. The search database, sesame url, and query timeout can be set through configuration items in astropy.coordinates.name_resolve – see docstring for get_icrs_coordinates for more information.

Parameters:
namepython:str

The name of the object to get coordinates for, e.g. 'M42'.

framepython:str or BaseCoordinateFrame class or instance

The frame to transform the object to.

parsebool

Whether to attempt extracting the coordinates from the name by parsing with a regex. For objects catalog names that have J-coordinates embedded in their names, e.g., ‘CRTS SSS100805 J194428-420209’, this may be much faster than a Sesame query for the same object name. The coordinates extracted in this way may differ from the database coordinates by a few deci-arcseconds, so only use this option if you do not need sub-arcsecond accuracy for coordinates.

cachebool, optional

Determines whether to cache the results or not. To update or overwrite an existing value, pass cache='update'.

Returns:
coordSkyCoord

Instance of the SkyCoord class.

classmethod from_pixel(xp, yp, wcs, origin=0, mode='all')[source]

Create a new SkyCoord from pixel coordinates using a World Coordinate System.

Parameters:
xp, yppython:float or ndarray

The coordinates to convert.

wcsWCS

The WCS to use for convert

originpython:int

Whether to return 0 or 1-based pixel coordinates.

mode‘all’ or ‘wcs’

Whether to do the transformation including distortions ('all') or only including only the core WCS transformation ('wcs').

Returns:
coordSkyCoord

A new object with sky coordinates corresponding to the input xp and yp.

See also

to_pixel

to do the inverse operation

astropy.wcs.utils.pixel_to_skycoord

the implementation of this method

get_constellation(short_name=False, constellation_list='iau')[source]

Determines the constellation(s) of the coordinates this SkyCoord contains.

Parameters:
short_namebool

If True, the returned names are the IAU-sanctioned abbreviated names. Otherwise, full names for the constellations are used.

constellation_listpython:str

The set of constellations to use. Currently only 'iau' is supported, meaning the 88 “modern” constellations endorsed by the IAU.

Returns:
constellationpython:str or python:str array

If this is a scalar coordinate, returns the name of the constellation. If it is an array SkyCoord, it returns an array of names.

Notes

To determine which constellation a point on the sky is in, this first precesses to B1875, and then uses the Delporte boundaries of the 88 modern constellations, as tabulated by Roman 1987.

classmethod guess_from_table(table, **coord_kwargs)[source]

A convenience method to create and return a new SkyCoord from the data in an astropy Table.

This method matches table columns that start with the case-insensitive names of the the components of the requested frames (including differentials), if they are also followed by a non-alphanumeric character. It will also match columns that end with the component name if a non-alphanumeric character is before it.

For example, the first rule means columns with names like 'RA[J2000]' or 'ra' will be interpreted as ra attributes for ICRS frames, but 'RAJ2000' or 'radius' are not. Similarly, the second rule applied to the Galactic frame means that a column named 'gal_l' will be used as the the l component, but gall or 'fill' will not.

The definition of alphanumeric here is based on Unicode’s definition of alphanumeric, except without _ (which is normally considered alphanumeric). So for ASCII, this means the non-alphanumeric characters are <space>_!"#$%&'()*+,-./\:;<=>?@[]^`{|}~).

Parameters:
tableTable or subclass

The table to load data from.

**coord_kwargs

Any additional keyword arguments are passed directly to this class’s constructor.

Returns:
newscSkyCoord or subclass

The new instance.

Raises:
ValueError

If more than one match is found in the table for a component, unless the additional matches are also valid frame component names. If a “coord_kwargs” is provided for a value also found in the table.

insert(obj, values, axis=0)[source]

Insert coordinate values before the given indices in the object and return a new Frame object.

The values to be inserted must conform to the rules for in-place setting of SkyCoord objects.

The API signature matches the np.insert API, but is more limited. The specification of insert index obj must be a single integer, and the axis must be 0 for simple insertion before the index.

Parameters:
objpython:int

Integer index before which values is inserted.

valuesnumpy:array_like

Value(s) to insert. If the type of values is different from that of quantity, values is converted to the matching type.

axispython:int, optional

Axis along which to insert values. Default is 0, which is the only allowed value and will insert a row.

Returns:
outSkyCoord instance

New coordinate object with inserted value(s)

is_equivalent_frame(other)[source]

Checks if this object’s frame as the same as that of the other object.

To be the same frame, two objects must be the same frame class and have the same frame attributes. For two SkyCoord objects, all of the frame attributes have to match, not just those relevant for the object’s frame.

Parameters:
otherSkyCoord or BaseCoordinateFrame

The other object to check.

Returns:
isequivbool

True if the frames are the same, False if not.

Raises:
TypeError

If other isn’t a SkyCoord or a subclass of BaseCoordinateFrame.

is_transformable_to(new_frame)[source]

Determines if this coordinate frame can be transformed to another given frame.

Parameters:
new_frameframe class, frame object, or python:str

The proposed frame to transform into.

Returns:
transformablebool or python:str

True if this can be transformed to new_frame, False if not, or the string ‘same’ if new_frame is the same system as this object but no transformation is defined.

Notes

A return value of ‘same’ means the transformation will work, but it will just give back a copy of this object. The intended usage is:

if coord.is_transformable_to(some_unknown_frame):
    coord2 = coord.transform_to(some_unknown_frame)

This will work even if some_unknown_frame turns out to be the same frame class as coord. This is intended for cases where the frame is the same regardless of the frame attributes (e.g. ICRS), but be aware that it might also indicate that someone forgot to define the transformation between two objects of the same frame class but with different attributes.

match_to_catalog_3d(catalogcoord, nthneighbor=1)[source]

Finds the nearest 3-dimensional matches of this coordinate to a set of catalog coordinates.

This finds the 3-dimensional closest neighbor, which is only different from the on-sky distance if distance is set in this object or the catalogcoord object.

For more on how to use this (and related) functionality, see the examples in Separations, Offsets, Catalog Matching, and Related Functionality.

Parameters:
catalogcoordSkyCoord or BaseCoordinateFrame

The base catalog in which to search for matches. Typically this will be a coordinate object that is an array (i.e., catalogcoord.isscalar == False)

nthneighborpython:int, optional

Which closest neighbor to search for. Typically 1 is desired here, as that is correct for matching one set of coordinates to another. The next likely use case is 2, for matching a coordinate catalog against itself (1 is inappropriate because each point will find itself as the closest match).

Returns:
idxpython:int array

Indices into catalogcoord to get the matched points for each of this object’s coordinates. Shape matches this object.

sep2dAngle

The on-sky separation between the closest match for each element in this object in catalogcoord. Shape matches this object.

dist3dQuantity [:ref: ‘length’]

The 3D distance between the closest match for each element in this object in catalogcoord. Shape matches this object.

Notes

This method requires SciPy to be installed or it will fail.

match_to_catalog_sky(catalogcoord, nthneighbor=1)[source]

Finds the nearest on-sky matches of this coordinate in a set of catalog coordinates.

For more on how to use this (and related) functionality, see the examples in Separations, Offsets, Catalog Matching, and Related Functionality.

Parameters:
catalogcoordSkyCoord or BaseCoordinateFrame

The base catalog in which to search for matches. Typically this will be a coordinate object that is an array (i.e., catalogcoord.isscalar == False)

nthneighborpython:int, optional

Which closest neighbor to search for. Typically 1 is desired here, as that is correct for matching one set of coordinates to another. The next likely use case is 2, for matching a coordinate catalog against itself (1 is inappropriate because each point will find itself as the closest match).

Returns:
idxpython:int array

Indices into catalogcoord to get the matched points for each of this object’s coordinates. Shape matches this object.

sep2dAngle

The on-sky separation between the closest match for each element in this object in catalogcoord. Shape matches this object.

dist3dQuantity [:ref: ‘length’]

The 3D distance between the closest match for each element in this object in catalogcoord. Shape matches this object. Unless both this and catalogcoord have associated distances, this quantity assumes that all sources are at a distance of 1 (dimensionless).

Notes

This method requires SciPy to be installed or it will fail.

position_angle(other)[source]

Computes the on-sky position angle (East of North) between this SkyCoord and another.

Parameters:
otherSkyCoord

The other coordinate to compute the position angle to. It is treated as the “head” of the vector of the position angle.

Returns:
paAngle

The (positive) position angle of the vector pointing from self to other. If either self or other contain arrays, this will be an array following the appropriate numpy broadcasting rules.

Examples

>>> c1 = SkyCoord(0*u.deg, 0*u.deg)
>>> c2 = SkyCoord(1*u.deg, 0*u.deg)
>>> c1.position_angle(c2).degree
90.0
>>> c3 = SkyCoord(1*u.deg, 1*u.deg)
>>> c1.position_angle(c3).degree  
44.995636455344844
radial_velocity_correction(kind='barycentric', obstime=None, location=None)[source]

Compute the correction required to convert a radial velocity at a given time and place on the Earth’s Surface to a barycentric or heliocentric velocity.

Parameters:
kindpython:str

The kind of velocity correction. Must be ‘barycentric’ or ‘heliocentric’.

obstimeTime or python:None, optional

The time at which to compute the correction. If None, the obstime frame attribute on the SkyCoord will be used.

locationEarthLocation or python:None, optional

The observer location at which to compute the correction. If None, the location frame attribute on the passed-in obstime will be used, and if that is None, the location frame attribute on the SkyCoord will be used.

Returns:
vcorrQuantity [:ref: ‘speed’]

The correction with a positive sign. I.e., add this to an observed radial velocity to get the barycentric (or heliocentric) velocity. If m/s precision or better is needed, see the notes below.

Raises:
ValueError

If either obstime or location are passed in (not None) when the frame attribute is already set on this SkyCoord.

TypeError

If obstime or location aren’t provided, either as arguments or as frame attributes.

Notes

The barycentric correction is calculated to higher precision than the heliocentric correction and includes additional physics (e.g time dilation). Use barycentric corrections if m/s precision is required.

The algorithm here is sufficient to perform corrections at the mm/s level, but care is needed in application. The barycentric correction returned uses the optical approximation v = z * c. Strictly speaking, the barycentric correction is multiplicative and should be applied as:

>>> from astropy.time import Time
>>> from astropy.coordinates import SkyCoord, EarthLocation
>>> from astropy.constants import c
>>> t = Time(56370.5, format='mjd', scale='utc')
>>> loc = EarthLocation('149d33m00.5s','-30d18m46.385s',236.87*u.m)
>>> sc = SkyCoord(1*u.deg, 2*u.deg)
>>> vcorr = sc.radial_velocity_correction(kind='barycentric', obstime=t, location=loc)  
>>> rv = rv + vcorr + rv * vcorr / c  

Also note that this method returns the correction velocity in the so-called optical convention:

>>> vcorr = zb * c  

where zb is the barycentric correction redshift as defined in section 3 of Wright & Eastman (2014). The application formula given above follows from their equation (11) under assumption that the radial velocity rv has also been defined using the same optical convention. Note, this can be regarded as a matter of velocity definition and does not by itself imply any loss of accuracy, provided sufficient care has been taken during interpretation of the results. If you need the barycentric correction expressed as the full relativistic velocity (e.g., to provide it as the input to another software which performs the application), the following recipe can be used:

>>> zb = vcorr / c  
>>> zb_plus_one_squared = (zb + 1) ** 2  
>>> vcorr_rel = c * (zb_plus_one_squared - 1) / (zb_plus_one_squared + 1)  

or alternatively using just equivalencies:

>>> vcorr_rel = vcorr.to(u.Hz, u.doppler_optical(1*u.Hz)).to(vcorr.unit, u.doppler_relativistic(1*u.Hz))  

See also doppler_optical, doppler_radio, and doppler_relativistic for more information on the velocity conventions.

The default is for this method to use the builtin ephemeris for computing the sun and earth location. Other ephemerides can be chosen by setting the solar_system_ephemeris variable, either directly or via with statement. For example, to use the JPL ephemeris, do:

>>> from astropy.coordinates import solar_system_ephemeris
>>> sc = SkyCoord(1*u.deg, 2*u.deg)
>>> with solar_system_ephemeris.set('jpl'):  
...     rv += sc.radial_velocity_correction(obstime=t, location=loc)  
search_around_3d(searcharoundcoords, distlimit)[source]

Searches for all coordinates in this object around a supplied set of points within a given 3D radius.

This is intended for use on SkyCoord objects with coordinate arrays, rather than a scalar coordinate. For a scalar coordinate, it is better to use separation_3d.

For more on how to use this (and related) functionality, see the examples in Separations, Offsets, Catalog Matching, and Related Functionality.

Parameters:
searcharoundcoordsSkyCoord or BaseCoordinateFrame

The coordinates to search around to try to find matching points in this SkyCoord. This should be an object with array coordinates, not a scalar coordinate object.

distlimitQuantity [:ref: ‘length’]

The physical radius to search within.

Returns:
idxsearcharoundpython:int array

Indices into searcharoundcoords that match the corresponding elements of idxself. Shape matches idxself.

idxselfpython:int array

Indices into self that match the corresponding elements of idxsearcharound. Shape matches idxsearcharound.

sep2dAngle

The on-sky separation between the coordinates. Shape matches idxsearcharound and idxself.

dist3dQuantity [:ref: ‘length’]

The 3D distance between the coordinates. Shape matches idxsearcharound and idxself.

Notes

This method requires SciPy to be installed or it will fail.

In the current implementation, the return values are always sorted in the same order as the searcharoundcoords (so idxsearcharound is in ascending order). This is considered an implementation detail, though, so it could change in a future release.

search_around_sky(searcharoundcoords, seplimit)[source]

Searches for all coordinates in this object around a supplied set of points within a given on-sky separation.

This is intended for use on SkyCoord objects with coordinate arrays, rather than a scalar coordinate. For a scalar coordinate, it is better to use separation.

For more on how to use this (and related) functionality, see the examples in Separations, Offsets, Catalog Matching, and Related Functionality.

Parameters:
searcharoundcoordsastropy:coordinate-like

The coordinates to search around to try to find matching points in this SkyCoord. This should be an object with array coordinates, not a scalar coordinate object.

seplimitQuantity [:ref: ‘angle’]

The on-sky separation to search within.

Returns:
idxsearcharoundpython:int array

Indices into searcharoundcoords that match the corresponding elements of idxself. Shape matches idxself.

idxselfpython:int array

Indices into self that match the corresponding elements of idxsearcharound. Shape matches idxsearcharound.

sep2dAngle

The on-sky separation between the coordinates. Shape matches idxsearcharound and idxself.

dist3dQuantity [:ref: ‘length’]

The 3D distance between the coordinates. Shape matches idxsearcharound and idxself.

Notes

This method requires SciPy to be installed or it will fail.

In the current implementation, the return values are always sorted in the same order as the searcharoundcoords (so idxsearcharound is in ascending order). This is considered an implementation detail, though, so it could change in a future release.

separation(other)[source]

Computes on-sky separation between this coordinate and another.

Note

If the other coordinate object is in a different frame, it is first transformed to the frame of this object. This can lead to unintuitive behavior if not accounted for. Particularly of note is that self.separation(other) and other.separation(self) may not give the same answer in this case.

For more on how to use this (and related) functionality, see the examples in Separations, Offsets, Catalog Matching, and Related Functionality.

Parameters:
otherSkyCoord or BaseCoordinateFrame

The coordinate to get the separation to.

Returns:
sepAngle

The on-sky separation between this and the other coordinate.

Notes

The separation is calculated using the Vincenty formula, which is stable at all locations, including poles and antipodes [1].

separation_3d(other)[source]

Computes three dimensional separation between this coordinate and another.

For more on how to use this (and related) functionality, see the examples in Separations, Offsets, Catalog Matching, and Related Functionality.

Parameters:
otherSkyCoord or BaseCoordinateFrame

The coordinate to get the separation to.

Returns:
sepDistance

The real-space distance between these two coordinates.

Raises:
ValueError

If this or the other coordinate do not have distances.

skyoffset_frame(rotation=None)[source]

Returns the sky offset frame with this SkyCoord at the origin.

Parameters:
rotationastropy:angle-like

The final rotation of the frame about the origin. The sign of the rotation is the left-hand rule. That is, an object at a particular position angle in the un-rotated system will be sent to the positive latitude (z) direction in the final frame.

Returns:
astrframeSkyOffsetFrame

A sky offset frame of the same type as this SkyCoord (e.g., if this object has an ICRS coordinate, the resulting frame is SkyOffsetICRS, with the origin set to this object)

spherical_offsets_by(d_lon, d_lat)[source]

Computes the coordinate that is a specified pair of angular offsets away from this coordinate.

Parameters:
d_lonastropy:angle-like

The angular offset in the longitude direction. The definition of “longitude” depends on this coordinate’s frame (e.g., RA for equatorial coordinates).

d_latastropy:angle-like

The angular offset in the latitude direction. The definition of “latitude” depends on this coordinate’s frame (e.g., Dec for equatorial coordinates).

Returns:
newcoordSkyCoord

The coordinates for the location that corresponds to offsetting by d_lat in the latitude direction and d_lon in the longitude direction.

See also

spherical_offsets_to

compute the angular offsets to another coordinate

directional_offset_by

offset a coordinate by an angle in a direction

Notes

This internally uses SkyOffsetFrame to do the transformation. For a more complete set of transform offsets, use SkyOffsetFrame or WCS manually. This specific method can be reproduced by doing SkyCoord(SkyOffsetFrame(d_lon, d_lat, origin=self.frame).transform_to(self)).

spherical_offsets_to(tocoord)[source]

Computes angular offsets to go from this coordinate to another.

Parameters:
tocoordBaseCoordinateFrame

The coordinate to find the offset to.

Returns:
lon_offsetAngle

The angular offset in the longitude direction. The definition of “longitude” depends on this coordinate’s frame (e.g., RA for equatorial coordinates).

lat_offsetAngle

The angular offset in the latitude direction. The definition of “latitude” depends on this coordinate’s frame (e.g., Dec for equatorial coordinates).

Raises:
ValueError

If the tocoord is not in the same frame as this one. This is different from the behavior of the separation/separation_3d methods because the offset components depend critically on the specific choice of frame.

See also

separation

for the total angular offset (not broken out into components).

position_angle

for the direction of the offset.

Notes

This uses the sky offset frame machinery, and hence will produce a new sky offset frame if one does not already exist for this object’s frame class.

to_pixel(wcs, origin=0, mode='all')[source]

Convert this coordinate to pixel coordinates using a WCS object.

Parameters:
wcsWCS

The WCS to use for convert

originpython:int

Whether to return 0 or 1-based pixel coordinates.

mode‘all’ or ‘wcs’

Whether to do the transformation including distortions ('all') or only including only the core WCS transformation ('wcs').

Returns:
xp, ypnumpy.ndarray

The pixel coordinates

See also

astropy.wcs.utils.skycoord_to_pixel

the implementation of this method

to_string(style='decimal', **kwargs)[source]

A string representation of the coordinates.

The default styles definitions are:

'decimal': 'lat': {'decimal': True, 'unit': "deg"}
           'lon': {'decimal': True, 'unit': "deg"}
'dms': 'lat': {'unit': "deg"}
       'lon': {'unit': "deg"}
'hmsdms': 'lat': {'alwayssign': True, 'pad': True, 'unit': "deg"}
          'lon': {'pad': True, 'unit': "hour"}

See to_string() for details and keyword arguments (the two angles forming the coordinates are are both Angle instances). Keyword arguments have precedence over the style defaults and are passed to to_string().

Parameters:
style{‘hmsdms’, ‘dms’, ‘decimal’}

The formatting specification to use. These encode the three most common ways to represent coordinates. The default is decimal.

**kwargs

Keyword args passed to to_string().

to_table()[source]

Convert this SkyCoord to a QTable.

Any attributes that have the same length as the SkyCoord will be converted to columns of the QTable. All other attributes will be recorded as metadata.

Returns:
QTable

A QTable containing the data of this SkyCoord.

Examples

>>> sc = SkyCoord(ra=[40, 70]*u.deg, dec=[0, -20]*u.deg,
...               obstime=Time([2000, 2010], format='jyear'))
>>> t =  sc.to_table()
>>> t
<QTable length=2>
   ra     dec   obstime
  deg     deg
float64 float64   Time
------- ------- -------
   40.0     0.0  2000.0
   70.0   -20.0  2010.0
>>> t.meta
{'representation_type': 'spherical', 'frame': 'icrs'}
transform_to(frame, merge_attributes=True)[source]

Transform this coordinate to a new frame.

The precise frame transformed to depends on merge_attributes. If False, the destination frame is used exactly as passed in. But this is often not quite what one wants. E.g., suppose one wants to transform an ICRS coordinate that has an obstime attribute to FK4; in this case, one likely would want to use this information. Thus, the default for merge_attributes is True, in which the precedence is as follows: (1) explicitly set (i.e., non-default) values in the destination frame; (2) explicitly set values in the source; (3) default value in the destination frame.

Note that in either case, any explicitly set attributes on the source SkyCoord that are not part of the destination frame’s definition are kept (stored on the resulting SkyCoord), and thus one can round-trip (e.g., from FK4 to ICRS to FK4 without losing obstime).

Parameters:
framepython:str, BaseCoordinateFrame class or instance, or SkyCoord instance

The frame to transform this coordinate into. If a SkyCoord, the underlying frame is extracted, and all other information ignored.

merge_attributesbool, optional

Whether the default attributes in the destination frame are allowed to be overridden by explicitly set attributes in the source (see note above; default: True).

Returns:
coordSkyCoord

A new object with this coordinate represented in the frame frame.

Raises:
ValueError

If there is no possible transformation route.