RadialDifferential#

class astropy.coordinates.RadialDifferential(*args, **kwargs)[source]#

Differential(s) of radial distances.

Parameters:

d_distanceQuantity: The differential distance.
copybool, optional: If True (default), arrays will be copied. If False, arrays will be references, though possibly broadcast to ensure matching shapes.

Attributes Summary

`attr_classes`
`d_distance`	Component 'd_distance' of the Differential.

Methods Summary

`from_cartesian`(other, base)	Convert the differential from 3D rectangular cartesian coordinates to the desired class.
`from_representation`(representation[, base])	Create a new instance of this representation from another one.
`norm`([base])	Vector norm.
`to_cartesian`(base)	Convert the differential to 3D rectangular cartesian coordinates.

Attributes Documentation

Methods Documentation

classmethod from_cartesian(other, base)[source]#

Convert the differential from 3D rectangular cartesian coordinates to the desired class.

Parameters:

other: The object to convert into this differential.
baseBaseRepresentation: The points for which the differentials are to be converted: each of the components is multiplied by its unit vectors and scale factors. Will be converted to cls.base_representation if needed.

Returns:

BaseDifferential subclass instance: A new differential object that is this class’ type.

classmethod from_representation(representation, base=None)[source]#

Create a new instance of this representation from another one.

Parameters:

representationBaseRepresentation instance: The presentation that should be converted to this class.
baseinstance of cls.base_representation: The base relative to which the differentials will be defined. If the representation is a differential itself, the base will be converted to its base_representation to help convert it.

norm(base=None)[source]#

Vector norm.

The norm is the standard Frobenius norm, i.e., the square root of the sum of the squares of all components with non-angular units.

Parameters:

baseinstance of self.base_representation: Base relative to which the differentials are defined. This is required to calculate the physical size of the differential for all but Cartesian differentials or radial differentials.

Returns:

normastropy.units.Quantity: Vector norm, with the same shape as the representation.

to_cartesian(base)[source]#

Convert the differential to 3D rectangular cartesian coordinates.

Parameters:

baseinstance of self.base_representation: The points for which the differentials are to be converted: each of the components is multiplied by its unit vectors and scale factors.

Returns: