# Licensed under a 3-clause BSD style license - see LICENSE.rst
__all__ = ["FLRW", "FlatFLRWMixin"]
import inspect
import warnings
from dataclasses import field
from functools import cached_property
from inspect import signature
from math import floor, pi, sqrt
from numbers import Number
from typing import Any, Final, NamedTuple, TypeVar, overload
import numpy as np
from numpy import inf, sin
from numpy.typing import ArrayLike, NDArray
import astropy.constants as const
import astropy.units as u
from astropy.cosmology._src.typing import CosmoMeta, FArray
from astropy.utils.decorators import lazyproperty
from astropy.utils.exceptions import AstropyUserWarning
# isort: split
from astropy.cosmology._src.core import (
Cosmology,
FlatCosmologyMixin,
dataclass_decorator,
)
from astropy.cosmology._src.parameter import (
Parameter,
validate_non_negative,
validate_with_unit,
)
from astropy.cosmology._src.scipy_compat import quad
from astropy.cosmology._src.traits import (
BaryonComponent,
CriticalDensity,
CurvatureComponent,
DarkEnergyComponent,
DarkMatterComponent,
HubbleParameter,
MatterComponent,
PhotonComponent,
ScaleFactor,
TemperatureCMB,
TotalComponent,
)
from astropy.cosmology._src.utils import (
aszarr,
deprecated_keywords,
vectorize_redshift_method,
)
__doctest_requires__ = {"*": ["scipy"]}
_InputT = TypeVar("_InputT", bound=u.Quantity | np.ndarray | np.generic | Number)
##############################################################################
# Parameters
# Some conversion constants -- useful to compute them once here and reuse in
# the initialization rather than have every object do them.
# angle conversions
RAD_IN_ARCSEC: Final = (1 * u.rad).to(u.arcsec)
RAD_IN_ARCMIN: Final = (1 * u.rad).to(u.arcmin)
# Radiation parameter over c^2 in cgs (g cm^-3 K^-4)
a_B_c2: Final = (4 * const.sigma_sb / const.c**3).cgs.value
# Boltzmann constant in eV / K
kB_evK: Final = const.k_B.to(u.eV / u.K)
# See Komatsu et al. 2011, eq 26 and the surrounding discussion for an explanation of
# what this does. However, this is modified to handle multiple neutrino masses by
# computing the above for each mass, then summing
NEUTRINO_FERMI_DIRAC_CORRECTION: Final = 0.22710731766 # 7/8 (4/11)^4/3
# These are purely fitting constants -- see the Komatsu paper
KOMATSU_P: Final = 1.83
KOMATSU_INVP: Final = 0.54644808743 # 1.0 / p
KOMATSU_K: Final = 0.3173
# typing
_FLRWT = TypeVar("_FLRWT", bound="FLRW")
_FlatFLRWMixinT = TypeVar("_FlatFLRWMixinT", bound="FlatFLRWMixin")
##############################################################################
class NeutrinoInfo(NamedTuple):
"""A container for neutrino information.
This is Private API.
"""
n_nu: int
"""Number of neutrino species (floor of Neff)."""
neff_per_nu: float | None
"""Number of effective neutrino species per neutrino.
We are going to share Neff between the neutrinos equally. In detail this is not
correct, but it is a standard assumption because properly calculating it is a)
complicated b) depends on the details of the massive neutrinos (e.g., their weak
interactions, which could be unusual if one is considering sterile neutrinos).
"""
has_massive_nu: bool
"""Boolean of which neutrinos are massive."""
n_massive_nu: int
"""Number of massive neutrinos."""
n_massless_nu: int
"""Number of massless neutrinos."""
nu_y: NDArray[np.floating] | None
"""The ratio m_nu / (kB T_nu) for each massive neutrino."""
nu_y_list: list[float] | None
"""The ratio m_nu / (kB T_nu) for each massive neutrino as a list."""
##############################################################################
ParameterOde0 = Parameter(
doc="Omega dark energy; dark energy density/critical density at z=0.",
fvalidate="float",
)
[docs]
@dataclass_decorator
class FLRW(
Cosmology,
# Traits
BaryonComponent,
TotalComponent,
CriticalDensity,
MatterComponent,
CurvatureComponent,
DarkEnergyComponent,
HubbleParameter,
PhotonComponent,
ScaleFactor,
DarkMatterComponent,
TemperatureCMB,
):
"""An isotropic and homogeneous (Friedmann-Lemaitre-Robertson-Walker) cosmology.
This is an abstract base class -- you cannot instantiate examples of this
class, but must work with one of its subclasses, such as
:class:`~astropy.cosmology.LambdaCDM` or :class:`~astropy.cosmology.wCDM`.
Parameters
----------
H0 : float or scalar quantity-like ['frequency']
Hubble constant at z = 0. If a float, must be in [km/sec/Mpc].
Om0 : float
Omega matter: density of non-relativistic matter in units of the
critical density at z=0. Note that this does not include massive
neutrinos.
Ode0 : float
Omega dark energy: density of dark energy in units of the critical
density at z=0.
Tcmb0 : float or scalar quantity-like ['temperature'], optional
Temperature of the CMB z=0. If a float, must be in [K]. Default: 0 [K].
Setting this to zero will turn off both photons and neutrinos
(even massive ones).
Neff : float, optional
Effective number of Neutrino species. Default 3.04.
m_nu : quantity-like ['energy', 'mass'] or array-like, optional
Mass of each neutrino species in [eV] (mass-energy equivalency enabled).
If this is a scalar Quantity, then all neutrino species are assumed to
have that mass. Otherwise, the mass of each species. The actual number
of neutrino species (and hence the number of elements of m_nu if it is
not scalar) must be the floor of Neff. Typically this means you should
provide three neutrino masses unless you are considering something like
a sterile neutrino.
Ob0 : float, optional
Omega baryons: density of baryonic matter in units of the critical
density at z=0.
name : str or None (optional, keyword-only)
Name for this cosmological object.
meta : mapping or None (optional, keyword-only)
Metadata for the cosmology, e.g., a reference.
Notes
-----
Class instances are immutable -- you cannot change the parameters' values.
That is, all of the above attributes (except meta) are read only.
For details on how to create performant custom subclasses, see the
documentation on :ref:`astropy-cosmology-fast-integrals`.
"""
H0: Parameter = Parameter(
doc="Hubble constant at z=0.",
unit="km/(s Mpc)",
fvalidate="scalar",
)
Om0: Parameter = Parameter(
doc="Omega matter; matter density/critical density at z=0.",
fvalidate="non-negative",
)
Ode0: Parameter = ParameterOde0.clone()
Tcmb0: Parameter = Parameter(
default=0.0 * u.K,
doc="Temperature of the CMB at z=0.",
unit="Kelvin",
fvalidate="scalar",
)
Neff: Parameter = Parameter(
default=3.04,
doc="Number of effective neutrino species.",
fvalidate="non-negative",
)
m_nu: Parameter = Parameter(
default=0.0 * u.eV,
doc="Mass of neutrino species.",
unit="eV",
equivalencies=u.mass_energy(),
)
Ob0: Parameter = Parameter(
default=0.0,
doc="Omega baryon; baryonic matter density/critical density at z=0.",
)
def __post_init__(self) -> None:
# Compute neutrino parameters:
if self.m_nu is None:
nu_info = NeutrinoInfo(
n_nu=0,
neff_per_nu=None,
has_massive_nu=False,
n_massive_nu=0,
n_massless_nu=0,
nu_y=None,
nu_y_list=None,
)
else:
n_nu = floor(self.Neff)
massive = np.nonzero(self.m_nu.value > 0)[0]
has_massive_nu = massive.size > 0
n_massive_nu = len(massive)
# Compute Neutrino Omega and total relativistic component for massive
# neutrinos. We also store a list version, since that is more efficient
# to do integrals with (perhaps surprisingly! But small python lists
# are more efficient than small NumPy arrays).
if has_massive_nu:
nu_y = (self.m_nu[massive] / (kB_evK * self.Tnu0)).to_value(u.one)
nu_y_list = nu_y.tolist()
else:
nu_y = nu_y_list = None
nu_info = NeutrinoInfo(
n_nu=n_nu,
# We share Neff between the neutrinos equally. In detail this is not
# correct. See NeutrinoInfo for more info.
neff_per_nu=self.Neff / n_nu,
# Now figure out if we have massive neutrinos to deal with, and if
# so, get the right number of masses. It is worth keeping track of
# massless ones separately (since they are easy to deal with, and a
# common use case is to have only one massive neutrino).
has_massive_nu=has_massive_nu,
n_massive_nu=n_massive_nu,
n_massless_nu=n_nu - n_massive_nu,
nu_y=nu_y,
nu_y_list=nu_y_list,
)
self._nu_info: NeutrinoInfo
object.__setattr__(self, "_nu_info", nu_info)
# Subclasses should override this reference if they provide
# more efficient scalar versions of inv_efunc.
object.__setattr__(self, "_inv_efunc_scalar", self.inv_efunc)
object.__setattr__(self, "_inv_efunc_scalar_args", ())
# ---------------------------------------------------------------
# Parameter details
@m_nu.validator
def m_nu(self, param: Parameter, value: Any) -> FArray | None:
"""Validate neutrino masses to right value, units, and shape.
There are no neutrinos if floor(Neff) or Tcmb0 are 0. The number of
neutrinos must match floor(Neff). Neutrino masses cannot be
negative.
"""
# Check if there are any neutrinos
if (n_nu := floor(self.Neff)) == 0 or self.Tcmb0.value == 0:
return None # None, regardless of input
# Validate / set units
value = validate_with_unit(self, param, value)
# Check values and data shapes
if value.shape not in ((), (n_nu,)):
raise ValueError(
"unexpected number of neutrino masses — "
f"expected {n_nu}, got {len(value)}."
)
elif np.any(value.value < 0):
raise ValueError("invalid (negative) neutrino mass encountered.")
# scalar -> array
if value.isscalar:
value = np.full_like(value, value, shape=n_nu)
return value
# ---------------------------------------------------------------
# Baryons
@Ob0.validator
def Ob0(self, param: Parameter, value: Any) -> float:
"""Validate baryon density to a non-negative float > matter density."""
if value is None:
warnings.warn(
"Ob0=None is deprecated, use Ob0=0 instead, "
"which never causes methods to raise exceptions.",
category=DeprecationWarning,
stacklevel=2,
)
return 0.0
value = validate_non_negative(self, param, value)
if value > self.Om0:
raise ValueError(
"baryonic density can not be larger than total matter density."
)
return value
# ---------------------------------------------------------------
# Critical Density
[docs]
@cached_property
def critical_density0(self) -> u.Quantity:
r"""Critical mass density at z=0.
The critical density is the density of the Universe at which the Universe is
flat. It is defined as :math:`\rho_{\text{crit}} = 3 H_0^2 / (8 \pi G)`.
"""
return (3 * self.H0**2 / (8 * pi * const.G)).cgs
# ---------------------------------------------------------------
# Curvature
[docs]
@cached_property
def Ok0(self) -> float | np.floating:
"""Omega curvature; the effective curvature density/critical density at z=0."""
return 1.0 - self.Om0 - self.Ode0 - self.Ogamma0 - self.Onu0
@property
def is_flat(self) -> bool:
"""Return `bool`; `True` if the cosmology is globally flat."""
return bool((self.Ok0 == 0.0) and (self.Otot0 == 1.0))
# ---------------------------------------------------------------
# Dark Matter
[docs]
@cached_property
def Odm0(self) -> float:
"""Omega dark matter; dark matter density/critical density at z=0."""
return self.Om0 - self.Ob0
# ---------------------------------------------------------------
# Hubble Parameter
[docs]
@deprecated_keywords("z", since="7.0")
def efunc(self, z: u.Quantity | ArrayLike) -> FArray:
"""Function used to calculate H(z), the Hubble parameter.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
E : array
The redshift scaling of the Hubble constant.
Defined such that :math:`H(z) = H_0 E(z)`.
Notes
-----
It is not necessary to override this method, but if de_density_scale
takes a particularly simple form, it may be advantageous to.
"""
Or = self.Ogamma0 + (
self.Onu0
if not self._nu_info.has_massive_nu
else self.Ogamma0 * self.nu_relative_density(z)
)
zp1 = aszarr(z) + 1.0 # (converts z [unit] -> z [dimensionless])
return np.sqrt(
zp1**2 * ((Or * zp1 + self.Om0) * zp1 + self.Ok0)
+ self.Ode0 * self.de_density_scale(z)
)
[docs]
@deprecated_keywords("z", since="7.0")
def inv_efunc(self, z: u.Quantity | ArrayLike) -> FArray:
"""Inverse of ``efunc``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
E : array
The redshift scaling of the inverse Hubble constant.
"""
# Avoid the function overhead by repeating code
Or = self.Ogamma0 + (
self.Onu0
if not self._nu_info.has_massive_nu
else self.Ogamma0 * self.nu_relative_density(z)
)
zp1 = aszarr(z) + 1.0 # (converts z [unit] -> z [dimensionless])
return (
zp1**2 * ((Or * zp1 + self.Om0) * zp1 + self.Ok0)
+ self.Ode0 * self.de_density_scale(z)
) ** (-0.5)
# ---------------------------------------------------------------
# properties
@property
def Otot0(self) -> float:
"""Omega total; the total density/critical density at z=0."""
return self.Om0 + self.Ogamma0 + self.Onu0 + self.Ode0 + self.Ok0
[docs]
@cached_property
def Tnu0(self) -> u.Quantity:
"""Temperature of the neutrino background as |Quantity| at z=0."""
# The constant in front is (4/11)^1/3 -- see any cosmology book for an
# explanation -- for example, Weinberg 'Cosmology' p 154 eq (3.1.21).
return 0.7137658555036082 * self.Tcmb0
@property
def has_massive_nu(self) -> bool:
"""Does this cosmology have at least one massive neutrino species?"""
if self.Tnu0.value == 0:
return False
return self._nu_info.has_massive_nu
[docs]
@cached_property
def Ogamma0(self) -> float:
"""Omega gamma; the density/critical density of photons at z=0."""
# photon density from Tcmb
return a_B_c2 * self.Tcmb0.value**4 / self.critical_density0.value
[docs]
@cached_property
def Onu0(self) -> float:
"""Omega nu; the density/critical density of neutrinos at z=0."""
if self._nu_info.has_massive_nu:
return self.Ogamma0 * self.nu_relative_density(0)
else:
# This case is particularly simple, so do it directly The 0.2271...
# is 7/8 (4/11)^(4/3) -- the temperature bit ^4 (blackbody energy
# density) times 7/8 for FD vs. BE statistics.
return NEUTRINO_FERMI_DIRAC_CORRECTION * self.Neff * self.Ogamma0
# ---------------------------------------------------------------
[docs]
@deprecated_keywords("z", since="7.0")
def Otot(self, z: u.Quantity | ArrayLike) -> FArray:
"""The total density parameter at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshifts.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
Otot : array
The total density relative to the critical density at each redshift.
"""
return self.Om(z) + self.Ogamma(z) + self.Onu(z) + self.Ode(z) + self.Ok(z)
# Odm is provided by the DarkMatterComponent trait
# Ogamma is provided by the PhotonComponent trait
[docs]
@deprecated_keywords("z", since="7.0")
def Onu(self, z: u.Quantity | ArrayLike) -> FArray:
r"""Return the density parameter for neutrinos at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
Onu : ndarray
The energy density of neutrinos relative to the critical density at
each redshift. Note that this includes their kinetic energy (if
they have mass), so it is not equal to the commonly used
:math:`\sum \frac{m_{\nu}}{94 eV}`, which does not include
kinetic energy.
"""
z = aszarr(z)
if self.Onu0 == 0: # Common enough to be worth checking explicitly
return np.zeros_like(z)
return self.Ogamma(z) * self.nu_relative_density(z)
[docs]
@deprecated_keywords("z", since="7.0")
def Tnu(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Return the neutrino temperature at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
Tnu : Quantity ['temperature']
The temperature of the cosmic neutrino background in K.
"""
return self.Tnu0 * (aszarr(z) + 1.0)
[docs]
@deprecated_keywords("z", since="7.0")
def nu_relative_density(self, z: u.Quantity | ArrayLike) -> FArray:
r"""Neutrino density function relative to the energy density in photons.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
f : array
The neutrino density scaling factor relative to the density in
photons at each redshift.
Notes
-----
The density in neutrinos is given by
.. math::
\rho_{\nu} \left(a\right) = 0.2271 \, N_{eff} \,
f\left(m_{\nu} a / T_{\nu 0} \right) \,
\rho_{\gamma} \left( a \right)
where
.. math::
f \left(y\right) = \frac{120}{7 \pi^4}
\int_0^{\infty} \, dx \frac{x^2 \sqrt{x^2 + y^2}}
{e^x + 1}
assuming that all neutrino species have the same mass.
If they have different masses, a similar term is calculated for each
one. Note that ``f`` has the asymptotic behavior :math:`f(0) = 1`. This
method returns :math:`0.2271 f` using an analytical fitting formula
given in Komatsu et al. 2011, ApJS 192, 18.
"""
# Note that there is also a scalar-z-only cython implementation of
# this in scalar_inv_efuncs.pyx, so if you find a problem in this
# you need to update there too.
# The massive and massless contribution must be handled separately
# But check for common cases first
z = aszarr(z)
if not self._nu_info.has_massive_nu:
return NEUTRINO_FERMI_DIRAC_CORRECTION * self.Neff * np.ones_like(z)
curr_nu_y = self._nu_info.nu_y / (1.0 + np.expand_dims(z, axis=-1))
rel_mass_per = (1.0 + (KOMATSU_K * curr_nu_y) ** KOMATSU_P) ** KOMATSU_INVP
rel_mass = rel_mass_per.sum(-1) + self._nu_info.n_massless_nu
return NEUTRINO_FERMI_DIRAC_CORRECTION * self._nu_info.neff_per_nu * rel_mass
def _lookback_time_integrand_scalar(self, z: float, /) -> float:
"""Integrand of the lookback time (equation 30 of [1]_).
Parameters
----------
z : float, positional-only
Input redshift.
.. versionchanged:: 7.0
The argument is positional-only.
Returns
-------
I : float
The integrand for the lookback time.
References
----------
.. [1] Hogg, D. (1999). Distance measures in cosmology, section 11.
arXiv e-prints, astro-ph/9905116.
"""
return self._inv_efunc_scalar(z, *self._inv_efunc_scalar_args) / (z + 1.0)
[docs]
@deprecated_keywords("z", since="7.0")
def lookback_time_integrand(self, z: u.Quantity | ArrayLike) -> FArray:
"""Integrand of the lookback time (equation 30 of [1]_).
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
I : array
The integrand for the lookback time.
References
----------
.. [1] Hogg, D. (1999). Distance measures in cosmology, section 11.
arXiv e-prints, astro-ph/9905116.
"""
z = aszarr(z)
return self.inv_efunc(z) / (z + 1.0)
def _abs_distance_integrand_scalar(self, z: u.Quantity | ArrayLike, /) -> float:
"""Integrand of the absorption distance (eq. 4, [1]_).
Parameters
----------
z : Quantity-like ['redshift'], array-like, positional-only
Input redshift.
.. versionchanged:: 7.0
The argument is positional-only.
Returns
-------
dX : float
The integrand for the absorption distance (dimensionless).
References
----------
.. [1] Bahcall, John N. and Peebles, P.J.E. 1969, ApJ, 156L, 7B
"""
return (z + 1.0) ** 2 * self._inv_efunc_scalar(z, *self._inv_efunc_scalar_args)
[docs]
@deprecated_keywords("z", since="7.0")
def abs_distance_integrand(self, z: u.Quantity | ArrayLike) -> FArray:
"""Integrand of the absorption distance (eq. 4, [1]_).
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
dX : array
The integrand for the absorption distance (dimensionless).
References
----------
.. [1] Bahcall, John N. and Peebles, P.J.E. 1969, ApJ, 156L, 7B
"""
z = aszarr(z)
return (z + 1.0) ** 2 * self.inv_efunc(z)
[docs]
@deprecated_keywords("z", since="7.0")
def lookback_time(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Lookback time in Gyr to redshift ``z``.
The lookback time is the difference between the age of the Universe now
and the age at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
t : Quantity ['time']
Lookback time in Gyr to each input redshift.
See Also
--------
z_at_value : Find the redshift corresponding to a lookback time.
"""
return self._lookback_time(z)
def _lookback_time(self, z: u.Quantity | ArrayLike, /) -> u.Quantity:
"""Lookback time in Gyr to redshift ``z``.
The lookback time is the difference between the age of the Universe now
and the age at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like, positional-only
Input redshift.
.. versionchanged:: 7.0
The argument is positional-only.
Returns
-------
t : Quantity ['time']
Lookback time in Gyr to each input redshift.
"""
return self.hubble_time * self._integral_lookback_time(z)
@vectorize_redshift_method
def _integral_lookback_time(self, z: u.Quantity | ArrayLike, /) -> FArray:
"""Lookback time to redshift ``z``. Value in units of Hubble time.
The lookback time is the difference between the age of the Universe now
and the age at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like, positional-only
Input redshift.
.. versionchanged:: 7.0
The argument is positional-only.
Returns
-------
t : ndarray
Lookback time to each input redshift in Hubble time units.
"""
return quad(self._lookback_time_integrand_scalar, 0, z)[0]
[docs]
@deprecated_keywords("z", since="7.0")
def lookback_distance(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""The lookback distance is the light travel time distance to a given redshift.
It is simply c * lookback_time. It may be used to calculate
the proper distance between two redshifts, e.g. for the mean free path
to ionizing radiation.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : Quantity ['length']
Lookback distance in Mpc
"""
return (self.lookback_time(z) * const.c).to(u.Mpc)
[docs]
@deprecated_keywords("z", since="7.0")
def age(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Age of the universe in Gyr at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
t : Quantity ['time']
The age of the universe in Gyr at each input redshift.
See Also
--------
z_at_value : Find the redshift corresponding to an age.
"""
return self._age(z)
def _age(self, z: u.Quantity | ArrayLike, /) -> u.Quantity:
"""Age of the universe in Gyr at redshift ``z``.
This internal function exists to be re-defined for optimizations.
Parameters
----------
z : Quantity-like ['redshift'], array-like, positional-only
Input redshift.
.. versionchanged:: 7.0
The argument is positional-only.
Returns
-------
t : Quantity ['time']
The age of the universe in Gyr at each input redshift.
"""
return self.hubble_time * self._integral_age(z)
@vectorize_redshift_method
def _integral_age(self, z: u.Quantity | ArrayLike, /) -> FArray:
"""Age of the universe at redshift ``z``. Value in units of Hubble time.
Calculated using explicit integration.
Parameters
----------
z : Quantity-like ['redshift'], array-like, positional-only
Input redshift.
Returns
-------
t : array
The age of the universe at each input redshift in Hubble time units.
See Also
--------
z_at_value : Find the redshift corresponding to an age.
"""
return quad(self._lookback_time_integrand_scalar, z, inf)[0]
# ---------------------------------------------------------------
# Comoving distance
@overload
def comoving_distance(self, z: _InputT) -> u.Quantity: ...
@overload
def comoving_distance(self, z: _InputT, z2: _InputT) -> u.Quantity: ...
[docs]
@deprecated_keywords("z2", since="7.1")
@deprecated_keywords("z", since="7.0")
def comoving_distance(self, z: _InputT, z2: _InputT | None = None) -> u.Quantity:
r"""Comoving line-of-sight distance :math:`d_c(z1, z2)` in Mpc.
The comoving distance along the line-of-sight between two objects
remains constant with time for objects in the Hubble flow.
Parameters
----------
z, z2 : Quantity ['redshift'], positional-only
Input redshifts. If one argument ``z`` is given, the distance
:math:`d_c(0, z)` is returned. If two arguments ``z1, z2`` are
given, the distance :math:`d_c(z_1, z_2)` is returned.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
Quantity ['length']
Comoving distance in Mpc between each input redshift.
"""
z1, z2 = (0.0, z) if z2 is None else (z, z2)
return self._comoving_distance_z1z2(z1, z2)
def _comoving_distance_z1z2(
self, z1: u.Quantity | ArrayLike, z2: u.Quantity | ArrayLike, /
) -> u.Quantity:
"""Comoving line-of-sight distance in Mpc between redshifts ``z1`` and ``z2``.
The comoving distance along the line-of-sight between two objects
remains constant with time for objects in the Hubble flow.
Parameters
----------
z1, z2 : Quantity-like ['redshift'], array-like, positional-only
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : Quantity ['length']
Comoving distance in Mpc between each input redshift.
"""
return self._integral_comoving_distance_z1z2(z1, z2)
def _integral_comoving_distance_z1z2(
self, z1: u.Quantity | ArrayLike, z2: u.Quantity | ArrayLike, /
) -> u.Quantity:
"""Comoving line-of-sight distance (Mpc) between objects at redshifts z1 and z2.
The comoving distance along the line-of-sight between two objects remains
constant with time for objects in the Hubble flow.
Parameters
----------
z1, z2 : Quantity-like ['redshift'] or array-like
Input redshifts.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
|Quantity| ['length']
Comoving distance in Mpc between each input redshift.
"""
return self.hubble_distance * self._integral_comoving_distance_z1z2_scalar(z1, z2) # fmt: skip
@vectorize_redshift_method(nin=2)
def _integral_comoving_distance_z1z2_scalar(
self, z1: u.Quantity | ArrayLike, z2: u.Quantity | ArrayLike, /
) -> FArray:
"""Comoving line-of-sight distance in Mpc between objects at redshifts ``z1`` and ``z2``.
The comoving distance along the line-of-sight between two objects
remains constant with time for objects in the Hubble flow.
Parameters
----------
z1, z2 : Quantity-like ['redshift'], array-like, positional-only
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : array
Comoving distance in Mpc between each input redshift.
"""
return quad(self._inv_efunc_scalar, z1, z2, args=self._inv_efunc_scalar_args)[0]
# ---------------------------------------------------------------
[docs]
@deprecated_keywords("z", since="7.0")
def comoving_transverse_distance(self, z: u.Quantity | ArrayLike) -> u.Quantity:
r"""Comoving transverse distance in Mpc at a given redshift.
This value is the transverse comoving distance at redshift ``z``
corresponding to an angular separation of 1 radian. This is the same as
the comoving distance if :math:`\Omega_k` is zero (as in the current
concordance Lambda-CDM model).
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : Quantity ['length']
Comoving transverse distance in Mpc at each input redshift.
Notes
-----
This quantity is also called the 'proper motion distance' in some texts.
"""
return self._comoving_transverse_distance_z1z2(0, z)
def _comoving_transverse_distance_z1z2(
self, z1: u.Quantity | ArrayLike, z2: u.Quantity | ArrayLike, /
) -> u.Quantity:
r"""Comoving transverse distance in Mpc between two redshifts.
This value is the transverse comoving distance at redshift ``z2`` as
seen from redshift ``z1`` corresponding to an angular separation of
1 radian. This is the same as the comoving distance if :math:`\Omega_k`
is zero (as in the current concordance Lambda-CDM model).
Parameters
----------
z1, z2 : Quantity-like ['redshift'], array-like, positional-only
Input redshifts.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : Quantity ['length']
Comoving transverse distance in Mpc between input redshift.
Notes
-----
This quantity is also called the 'proper motion distance' in some texts.
"""
Ok0 = self.Ok0
dc = self._comoving_distance_z1z2(z1, z2)
if Ok0 == 0:
return dc
sqrtOk0 = sqrt(abs(Ok0))
dh = self.hubble_distance
if Ok0 > 0:
return dh / sqrtOk0 * np.sinh(sqrtOk0 * dc.value / dh.value)
else:
return dh / sqrtOk0 * sin(sqrtOk0 * dc.value / dh.value)
[docs]
@deprecated_keywords("z", since="7.0")
def angular_diameter_distance(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Angular diameter distance in Mpc at a given redshift.
This gives the proper (sometimes called 'physical') transverse
distance corresponding to an angle of 1 radian for an object
at redshift ``z`` ([1]_, [2]_, [3]_).
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : Quantity ['length']
Angular diameter distance in Mpc at each input redshift.
References
----------
.. [1] Weinberg, 1972, pp 420-424; Weedman, 1986, pp 421-424.
.. [2] Weedman, D. (1986). Quasar astronomy, pp 65-67.
.. [3] Peebles, P. (1993). Principles of Physical Cosmology, pp 325-327.
"""
z = aszarr(z)
return self.comoving_transverse_distance(z) / (z + 1.0)
[docs]
@deprecated_keywords("z", since="7.0")
def luminosity_distance(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Luminosity distance in Mpc at redshift ``z``.
This is the distance to use when converting between the bolometric flux
from an object at redshift ``z`` and its bolometric luminosity [1]_.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : Quantity ['length']
Luminosity distance in Mpc at each input redshift.
See Also
--------
z_at_value : Find the redshift corresponding to a luminosity distance.
References
----------
.. [1] Weinberg, 1972, pp 420-424; Weedman, 1986, pp 60-62.
"""
z = aszarr(z)
return (z + 1.0) * self.comoving_transverse_distance(z)
[docs]
def angular_diameter_distance_z1z2(
self, z1: u.Quantity | ArrayLike, z2: u.Quantity | ArrayLike
) -> u.Quantity:
"""Angular diameter distance between objects at 2 redshifts.
Useful for gravitational lensing, for example computing the angular
diameter distance between a lensed galaxy and the foreground lens.
Parameters
----------
z1, z2 : Quantity-like ['redshift'], array-like
Input redshifts. For most practical applications such as
gravitational lensing, ``z2`` should be larger than ``z1``. The
method will work for ``z2 < z1``; however, this will return
negative distances.
Returns
-------
d : Quantity ['length']
The angular diameter distance between each input redshift pair.
Returns scalar if input is scalar, array else-wise.
"""
z1, z2 = aszarr(z1), aszarr(z2)
if np.any(z2 < z1):
warnings.warn(
f"Second redshift(s) z2 ({z2}) is less than first "
f"redshift(s) z1 ({z1}).",
AstropyUserWarning,
)
return self._comoving_transverse_distance_z1z2(z1, z2) / (z2 + 1.0)
[docs]
@vectorize_redshift_method
def absorption_distance(self, z: u.Quantity | ArrayLike, /) -> FArray:
"""Absorption distance at redshift ``z`` (eq. 4, [1]_).
This is used to calculate the number of objects with some cross section
of absorption and number density intersecting a sightline per unit
redshift path [1]_.
Parameters
----------
z : Quantity-like ['redshift'], array-like, positional-only
Input redshift.
Returns
-------
X : array
Absorption distance (dimensionless) at each input redshift.
References
----------
.. [1] Bahcall, John N. and Peebles, P.J.E. 1969, ApJ, 156L, 7B
"""
return quad(self._abs_distance_integrand_scalar, 0, z)[0]
[docs]
@deprecated_keywords("z", since="7.0")
def distmod(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Distance modulus at redshift ``z``.
The distance modulus is defined as the (apparent magnitude - absolute
magnitude) for an object at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
distmod : Quantity ['length']
Distance modulus at each input redshift, in magnitudes.
See Also
--------
z_at_value : Find the redshift corresponding to a distance modulus.
"""
# Remember that the luminosity distance is in Mpc
# Abs is necessary because in certain obscure closed cosmologies
# the distance modulus can be negative -- which is okay because
# it enters as the square.
val = 5.0 * np.log10(abs(self.luminosity_distance(z).value)) + 25.0
return u.Quantity(val, u.mag)
[docs]
@deprecated_keywords("z", since="7.0")
def comoving_volume(self, z: u.Quantity | ArrayLike) -> u.Quantity:
r"""Comoving volume in cubic Mpc at redshift ``z``.
This is the volume of the universe encompassed by redshifts less than
``z``. For the case of :math:`\Omega_k = 0` it is a sphere of radius
`comoving_distance` but it is less intuitive if :math:`\Omega_k` is not.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
V : Quantity ['volume']
Comoving volume in :math:`Mpc^3` at each input redshift.
"""
Ok0 = self.Ok0
if Ok0 == 0:
return 4.0 / 3.0 * pi * self.comoving_distance(z) ** 3
dh = self.hubble_distance.value # .value for speed
dm = self.comoving_transverse_distance(z).value
term1 = 4.0 * pi * dh**3 / (2.0 * Ok0) * u.Mpc**3
term2 = dm / dh * np.sqrt(1 + Ok0 * (dm / dh) ** 2)
term3 = sqrt(abs(Ok0)) * dm / dh
if Ok0 > 0:
return term1 * (term2 - 1.0 / sqrt(abs(Ok0)) * np.arcsinh(term3))
else:
return term1 * (term2 - 1.0 / sqrt(abs(Ok0)) * np.arcsin(term3))
[docs]
@deprecated_keywords("z", since="7.0")
def differential_comoving_volume(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Differential comoving volume at redshift z.
Useful for calculating the effective comoving volume.
For example, allows for integration over a comoving volume that has a
sensitivity function that changes with redshift. The total comoving
volume is given by integrating ``differential_comoving_volume`` to
redshift ``z`` and multiplying by a solid angle.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
dV : Quantity
Differential comoving volume per redshift per steradian at each
input redshift.
"""
dm = self.comoving_transverse_distance(z)
return self.hubble_distance * (dm**2.0) / (self.efunc(z) << u.steradian)
[docs]
@deprecated_keywords("z", since="7.0")
def kpc_comoving_per_arcmin(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Separation in transverse comoving kpc equal to an arcmin at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : Quantity ['length']
The distance in comoving kpc corresponding to an arcmin at each
input redshift.
"""
return self.comoving_transverse_distance(z).to(u.kpc) / RAD_IN_ARCMIN
[docs]
@deprecated_keywords("z", since="7.0")
def kpc_proper_per_arcmin(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Separation in transverse proper kpc equal to an arcminute at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
d : Quantity ['length']
The distance in proper kpc corresponding to an arcmin at each input
redshift.
"""
return self.angular_diameter_distance(z).to(u.kpc) / RAD_IN_ARCMIN
[docs]
@deprecated_keywords("z", since="7.0")
def arcsec_per_kpc_comoving(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Angular separation in arcsec equal to a comoving kpc at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
theta : Quantity ['angle']
The angular separation in arcsec corresponding to a comoving kpc at
each input redshift.
"""
return RAD_IN_ARCSEC / self.comoving_transverse_distance(z).to(u.kpc)
[docs]
@deprecated_keywords("z", since="7.0")
def arcsec_per_kpc_proper(self, z: u.Quantity | ArrayLike) -> u.Quantity:
"""Angular separation in arcsec corresponding to a proper kpc at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
theta : Quantity ['angle']
The angular separation in arcsec corresponding to a proper kpc at
each input redshift.
"""
return RAD_IN_ARCSEC / self.angular_diameter_distance(z).to(u.kpc)
[docs]
@dataclass_decorator
class FlatFLRWMixin(FlatCosmologyMixin):
"""Mixin class for flat FLRW cosmologies.
Do NOT instantiate directly. Must precede the base class in the
multiple-inheritance so that this mixin's ``__init__`` proceeds the
base class'. Note that all instances of ``FlatFLRWMixin`` are flat, but
not all flat cosmologies are instances of ``FlatFLRWMixin``. As
example, ``LambdaCDM`` **may** be flat (for the a specific set of
parameter values), but ``FlatLambdaCDM`` **will** be flat.
"""
Ode0: Parameter = field( # now a derived param.
default=ParameterOde0.clone(default=0, derived=True),
init=False,
repr=False,
)
def __init_subclass__(cls) -> None:
super().__init_subclass__()
# Check that Ode0 is not in __init__
if (
getattr(
vars(cls).get("Ode0", cls.__dataclass_fields__.get("Ode0")),
"init",
True,
)
or "Ode0" in signature(cls.__init__).parameters
):
msg = "subclasses of `FlatFLRWMixin` cannot have `Ode0` in `__init__`"
raise TypeError(msg)
def __post_init__(self) -> None:
self.__dict__["Ode0"] = 0
super().__post_init__()
# Do some twiddling after the fact to get flatness
self.__dict__["Ok0"] = 0.0
self.__dict__["Ode0"] = 1.0 - (self.Om0 + self.Ogamma0 + self.Onu0 + self.Ok0)
@lazyproperty
def nonflat(self: _FlatFLRWMixinT) -> _FLRWT: # noqa: PYI019
# Create BoundArgument to handle args versus kwargs.
# This also handles all errors from mismatched arguments
ba = inspect.signature(self.__nonflatclass__).bind_partial(
**dict(self.parameters), Ode0=self.Ode0, name=self.name
)
# Make new instance, respecting args vs kwargs
inst = self.__nonflatclass__(*ba.args, **ba.kwargs)
# Because of machine precision, make sure parameters exactly match
inst.__dict__.update(inst.parameters)
inst.__dict__.update(inst._derived_parameters)
inst.__dict__["Ok0"] = self.Ok0
return inst
@property
def Otot0(self) -> float:
"""Omega total; the total density/critical density at z=0."""
return 1.0
[docs]
@deprecated_keywords("z", since="7.0")
def Otot(self, z: u.Quantity | ArrayLike) -> FArray:
"""The total density parameter at redshift ``z``.
Parameters
----------
z : Quantity-like ['redshift'], array-like
Input redshift.
.. versionchanged:: 7.0
Passing z as a keyword argument is deprecated.
Returns
-------
Otot : array
"""
return np.ones_like(aszarr(z), subok=True)
[docs]
def clone(
self, *, meta: CosmoMeta | None = None, to_nonflat: bool = False, **kwargs: Any
) -> "FLRW":
if not to_nonflat and kwargs.get("Ode0") is not None:
msg = "Cannot set 'Ode0' in clone unless 'to_nonflat=True'. "
raise ValueError(msg)
return super().clone(meta=meta, to_nonflat=to_nonflat, **kwargs)
