Halo model power spectrum calculations
Project description
Halo model
This repository is home to the pyhalomodel
package, which was written as part of the Asgari, Mead & Heymans (2023) halo-model review paper. The software is written entirely in Python
, with extendability and reusability in mind. The purpose of this software is to take some of the drudgery out of performing basic calculations using the halo model. While the integrals that the halo model requires the researcher to evaluate are simple, in practice the changes of variables required to integrate halo profiles against halo mass functions can be confusing and tedious. In our experience this confusion has led to bugs and misunderstandings over the years, and our hope for this software is to reduce the proliferation of these somewhat. Our software can produce power spectra for any combinations of tracers, and simply requires halo profiles for the tracers to be specified. These could be matter profiles, galaxy profiles, or anything else, for example electron-pressure or HI profiles.
You might also be interested in this pure Python
implementation of HMcode, which makes use of the pyhalomodel
package.
Dependencies
numpy
scipy
Installation
For the general user, pyhalomodel
can be installed using pip
:
pip install pyhalomodel
If you you want to modify the source, or use the demo notebooks, then simply clone the repository. You can then create an environment with all necessary dependencies using poetry. From the cloned pyhalomodel
directory:
poetry install
The demo notebooks require some additional dependencies: camb
; dark-emulator
; ipykernel
; matplotlib
; halomod
. These will be installed in the environment automatically. You can also install without poetry
, either system wide or using another environment manager; we include a requirements.txt
.
Usage
Start a script with
import numpy as np
import pyhalomodel as halo
Importing via import pyhalomodel as halo
is nice because the functions and classes then have readable names (e.g., halo.model
, halo.profile
). To make non-linear power spectrum predictions using the halo model requires a linear power spectrum. In our demonstration notebooks we always take this from CAMB
, but it could come from any source. Calculations also require the variance in the linear density field when smoothed on comoving scale $R$: $\sigma^2(R)$. Once again, this function could come from any source, but we take it from CAMB
.
A typical call to create an instance of a model
object looks like
model = halo.model(z, Omega_m, name='Tinker et al. (2010)', Dv=330., dc=1.686, verbose=True)
where:
z
is the redshiftOmega_m
is the cosmological matter density parameter (at $z=0$)name
is the name of the halo mass function/linear halo bias pair to useDv
is the halo overdensity definitiondc
is the linear collapse threshold
Currently supported name
choices are:
Press & Schecter (1974)
Sheth & Tormen (1999)
Sheth, Mo & Tormen (2001)
Tinker et al. (2010)
Despali et al. (2016)
When the model
instance is created the desired mass function is initialised.
To make a power-spectrum calculation one simply calls:
Pk_2h, Pk_1h, Pk_hm = model.power_spectrum(k, Pk_lin, M, sigmaM, profiles)
where:
k
is an array of comoving Fourier wavenumbers (units: $h\mathrm{Mpc}^{-1}$)Pk_lin
is an array of linear power spectrum values at a givenk
(units: $(h^{-1}\mathrm{Mpc})^3$)M
is an array of halo masses (units: $h^{-1}M_\odot$)sigmaM
is an array of root-variance linear density values at Lagrangian scales corresponding toM
profiles
is a dictionary of haloprofile
s (which could contain a single entry)
The function returns a tuple of Pk_2h
(two-halo), Pk_1h
(one-halo), and Pk_hm
(halo model) power at the chosen k
values. The power_spectrum
method computes all possible auto- and cross-spectra given the dictionary of halo profiles. For example, if three profiles were in the dictionary this would compute the three autospectra and the three unique cross spectra. The returned Pk
are then dictionaries containing all possible spectra. For example, if profiles={'a':profile_a, 'b':profile_b, 'c':profile_c}
then the Pk
dictionaries will contain the keys: a-a
; a-b
; a-c
; b-b
; b-c
, c-c
. It will also contain symmetric combinations (e.g., b-a
as well as a-b
) but the values will be identical. Each value in the Pk
dictionary is an array of the power at all k
.
Halo profiles are instances of the profile
class. These are initialised in Fourier space like:
profile = halo.profile.Fourier(k, M, Uk, amplitude=None, normalisation=1., variance=None, mass_tracer=False, discrete_tracer=False)
where
k
is an array of comoving Fourier wavenumbers (units: $h\mathrm{Mpc}^{-1}$)M
is an array of halo masses (units: $h^{-1}M_\odot$)Uk
is a 2D array of the Fourier halo profile at eachk
(first index) andM
(second index) valueamplitude
is an array of (mean) profile amplitudes, corresponding to eachM
normalisation
is a float containing the field normalisationvariance
is an array containing the variance in the profile amplitude at eachM
mass_tracer
is a boolean telling the code if the profile corresponds to mass densitydiscrete_tracer
is a boolean telling the code if it dealing with a discrete tracer or not
The arrays k
and M
be identical to those in the subsequent model.power_spectrum
call. If amplitude=None
the Fourier profile is assumed to be normalised such that $U(k\to0, M)$ gives the total contribution of the halo to the field. Otherwise the profile is renormalised by the amplitude
, and $U(k\to0, M)=1$ is assumed.
Some examples best illustrate how to create your own halo profiles:
matter_profile = halo.profile.Fourier(k, M, Uk_matter, amplitude=M, normalisation=rho_matter, mass_tracer=True)
would create a matter profile. Here Uk_matter
would be the normalised Fourier transform of a matter profile (e.g., an NFW profile), the amplitude of each profile is exactly M
(because the haloes are the mass), but the field normalisation is rho_matter
(which can be accessed via model.rhom
) because the field we are usually interested in is matter overdensity. We use mass_tracer=True
to tell the code that the profile corresponds to mass. Note that in this case we would get identical behaviour if we fixed the profile amplitude as amplitude=M/rho_matter
and the field normalisation as normalisation=1.
.
galaxy_profile = halo.profile.Fourier(k, M, Uk_galaxy, amplitude=N_galaxy, normalisation=rho_galaxy, variance=var_galaxy, discrete_tracer=True)
would create a galaxy profile. Here Uk_galaxy
would be the normalised Fourier transform of a galaxy profile (e.g., an isothermal profile). The amplitude of the profile is the mean galaxy-occupation number at each M
: N_galaxy
. The field is normalised by the mean galaxy density: rho_galaxy
. For a given assumption about the mean galaxy-occupation number and halo model this can be calculated using the average
method of the model
class:
rho_galaxy = hmod.average(M, sigmaM, N_galaxy)
The variance in galaxy number at each M
is var_galaxy
. If one is assuming Poisson statistics then variance=N_galaxy
is appropriate, but any value can be used in principle, including variance=None
, which ignores the contribution of tracer-occupation variance to the power. We tell the code that discrete_tracer=True
because in the discrete-tracer case it is essential to split the profile amplitude from the field normalisation if the discreteness of the tracer is to be accounted for properly.
Halo profiles can also be specified in configuration (real) space, via a function of radius from the halo centre. This is slower than specifying the Fourier profiles since the conversion of the profile to Fourier space will need to be performed internally.
halo.profile.configuration(k, M, rv, c, differential_profile, amplitude=None, normalisation=1., variance=None, mass_tracer=False, discrete_tracer=False):
the arguments are similar to those for Fourier-space profiles, except that
differential_profile
is a the halo profile multiplied by $4\pi r^2$ with call signaturedifferential_profile(r, M, rv, c)
rv
is the halo virial radius (units: $h^{-1}\mathrm{Mpc}$)c
is the halo concentration
the differential halo profile is the function defined such that integrating in radius between $0$ and $r_\mathrm{v}$ gives the total contribution of an individual halo to the field. It is usually the standard density profile multiplied $4\pi r^2$. This convention is used so as to avoid singularities that often occur in halo profiles at $r=0$. Again, some examples best illustrate how to use this
def differential_profile_matter(r, M, rv, c):
# This is NFW (1./((r/rs)*(1.+r/rs)**2)) multiplied by 4pir^2 with constant factors ignored
rs = rv/c
return r/(1.+r/rs)**2.
matter_profile = halo.profile.configuration(k, M, rv, c, differential_profile_matter, amplitude=M/rho_matter, mass_tracer=True)
note that because we specify the amplitude here we do not need to worry about constant factors in the differential_profile
definition, since the profile normalisation will be calculated self consistently. Note also that because we set amplitude=M/rho_matter
(matter overdensity) we can omit the normalisation
argument, which defaults to 1.
.
# Isothermal profile: 1/r^2, multiplied by 4pir^2 with constant factors ignored
differential_profile_gal = lambda r, M, rv, c: 1.
galaxy_profile = halo.profile.configuration(k, M, rv, c, differential_profile_gal, amplitude=N_galaxy, normalisation=rho_galaxy, discrete_tracer=True)
in the discrete tracer case it is important to split up normalisation
and amplitude
so that amplitude
is something that can be interpreted as the mean of a discrete probability distribution. In this example we have also decided to ignore the contribution of the variance in the number of galaxies at fixed halo mass to the eventual power spectrum calculation.
Note that the covariance in the mean profile amplitude between two different tracers is not currently supported. This can be important in halo-occupation models where galaxies are split into centrals and satellites and the presence of a satellite galaxy is conditional on the halo first containing a central galaxy. We hope to include this in future. Also any spatial variance or covariance in halo profiles at fixed mass is not currently supported; we have no plans to include this in future.
Notebooks
There are several jupyter
notebooks in the notebooks/
directory giving examples of how to use the code. The first one to try is demo-basic.ipynb
, which gives an overview of the main features of pyhalomodel
. As a bonus, we include notebooks that produce (almost) all of the plots from the review paper.
Citation
Please add a citation to Asgari, Mead & Heymans (2023) if you use this code.
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