csiborgtools/notebooks/plot_galaxy_distribution.ipynb
Richard Stiskalek 5dd8c668fa
Gaussian smoothing of density fields (#33)
* Simplify smoothing support and looping over nonzero

* Simplify comments

* add now()

* add cat length

* add smoothed calculation

* add smoothing

* Add sorting

* Edit what is ignored

* Move notebooks

* Add nonsymmetric smoothed overlap

* Update NB

* Add support for reading in the smoothed overlap

* Switch to the true overlap definition

* Reader of the true overlap

* rem occups

* Import moved to a class

* Move definition

* Edit submission script

* Update to account for the new definition

* backup nb

* Switch back to properly initialising arrays

* Fix addition bug

* Update NB

* Fix little bug

* Update nb
2023-03-27 09:22:03 +01:00

1.1 MiB

Using a calibrated flow model to predict $z_{\rm cosmo}$

In [5]:
# Copyright (C) 2024 Richard Stiskalek
# This program is free software; you can redistribute it and/or modify it
# under the terms of the GNU General Public License as published by the
# Free Software Foundation; either version 3 of the License, or (at your
# option) any later version.
#
# This program is distributed in the hope that it will be useful, but
# WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General
# Public License for more details.
#
# You should have received a copy of the GNU General Public License along
# with this program; if not, write to the Free Software Foundation, Inc.,
# 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301, USA.
import numpy as np
import matplotlib.pyplot as plt
from h5py import File
from tqdm import tqdm

import csiborgtools

%load_ext autoreload
%autoreload 2
%matplotlib inline

paths = csiborgtools.read.Paths(**csiborgtools.paths_glamdring)
The autoreload extension is already loaded. To reload it, use:
  %reload_ext autoreload
In [2]:
def load_calibration(catalogue, simname, nsim, ksmooth):
    fname = f"/mnt/extraspace/rstiskalek/csiborg_postprocessing/peculiar_velocity/flow_samples_{catalogue}_{simname}_smooth_{ksmooth}.hdf5"  # noqa
    keys = ["Vext_x", "Vext_y", "Vext_z", "alpha", "beta", "sigma_v"]

    # SN_keys = ['mag_cal', 'alpha_cal', 'beta_cal']
    # SN_keys = []
    calibration_samples = {}
    with File(fname, 'r') as f:
        for key in keys:
            calibration_samples[key] = f[f"sim_{nsim}/{key}"][:][::10]

        # for key in SN_keys:
        #     calibration_samples[key] = f[f"sim_{nsim}/{key}"][:]

    return calibration_samples

Test running a model

In [135]:
# fpath_data = "/mnt/extraspace/rstiskalek/catalogs/PV_compilation_Supranta2019.hdf5"
fpath_data = "/mnt/extraspace/rstiskalek/catalogs/PV_mock_CB2_17417_large.hdf5"

simname = "csiborg2_main"
catalogue = "CB2_large"

nsims = paths.get_ics(simname)[:-1]
ksmooth = 1

loaders = []
models = []
zcosmo_mean = None
zobs = None

for i, nsim in enumerate(tqdm(nsims)):
    loader = csiborgtools.flow.DataLoader(simname, i, catalogue, fpath_data, paths, ksmooth=ksmooth)
    calibration_samples = load_calibration(catalogue, simname, nsim, ksmooth)
    model = csiborgtools.flow.Observed2CosmologicalRedshift(calibration_samples, loader.rdist, loader._Omega_m)

    if i == 0:
        zcosmo_mean = loader.cat["zcosmo"]
        zobs = loader.cat["zobs"]
        vrad = loader.cat["vrad"]

    loaders.append(loader)
    models.append(model)
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10:32:19: reading the catalogue.
10:32:19: reading the interpolated field.
/mnt/users/rstiskalek/csiborgtools/csiborgtools/flow/flow_model.py:113: UserWarning: The number of radial steps is even. Skipping the first step at 0.0 because Simpson's rule requires an odd number of steps.
  warn(f"The number of radial steps is even. Skipping the first "
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10:32:25: calculating the radial velocity.

In [143]:
n = 400
zcosmo, pzcosmo = csiborgtools.flow.stack_pzosmo_over_realizations(
    n, models, loaders, "zobs")
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In [144]:
plt.figure()

# for i in range(len(nsims)):
    # mask = pzcosmo[i] > 1e-5
    # plt.plot(zcosmo[mask], pzcosmo[i][mask], color="black", alpha=0.1)

# mu = np.nanmean(pzcosmo, axis=0)
mask = pzcosmo > 1e-5
plt.plot(zcosmo[mask], pzcosmo[mask], color="black", label=r"$p(z_{\rm cosmo})$")

plt.ylim(0)
plt.axvline(zcosmo_mean[n], color="green", label=r"$z_{\rm cosmo}$")
plt.axvline(zobs[n], color="red", label=r"$z_{\rm CMB}$")

plt.xlabel(r"$z$")
plt.ylabel(r"$p(z)$")
plt.legend()
plt.tight_layout()
# plt.savefig("../plots/zcosmo_posterior_mock_example_B.png", dpi=450)
plt.show()
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In [ ]: