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Code description

drphilmarshall edited this page Mar 22, 2013 · 11 revisions

Configuration

Define your experiment in a file called .config so the code knows what you want it to do. A commented example is given here.

Scripts

From an input catalog of galaxies (either real or simulated), drill out a narrow lightcone (or set of lightcones) centred on some sky position of interest, and save the resulting smaller catalog (or catalogs).

Read in a lightcone catalog (or set of catalogs), and assign dark matter mass to the galaxies within, probabilistically. Each lightcone yields its own Pr(kappah|D), where kappah is the total gravitational lensing convergence at the centre of the lightcone - this quantity is of great relevance to the strong lens time delay distance in particular.

kappah is (at the moment) a fairly crude approximation to the "true" convergence kappa - but we have shown that one can recover a better approximation by considering Pr(kappah,kappa|C), where C is large set of lightcone catalogs drawn from a cosmological simulation. The resulting PDF Pr(kappah|D,C) contains the assumption that this simulation is an accurate representation of our real Universe - but we're working towards relaxing this.

Classes

The primary "lightcone" class defines a volume of space, containing galaxies and their properties. A lightcone is instantiated from an input catalog, and returns (among other things) estimates of lensing convergence given various assumptions.

The "kappamap" class allows convergence maps, like those obtained by Hilbert et al from full-on ray-tracing through the Millennium Simulation, to be loaded and queried by position - this provides "truth" at each sky position for calibration purposes.

For calculating cosmologically useful quantities, such as distances of various kinds. Written by Matt Auger.

Creates a scaffolding of redshift slices, in which useful quantities are pre-calculated. Lightcone objects are then "snapped" to this grid to speed up the lensing calculations.

A place to store probability density functions - including samples drawn from them.

The stellar mass to halo mass relation. The one from Behroozi et al requires a numerical look-up table - the SHMR class provides a place to store this.

Function libraries

The other files in pangloss contain useful functions.

LensingProfiles.py contains functions needed to calculate the convergence and shear caused by various halo profiles.

Relations.py contains the neto and maccio halo mass to concentration relation and the behroozi stellar mass to halo mass relation.

LensingFunc.py contains functions to calculate the lensing scale factor, beta, and critical density, sigma_crit. # I think this is obsolete and never used. TC