Jammy2211/PyAutoLens: 2021.10.10.21

Note on backwards compatibility The unique identifers of certain lens model will change as a result of this release, meaning that backwards compatibility may not be possible. We have a tool which updates the identifiers to this version such that existing results can be updated and retained, please contact me on SLACK if this is necessary. Function Renames Many core functions have been renamed for conciseness, for example: deflections_2d_from_grid -> deflections_2d_from convergence_2d_from_grid -> convergence_2d_from This should not impact general use and the workspace has been updated with new templates using these functions. Double Source Plane Lens Inversions Reconstruction of multiple strong lensed sources at different redshifts (e.g. double Einstein ring systems) is now supported, including full model-fitting pipelines. The API for this is a natural extension of the existing API whereby multiple sources are allocated a Pixelization and Regularization: lens = af.Model( al.Galaxy, redshift=0.5, bulge=af.Model(al.lp.EllSersic), mass=af.Model(al.mp.EllIsothermal) ) source_0 = af.Model( al.Galaxy, redshift=1.0, mass=al.mp.SphericalIsothermal, pixelization=al.pix.VoronoiMagnification, regularization=al.reg.Constant, ) source_1 = af.Model( al.Galaxy, redshift=2.0, pixelization=al.pix.VoronoiMagnification, regularization=al.reg.Constant, ) model = af.Collection(galaxies=af.Collection(lens=lens, source_0=source_0, source_1=source_1)) The following workspace examples demonstrate double source modeling and visualization further: ? Signal To Noise Light Profile Simulations A class of signal-to-noise based light profiles, accessible via the command al.lp_snr, are now available. When used to simulate strtong lens imaging, these light profiles automatically adjust their intensity parameter based on the noise properties simulation to give the desired signal to noise ratio: bulge=al.lp_snr.EllSersic( signal_to_noise_ratio=50.0, centre=(0.0, 0.0), elliptical_comps=al.convert.elliptical_comps_from(axis_ratio=0.9, angle=45.0), effective_radius=0.6, sersic_index=3.0, ), When combined with a Tracer the signal to noise of the light profile's image is adjusted based on the ray-traced image, thus it fully accounts for magnification when setting the signal to noise. A full description of this feature can be found at this link: ? W-Tilde Inversion Imaging Formalism All Imaging Inversion analysis uses a new formalism for the linear algebra, which provides numerically equivalent results to the previous formalism (which is still implemented and used in certain scenarions). The W-tilde formalism provides a > x3 speed up on high resolution imaging datasets. For example, for HST images with a pixel scale of 0.05" and a circular mask of 3.5", this formalism speeds up the overall run-time of a fit (e.g. one evaluation of the log likelihood function) from 4.8 seconds to 1.55 seconds. For higher resolution data or bigger masks an even more significant speed up is provided. Users so not need to do anything to activate this formalism, it is now the default method used when an inversion is performed. Implicit Preloading Imaging and Interferometer analysis now use implicit preloading, whereby before a model-fit the model is inspected and preloadsare automatically generated for the parts aspects of the model-fit which do not change between each lens model. Previously, these would have been recomputed for every model fit, making the log likelihood evaluation time longer than necessary. Example quantities which are stored via implicit preloading are: If the light profiles of all galaxies are fixed, their corresponding blurred image-plane image is preloaded and reused for every lens model fit. If the mass profiles of all galaxies are fixed, the deflection angles and ray-tracing do not change. Preloading is used to avoid repeated computation. Numerous aspects of the linear algebra of an inversion can be preloaded depending on which parts of the model do or do not vary. This will provide significantl speed up for certain lens model fits.