Getting started
psipy is a package for loading and visualising the output of PSI’s MAS model runs. This page provides some narrative documentation that should get you up and running with obtaining, loading, and visualising some model results.
Getting data
The PSI MHDWeb pages give access to MAS model runs. The runs are indexed by Carrington rotation, and for each Carrington rotation there are generally a number of different runs, varying in the type model run and/or the boundary conditions.
To load data with psipy you need to manually download the files you are interested in to a directory on your computer.
MAS and PLUTO data
psipy supports data from both MAS model runs and PLUTO model runs.
For simplicity the instructions in this guide are written with MAS model output in mind.
Everything works the same way for PLUTO model output though - just load the files with the PLUTOOutput
class instead of the MASOutput
class.
The one feature that is not yet implemented for PLUTO data is field line tracing.
Loading data
psipy stores the output variables from a single MAS run in the MASOutput
object. To create one of these, specify the directory which has all of the
output .hdf
files you want to load:
from psipy.model import MASOutput
directory = '/path/to/files'
mas_output = MASOutput(directory)
It is assmumed that the files have the filename structure
'{var}{timestep}.hdf'
, where var
is a variable name, and timestep
is a three-digit zero-padded integer timestep.
To see which variables have been loaded, we can look at the .variables
attribute:
print(mas_output.variables)
This will print a list of the variables that have been loaded. Each individual variable can then be accessed with square brackets, for example to get the radial magnetic field component:
br = mas_output['br']
This will return a Variable
object, which stores the underlying data as a
xarray.DataArray
under the Variable.data
property.
Data coordinates
The data stored in Variable.data
contains the values of the data as a normal
array, and in addition stores the coordinates of each data point.
MAS model outputs are defined on a 3D grid of points on a spherical grid. The
coordinate names are 'r', 'theta', 'phi'
. The coordinate values along each
dimension can be accessed using the r_coords, theta_coords, phi_coords
properties, e.g.:
rvals = br.r_coords
Sampling data
Variable objects have a Variable.sample_at_coords
method, to take a sample of
the 3D data cube along a 1D trajectory. This is helpful for flying a ‘virtual
spacecraft’ through the model, in order to compare model results with in-situ
measurements.
sample_at_coords
requires arrays of longitude, latitude, and radial distance.
Given these coordinates, it uses linear interpolation to extract the values
of the variable at each of the coordinate points.
For an example of how all this works, see Comparing in-situ data to model output.