Python interface for gluing together several HEP programs (e.g. from HEPForge https://www.hepforge.org/).
Stable | Unstable |
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The goal of this project is to provide a simple and easy to use interface to common high-energy-physics tools (currently mainly SUSY related Tools). Parameter scans and plotting is also included. Different tools should just be plugged in and out as desired (i.e. generate a SUSY spectrum before running a scan with MadGraph).
First generate a list of interested parameter points i.e. mass 100 to 1000 GeV squark. Then if you also want to scan over the gluino mass just ask for a scan over previous list, and you get a 2d scan. After generating all parameters they can be used to directly run the codes (in parallel or sequential) or just generate the input file for distribution across several clusters. The results then can be imported again and plotted nicely.
In the working directory you have an input
and output
folder. The input would typically contain the baseline slha file.
The output
will contain the produced scripts to execute the tools.
To avoid file collisions the files in the output folder correspond to a hashed value of all input parameters.
If a result already exists hepi won't rerun the tool.
For more details on the usage of different tools, called runners, check the respective documentation.
pip install hepi[opt] [--user] [--upgrade]
pip install --index-url https://test.pypi.org/simple/ hepi[opt]
[opt]
can be omitted to avoid optional dependencies (ie. lhapdf).
HEPi-fast interpolates grids in a similar fashion to (n)nll-fast but also for Resummino.
They are given as json files as for the CERN SUSY wiki in xsec.
A default set of grids is in the source folder hepi/data/json/
.
HEPi can be used to generate such json files for convenient reloading of the data.
Just enter a mass point and the cross sections are returned:
$ hepi-fast --help
[...]
$ hepi-fast 13600_sleptons_1000011_-1000011_NNLL.json
547
0 547.0 0.0003595877111213834 2.524930051307783e-05 -2.520906052972218e-05 1.7378151961260709e-06 -9.940418204744763e-07 2.5189449167488203e-05 -2.5189449167488203e-05
988
0 988.0 1.431846191827644e-05 2.44205862446039e-06 -2.4413596449724868e-06 6.14033144355307e-08 -2.0494188119845572e-08 2.4412735921747426e-06 -2.4412735921747426e-06
547
0 547.0 0.00035958771606265744 -2.5249300930888148e-05 2.5209060862746587e-05 -1.737815390324732e-06 9.940418677810902e-07 -2.5189449417355387e-05 2.5189449417355387e-05
988
0 988.0 1.4318461918225316e-05 -2.4420586244508355e-06 2.441359644963803e-06 -6.140331443352323e-08 2.0494188119359375e-08 -2.4412735921671295e-06 2.4412735921671295e-06
[...]
Above shows slepton-pair cross section for requested 547 and 988 GeV mass at aNNLO+NNLL. The order of the output is
ID | Central value | error up | error down | error scale up | error scale down | error pdf up | error pdf down
If you just want to look at a quick plot of the interpolation run
$ hepi-fast pp13_squark_NNLO+NNLL.json --plot
for something like