Resampling tools for openPMD
PIC data
We often need to post-process the particle data from a PIC simulation, and pass it to additional tracking codes like GEANT
, GPT
, SIMION
or Wake-T
. The original dataset can correspond to several billion particles, so one needs to reduce it to a manageable size, while conserving the main features of the underlying physics. This repository implements several resampling methods from the literature [2], as well as a comprehensive suite of high-resolution visualization tools, based on Datashader.
We make use of the excellent pixi package manager, which can be installed on Linux/macOS via
$ curl -fsSL https://pixi.sh/install.sh | bash
One can then clone this repo via
$ git clone [email protected]:berceanu/openPMD-resampler.git
For an overview of the main functionality, see the usage.py
example script and its output.
For production runs, use
$ cd openPMD-resampler
$ pixi run start --opmd_path <path_to_your_openPMD_file> --species <electron_species_name> --reduction_factor <k>
Replace descriptions between chevrons <>
by relevant values, in this case the
path to the PIC output file, name of the electron species (e_all
or
e_highGamma
etc.) and an integer reduction factor k
, typically between 2 and ~100.
If the initial PIC file has N
macroparticles, the resulting reduced file will have N/k
macroparticles.
If you need a sample PIC output file for testing, you can download lwfa.h5 [212M].
The code works with openPMD
-compatible PIC codes, such as WarpX
, PIConGPU
, fbpic
, etc.
The runtime is typically a few minutes and the memory footprint is about twice the size of the input file.
The output is a CSV text file, of the following form:
position_x_um (μm), position_y_um (μm), position_z_um (μm), momentum_x_mev_c (MeV/c), momentum_y_mev_c (MeV/c), momentum_z_mev_c (MeV/c)
1.1201412540356980e+01,8.0062201241442832e-01,3.9551004545608885e+03,-9.1752357482910156e+00,-1.4616233825683594e+01,2.9899465942382812e+02
...
All project dependencies are listed under pixi.toml
.
Just create a fork, follow the install instructions and start making PRs.
For a computational estimate, here is a quote from Ref. [1]:
The computer system for
GEANT4
simulation is made up of Intel Quad-core 2.66 GHz CPU and 12 GB DDR3 RAM and OS is Ubuntu 9.04 server version. It took about 3~4 hours to simulate with$10^7$ primary particles.
[1] Park, Seong Hee, et al. "A simulation for the optimization of bremsstrahlung radiation for nuclear applications using laser accelerated electron beam." Proceedings of FEL2010, Malmö, 2010. PDF
[2] Muraviev, A. et al. "Strategies for particle resampling in PIC simulations." Comput. Phys. Commun. 262, 107826 (2021). DOI
[3] Shimazaki, Hideaki, and Shigeru Shinomoto. "A method for selecting the bin size of a time histogram." Neural computation 19.6, 1503 (2007). DOI
We would like to acknowledge useful discussions with Richard Pausch (HZDR).