fdfd_tools/meanas/__init__.py

"""
Electromagnetic simulation tools

This package is intended for building simulation inputs, analyzing
simulation outputs, and running short simulations on unspecialized hardware.
It is designed to provide tooling and a baseline for other, high-performance
purpose- and hardware-specific solvers.


**Contents**
- Finite difference frequency domain (FDFD)
    * Library of sparse matrices for representing the electromagnetic wave
    equation in 3D, as well as auxiliary matrices for conversion between fields
    * Waveguide mode operators
    * Waveguide mode eigensolver
    * Stretched-coordinate PML boundaries (SCPML)
    * Functional versions of most operators
    * Anisotropic media (limited to diagonal elements eps_xx, eps_yy, eps_zz, mu_xx, ...)
    * Arbitrary distributions of perfect electric and magnetic conductors (PEC / PMC)
- Finite difference time domain (FDTD)
    * Basic Maxwell time-steps
    * Poynting vector and energy calculation
    * Convolutional PMLs

This package does *not* provide a fast matrix solver, though by default
```meanas.fdfd.solvers.generic(...)``` will call
```scipy.sparse.linalg.qmr(...)``` to perform a solve.
For 2D FDFD problems this should be fine; likewise, the waveguide mode
solver uses scipy's eigenvalue solver, with reasonable results.

For solving large (or 3D) FDFD problems, I recommend a GPU-based iterative
solver, such as [opencl_fdfd](https://mpxd.net/code/jan/opencl_fdfd) or
those included in [MAGMA](http://icl.cs.utk.edu/magma/index.html)). Your
solver will need the ability to solve complex symmetric (non-Hermitian)
linear systems, ideally with double precision.


Dependencies:
- numpy
- scipy

"""

import pathlib

from .types import dx_lists_t, field_t, vfield_t, field_updater
from .vectorization import vec, unvec

__author__ = 'Jan Petykiewicz'

with open(pathlib.Path(__file__).parent / 'VERSION', 'r') as f:
    __version__ = f.read().strip()
rename to meanas and split fdtd/fdfd 2019-08-04 13:48:41 -07:00			`"""`
			`Electromagnetic simulation tools`

			`This package is intended for building simulation inputs, analyzing`
			`simulation outputs, and running short simulations on unspecialized hardware.`
			`It is designed to provide tooling and a baseline for other, high-performance`
			`purpose- and hardware-specific solvers.`


			`Contents`
			`- Finite difference frequency domain (FDFD)`
			`* Library of sparse matrices for representing the electromagnetic wave`
			`equation in 3D, as well as auxiliary matrices for conversion between fields`
			`* Waveguide mode operators`
			`* Waveguide mode eigensolver`
			`* Stretched-coordinate PML boundaries (SCPML)`
			`* Functional versions of most operators`
			`* Anisotropic media (limited to diagonal elements eps_xx, eps_yy, eps_zz, mu_xx, ...)`
			`* Arbitrary distributions of perfect electric and magnetic conductors (PEC / PMC)`
			`- Finite difference time domain (FDTD)`
			`* Basic Maxwell time-steps`
			`* Poynting vector and energy calculation`
			`* Convolutional PMLs`

			`This package does not provide a fast matrix solver, though by default`
			```meanas.fdfd.solvers.generic(...)``` will call
			```scipy.sparse.linalg.qmr(...)``` to perform a solve.
			`For 2D FDFD problems this should be fine; likewise, the waveguide mode`
			`solver uses scipy's eigenvalue solver, with reasonable results.`

			`For solving large (or 3D) FDFD problems, I recommend a GPU-based iterative`
			`solver, such as [opencl_fdfd](https://mpxd.net/code/jan/opencl_fdfd) or`
			`those included in [MAGMA](http://icl.cs.utk.edu/magma/index.html)). Your`
			`solver will need the ability to solve complex symmetric (non-Hermitian)`
			`linear systems, ideally with double precision.`


			`Dependencies:`
			`- numpy`
			`- scipy`

			`"""`

Switch to file-based version number 2019-09-27 20:44:31 -07:00			`import pathlib`
Move version into setup.py and read it back with pkg_resources 2019-09-12 03:21:09 -07:00
rename to meanas and split fdtd/fdfd 2019-08-04 13:48:41 -07:00			`from .types import dx_lists_t, field_t, vfield_t, field_updater`
			`from .vectorization import vec, unvec`

			`__author__ = 'Jan Petykiewicz'`
Switch to file-based version number 2019-09-27 20:44:31 -07:00
			`with open(pathlib.Path(__file__).parent / 'VERSION', 'r') as f:`
			`__version__ = f.read().strip()`