comment fixes

release
jan 8 years ago
parent 9198779974
commit efde4c4787

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# opencl_fdfd
**opencl_fdfd** is a 3D Finite Difference Frequency Domain (FDFD)
solver implemented in Python and OpenCL.
electromagnetic solver implemented in Python and OpenCL.
**Capabilities**
* Arbitrary distributions of the following:
* Dielectric constant (epsilon)
* Magnetic permeabilty (mu)
* Perfect electric conductor (PEC)
* Perfect magnetic conductor (PMC)
* Dielectric constant (```epsilon```)
* Magnetic permeabilty (```mu```)
* Perfect electric conductor (```PEC```)
* Perfect magnetic conductor (```PMC```)
* Variable-sized rectangular grids
* Stretched-coordinate PMLs (complex cell sizes allowed)
@ -16,13 +16,14 @@ Currently, only periodic boundary conditions are included.
PEC/PMC boundaries can be implemented by drawing PEC/PMC cells near the edges.
Bloch boundary conditions are not included but wouldn't be very hard to add.
The default solver (opencl_fdfd.cg_solver(...)) located in main.py implements
the E-field wave operator directly (ie, as a list of OpenCL instructions
rather than a matrix). Additionally, there is a slower (and slightly more
versatile) solver in csr.py which attempts to solve an arbitrary sparse
matrix in compressed sparse row (CSR) format using the same conjugate gradient
method as the default solver. The CSR solver is significantly slower, but can
be very useful for testing alternative formulations of the FDFD wave equation.
The default solver ```opencl_fdfd.cg_solver(...)``` located in main.py
implements the E-field wave operator directly (ie, as a list of OpenCL
instructions rather than a matrix). Additionally, there is a slower
(and slightly more versatile) solver in ```csr.py``` which attempts to solve
an arbitrary sparse matrix in compressed sparse row (CSR) format using
the same conjugate gradient method as the default solver. The CSR solver
is significantly slower, but can be very useful for testing alternative
formulations of the FDFD electromagnetic wave equation.
Currently, this solver only uses a single GPU or other OpenCL accelerator;
generalization to multiple GPUs should be pretty straightforward
@ -47,11 +48,12 @@ pip install git+https://mpxd.net/gogs/jan/opencl_fdfd.git@release
## Use
See the documentation for opencl_fdfd.cg_solver(...)
(located in main.py) for details about how to call the solver.
See the documentation for ```opencl_fdfd.cg_solver(...)```
(located in ```main.py```) for details about how to call the solver.
An alternate (slower) FDFD solver and a general gpu-based sparse matrix
solver is available in csr.py . These aren't particularly well-optimized,
and something like [MAGMA](http://icl.cs.utk.edu/magma/index.html) would
probably be a better choice if you absolutely need to solve arbitrary
sparse matrices and can tolerate writing and compiling C/C++ code.
solver is available in ```csr.py```. These aren't particularly
well-optimized, and something like
[MAGMA](http://icl.cs.utk.edu/magma/index.html) would probably be a
better choice if you absolutely need to solve arbitrary sparse matrices
and can tolerate writing and compiling C/C++ code.

@ -1,9 +1,10 @@
"""
opencl_fdfd OpenCL 3D FDFD solver
opencl_fdfd is a 3D Finite Difference Frequency Domain (FDFD) solver implemented in
Python and OpenCL. Its capabilities include:
opencl_fdfd is a 3D Finite Difference Frequency Domain (FDFD) electromagnetic
solver implemented in Python and OpenCL.
Its capabilities include:
- Arbitrary distributions of the following:
- Dielectric constant (epsilon)
- Magnetic permeabilty (mu)

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