Work in progress, commands are being added as the wrapper is used, therefore not all commands have been wrapped.
FEMM is a handy piece of software, although I felt its API is not as user-friendly as it could be. The motivation behind this light framework is to improve the usability of the FEMM API and also to add some additional features, such as hot reloading of the model definition to aid rapid model design and multiprocessing to speed up the running of the analysis stage when solving for many different models.
Currently the wrapper is designed to use the magnetics mode of FEMM (mi_ and mo_ prefixes). As further development
goes on the other three modes will be properly incorporated.
All command names are the same as shown in the FEMM manual with the
exception of correct Python naming. For example addnode becomes add_node.
This framework's API is not a one for one mapping of the FEMM API, I have made some design choices to make it easier to use and debug. The main difference is opting for the use of named arguments over position arguments. When using positional arguments I found myself consistently going back and forth between my FEMM code and the documentation. During the time I have spent using this framework I have has to do this far less often. The example below illustrates this:
# This is how to set a block's properties in pyFEMM.
femm.mi_setblockprop("my block name", 0, 10, "some circuit name", 0, "<None>", 100)
# This is how to set a block's properties using python-femm.
femm.set_block_prop(
block_name='my block name',
auto_mesh=False,
mesh_size=10,
in_circuit='some circuit name',
mag_direction=0,
# Notice if we want to set an argument to "<None>" we just don't
# give it a value here, i.e. I am choosing to leave out ``group``.
turns=100,
)In the example above we can see that, to use the FEMM API we need to remember not only the names of all the arguments but also their positions in the list of arguments. This framework's API relieves the user of having to remember the order of the arguments as named arguments do not depend on the order in which they are passed to the function. Also the code becomes self documenting to any other person looking over the code, they don't need to refer to the FEMM manual to find out what 4th positional argument of the function call is actually defining. An additional benefit of using named arguments is that code editors can provide code hints.
To define a model you must extend the BaseRunner class in a file called model.py (must be in the project
root directory). A model has five methods, two of which are defined already in BaseRunner, so you don't need to define them yourself unless
you need to. The other three will raise a NotImplementedError if they have not been defined and are called.
The pre method is responsible for drawing the model. This is also the method that is re-run when the model.py file changes
thanks to the hot reloader. The Runner class will have access to the FEMMSession via self.session.
Here's a quick example where a circle is drawn:
class Runner(BaseRunner):
def pre(self):
# Start a new document in magnetics mode. This will mean
# that all future commands will have 'm' prefixed to them
# when the FEMM script is run. This means we don't have to
# always write the 'mi_' or 'mo_' bits of each command.
self.session.new_document('magnetics')
# Define some geometry. Here ``self.session.pre`` is how we
# access all of the magnetics preprocessor commands. All methods
# run from ``self.session.pre`` will have 'i' prefixed to them.
self.session.pre.draw_circle(points=[[10, 10]])FEMM's way of defining points works but can be a little messy. In python-femm a standardised method of defining points is used.
Every command that requires positional information such as (x, y) or (x1, y1), (x2, y2) will accept a named parameter
called points. The structure of points is a "list of lists", i.e. points=[[1, 2], [3, 4]] would relate to x1 = 1, y1 = 2, x2 = 3 and y2 = 4. Note, this structure is still used for a single set of points, i.e. points=[[1, 2]] would
relate to x = 1 and y = 2. Defining points this way means that the same approach is used for every single command
that needs positional information, this enables to use of the patterning feature that will be mentioned later.
A more clear example is given below:
def pre(self):
# Define an arc from (0, 0) to (5, 5).
self.session.pre.draw_arc(points=[[0, 0], [5, 5]], angle=30, max_seg=1)
# Define a polygon which vertices at (0, 0), (1, 0), (1, 1) and (0, 1).
self.session.pre.draw_polygon(points=[[0, 0], [1, 0], [1, 1], [0, 1]])
# Define a node at (4, 4).
self.session.add_node(points=[[4, 5]])python-femm provides a very easy method of adding elements to groups as they are defined. You no longer need to draw an
element, select it, set it's group and then deselect it. You can just pass the group number when you define it like so:
def pre(self):
# Define an arc from (0, 0) to (5, 5) and set it to be in group 2.
self.session.pre.draw_arc(points=[[0, 0], [5, 5]], angle=30, max_seg=1, group=2)
# ^^^^^^^ We just define the group here.Much easier.
What is hot reloading then? Hot reloading is a development tool that makes incremental development much less
painful by listening to the model.py file for changes. When you make a change and save, python-femm will re-run the
pre method with the changes and update the FEMM model automatically. No more having to run commands after every change.
The solve method contains code that is pertinent to the analysis stage. A simple example illustrates this:
def solve(self):
# Analyse, zoom to fit and then load the solution.
self.session.pre.analyze()
self.session.pre.zoom_natural()
self.session.pre.load_solution()The post method contains code that tells python-femm how you want to use the FEMM postprocessor. Another simple
example explains this:
def post(self):
# Select a block by position and then run a block integral.
self.session.post.select_block(points=[[10, 10]])
value = self.session.post.block_integral(19) # Using an integral type of 19.
return valueIt should be reiterated that the pre, solve and post methods are all defined on the Runner class. I have combined
the examples above to illustrate what a complete model definition might look like:
class Runner(BaseRunner):
def pre(self):
# Define an arc from (0, 0) to (5, 5) and set it to be in group 2.
self.session.pre.draw_arc(points=[[0, 0], [5, 5]], group=2)
def solve(self):
# Analyse, zoom to fit and then load the solution.
self.session.pre.analyze()
self.session.pre.zoom_natural()
self.session.pre.load_solution()
def post(self):
# Select a block by position and then run a block integral.
self.session.post.select_block(points=[[10, 10]])
value = self.session.post.block_integral(19) # Using an integral type of 19.
return valueNote that you will not ever run these commands yourself, this brings us onto the management commands.
Once you have a valid (valid doesn't mean completed) model definition you can begin to use the management commands. There are several management commands that aid you in working with FEMM more effectively.
These commands are run from the terminal like so (the working directory must be the root of the project):
python manage.py <command_name>
There are five management commands:
-
pre: this will run thepremethod in the model definition once and wait until either FEMM closes or you pressCTRL + C. -
dev: this will run thepremethod with the hot reloader. Again, it will close when you pressCTRL + C. -
solve: this will run thepremethod and then thesolvemethod of your model definition. -
post: this will run thepremethod, thesolvemethod and then thepostmethod of your model definition. -
scene: (work in progress) this will run a scene where thepost(and all proceeding methods) will be run iteratively for a range of values. This will run each analysis concurrently providing a large speed up compared with running them sequentially.