This repo is a fork of the Sandia PVLIB_Python project.
It provides a set of sometimes-well-documented and usually correct functions for simulating the performance of photovoltaic energy systems. The toolbox was originally developed at Sandia National Laboratories and it implements many of the models and methods developed at the Labs.
We make some contributions to the Sandia develop branch, and we pull some commits back into our fork. We hope that the Sandia PVLIB_Python becomes the community standard, but we had some different ideas about how things should be done and we needed to make progress faster than the collaborative cycle would allow. See below for a partial list of differences.
We use this library to generate solar power forecasts for TEP, APS, and other SVERI utilities, and to perform grid integration and variability studies for SVERI. For more information, see https://forecasting.uaren.org and https://sveri.uaren.org.
The primary drawback to using this library over the official library is that, well, it's not the official Sandia library. Another drawback is that the structure of this library will look a lot different to people coming from the MATLAB world, which is either a good thing or a bad thing depending on your perspective. Keep the following in mind as you consider using or developing our fork:
- We hope to keep the projects as similar as possible to make it easier for people to experiment with our fork.
- The Sandia repo should be the default repo for the user community.
- Developers should strongly consider working on the official Sandia repo rather than, or in addition to, our fork.
- Reread the above point (...waiting...) before the following (...waiting again...): community contributions in the form of PRs, issues, wikis, docs, tutorials, thoughts, etc are all welcomed and we will try hard to address them in a timely manner.
- All code contributions must be documented, PEP8 compliant, and python 3 compatible.
- We're not promising to maintain this repo for any length of time.
That being said, we welcome your thoughts and contributions to our fork.
Here are some of the major differences between our fork and the official project. Note that some of these differences have been resolved in the Sandia develop branch.
- Remove pvl_ from module names.
- Locations are now
pvlib.location.Location
objects, not structs. - Return one DataFrame instead of a tuple of DataFrames.
- Specify time zones using a string from the standard IANA Time Zone Database naming conventions or using a pytz.timezone instead of an integer GMT offset. We may add dateutils support in the future.
- Add PyEphem option to solar position calculations.
- Consolidation of similar modules. For example, functions from
pvl_clearsky_ineichen.py
andpvl_clearsky_haurwitz.py
have been consolidated intoclearsky.py
. Similar consolidations have occured for airmass, solar position, and diffuse irradiance modules. irradiance.py
has more AOI, projection, and irradiance sum and calculation functions- Removing Vars=Locals(); Expect...; var=pvl_tools.Parse(Vars,Expect); pattern. Very few tests of input validitity remain. Garbage in, garbage out.
- Removing unnecssary and sometimes undesired behavior such as setting maximum zenith=90 or airmass=0.
__init__.py
imports have been removed.- Adding logging calls, removing print calls.
- Code in reviewed modules is mostly PEP8 compliant.
- Code in reviewed modules is mostly python 3 compatible.
- Changing function and module names so that they do not conflict.
- Not bothering with boilerplate unit test code such as
unittest.main()
. - No wildcard imports.
- Improved documentation here and there.
- TMY data is not forced to 1987.
- Azimuth is defined such that North=0.
- Documentation source code and tutorials live in
/
rather than/pvlib/docs
. - Added
/pvlib/data
for lookup tables, test, and tutorial data. - Tests are cleaner and more thorough. They are still no where near complete.
Pythonic code is easier to use, easier to maintain, and faster to develop. Adhering to PEP8 guidelines allows other python developers read code more quickly and accurately.
Hopefully you're using virtualenv and virtualenvwrapper. To install, clone this library and run
pip install .
Add -e
to install in develop mode.
# built-in imports
import sys
import datetime
# add-on imports
import pandas as pd
# pvlib imports
from pvlib.location import Location
import pvlib.solarposition
import pvlib.clearsky
# make a location
tus = Location(32.2, -111, 'MST', 700)
# make a pandas DatetimeIndex for some day
times = pd.date_range(start=datetime.datetime(2014,6,24), end=datetime.datetime(2014,6,25), freq='1Min')
# calculate the solar position
solpos = pvlib.solarposition.get_solarposition(times, tus, method='pyephem')
solpos.plot()
# calculate clear sky data
tus_cs = pvlib.clearsky.ineichen(times, tus, airmass_model='young1994')
tus_cs.plot()
Until the code is tested more thoroughly, you might find it useful to add:
import logging
logging.getLogger('pvlib').setLevel(logging.DEBUG)
Testing can be accomplished by running nosetests on the pvlib directory (or pvlib/tests):
nosetests -v pvlib
Unit test code should be placed in the pvlib/test
directory. Each module should have its own test module.