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Tools for performing common tasks on solar PV data signals. These tasks include finding clear days in a data set, common data transforms, and fixing time stamp issues. These tools are designed to be automatic and require little if any input from the user. Libraries are included to help with data IO and plotting as well.
There is close integration between this repository and the Statistical Clear Sky repository, which provides a "clear sky model" of system output, given only measured power as an input.
See notebooks folder for examples.
We recommend setting up a fresh Python virtual environment in which to use solar-data-tools. We recommend using the Conda package management system, and creating an environment with the environment configuration file named pvi-user.yml, provided in the top level of this repository. This will install the statistical-clear-sky package as well.
Creating the env:
$ conda env create -f pvi-user.ymlStarting the env:
$ conda activate pvi_userStopping the env
$ conda deactivateUpdating the env with latest
$ conda env update -f pvi-user.ymlAdditional documentation on setting up the Conda environment is available here.
$ pip install solar-data-toolsAlternative: Clone repo from GitHub
Mimic the pip package by setting up locally.
$ pip install -e path/to/root/folder$ conda install -c slacgismo solar-data-toolsBy default, QSS and OSQP solvers are used for non-convex and convex problems, respectively. Both are supported by OSD, the modeling language used to solve signal decomposition problems in Solar Data Tools, and both are open source.
MOSEK is a commercial software package. It is more stable and offers faster solve times. The included YAML/requirements.txt file will install MOSEK for you, but you will still need to obtain a license. More information is available here:
Users will primarily interact with this software through the DataHandler class. If you would like to specify a solver, just pass the keyword argument solver to dh.pipeline with the solver of choice. Passing QSS will keep the convex problems solver as OSQP, unless solver_convex=QSS is passed as well. Setting solver=MOSEK will set the solver to MOSEK for convex and non-convex problems by default.
from solardatatools import DataHandler
from solardatatools.dataio import get_pvdaq_data
pv_system_data = get_pvdaq_data(sysid=35, api_key='DEMO_KEY', year=[2011, 2012, 2013])
dh = DataHandler(pv_system_data)
dh.run_pipeline(power_col='dc_power')If everything is working correctly, you should see something like the following
total time: 24.27 seconds
--------------------------------
Breakdown
--------------------------------
Preprocessing 11.14s
Cleaning 0.94s
Filtering/Summarizing 12.19s
Data quality 0.25s
Clear day detect 1.75s
Clipping detect 7.77s
Capacity change detect 2.42s
Must enable pre-commit hook before pushing any contributions
pip install pre-commit
pre-commit install
Run pre-commit hook on all files
pre-commit run --all-files
In order to view the current test coverage metrics, run:
coverage run --source solardatatools -m unittest discover && coverage html
open htmlcov/index.html
We use Semantic Versioning for versioning. For the versions available, see the tags on this repository.
- Bennet Meyers - Initial work and Main research work - Bennet Meyers GitHub
See also the list of contributors who participated in this project.
This project is licensed under the BSD 2-Clause License - see the LICENSE file for details