GSEE: Global Solar Energy Estimator
GSEE is a solar energy simulation library designed for rapid calculations and ease of use. Renewables.ninja uses GSEE.
Requirements
Works only with Python 3. Required libraries:
Installation
Simply install with pip:
pip install gsee
The recommended way to install the required scientific libraries is to use the Anaconda Python distribution.
Known issue: If you do not already have numpy installed, you will get a compiler error when pip tries to build to climatedata_interface Cython extension.
Functionality
The following submodules are available:
-
brl_model: an implementation of the BRL model, a method to derive the diffuse fraction of irradiance, based on Ridley et al. (2010) -
climatedata_interface: an interface to use GSEE with annual, seasonal, monthly or daily data. See docs/climatedata_interface for details. -
pv: electric output from PV a panel -
trigon: functions to calculate irradiance on an inclined plane
A model can be imported like this: import gsee.pv
A plant simulation model implements a model class (e.g. PVPlant) with the relevant settings, and a run_model() function that take time series data (a pandas Series) and runs a default instance of the model class, but can also take a model argument to specify a custom-configured model instance.
Examples
Power output from a PV system with fixed panels
In this example, data must be a pandas.DataFrame with columns global_horizontal (in W/m2), diffuse_fraction, and optionally a temperature column for ambient air temperature (in degrees Celsius).
result = gsee.pv.run_model(
data,
coords=(22.78, 5.51), # Latitude and longitude
tilt=30, # 30 degrees tilt angle
azim=180, # facing towards equator,
tracking=0, # fixed - no tracking
capacity=1000, # 1000 W
)Aperture irradiance on a panel with 2-axis tracking
location = (22.78, 5.51)
plane_irradiance = gsee.trigon.aperture_irradiance(
data['direct_horizontal'], data['diffuse_horizontal'],
location, tracking=2
)Climate data Interface
Example use directly reading NetCDF files with GHI, diffuse irradiance fraction, and temperature data:
from gsee.climatedata_interface.interface import run_interface
run_interface(
ghi_data=('ghi_input.nc', 'ghi'), # Tuple of (input file path, variable name)
diffuse_data=('diffuse_fraction_input.nc', 'diff_frac'),
temp_data=('temperature_input.nc', 't2m'),
outfile='output_file.nc',
params=dict(tilt=35, azim=180, tracking=0, capacity=1000),
frequency='detect'
)Tilt can be given as a latitude-dependent function instead of static value:
params = dict(tilt=lambda lat: 0.35396 * lat + 16.84775, ...)Instead of letting the climate data interface read and prepare data from NetCDF files, an xarray.Dataset can also be passed directly (e.g. when using the module in combination with a larger application):
from gsee.climatedata_interface.interface import run_interface_from_dataset
result = run_interface_from_dataset(
data=my_dataset, # my_dataset is an xarray.Dataset
params=dict(tilt=35, azim=180, tracking=0, capacity=1000)
)By default, a built-in file with monthly probability density functions is automatically downloaded and used to generate synthetic daily irradiance.
For more information, see the climate data interface documentation.
Development
To install the latest development version directly from GitHub:
pip install -e git+https://github.com/renewables-ninja/gsee.git#egg=gsee
To build the climatedata_interface submodule Cython >= 0.28.5 is required.
Credits and contact
Contact Stefan Pfenninger for questions about GSEE. GSEE is also a component of the Renewables.ninja project, developed by Stefan Pfenninger and Iain Staffell. Use the contact page there if you want more information about Renewables.ninja.
Citation
If you use GSEE or code derived from it in academic work, please cite:
Stefan Pfenninger and Iain Staffell (2016). Long-term patterns of European PV output using 30 years of validated hourly reanalysis and satellite data. Energy 114, pp. 1251-1265. doi: 10.1016/j.energy.2016.08.060
License
BSD-3-Clause
