pvlib.modelchain.ModelChain¶

class pvlib.modelchain.ModelChain(system, location, orientation_strategy=None, clearsky_model='ineichen', transposition_model='haydavies', solar_position_method='nrel_numpy', airmass_model='kastenyoung1989', dc_model=None, ac_model=None, aoi_model=None, spectral_model=None, temperature_model=None, losses_model='no_loss', name=None, **kwargs)[source]¶

The ModelChain class to provides a standardized, high-level interface for all of the modeling steps necessary for calculating PV power from a time series of weather inputs.

See https://pvlib-python.readthedocs.io/en/stable/modelchain.html for examples.

Parameters:

system (PVSystem) – A PVSystem object that represents the connected set of modules, inverters, etc.
location (Location) – A Location object that represents the physical location at which to evaluate the model.
orientation_strategy (None or str, default None) – The strategy for aligning the modules. If not None, sets the surface_azimuth and surface_tilt properties of the system. Allowed strategies include ‘flat’, ‘south_at_latitude_tilt’. Ignored for SingleAxisTracker systems.
clearsky_model (str, default 'ineichen') – Passed to location.get_clearsky.
transposition_model (str, default 'haydavies') – Passed to system.get_irradiance.
solar_position_method (str, default 'nrel_numpy') – Passed to location.get_solarposition.
airmass_model (str, default 'kastenyoung1989') – Passed to location.get_airmass.
dc_model (None, str, or function, default None) – If None, the model will be inferred from the contents of system.module_parameters. Valid strings are ‘sapm’, ‘desoto’, ‘cec’, ‘pvsyst’, ‘pvwatts’. The ModelChain instance will be passed as the first argument to a user-defined function.
ac_model (None, str, or function, default None) – If None, the model will be inferred from the contents of system.inverter_parameters and system.module_parameters. Valid strings are ‘snlinverter’, ‘adrinverter’, ‘pvwatts’. The ModelChain instance will be passed as the first argument to a user-defined function.
aoi_model (None, str, or function, default None) – If None, the model will be inferred from the contents of system.module_parameters. Valid strings are ‘physical’, ‘ashrae’, ‘sapm’, ‘martin_ruiz’, ‘no_loss’. The ModelChain instance will be passed as the first argument to a user-defined function.
spectral_model (None, str, or function, default None) – If None, the model will be inferred from the contents of system.module_parameters. Valid strings are ‘sapm’, ‘first_solar’, ‘no_loss’. The ModelChain instance will be passed as the first argument to a user-defined function.
temperature_model (None, str or function, default None) – Valid strings are ‘sapm’, ‘pvsyst’, and ‘faiman’. The ModelChain instance will be passed as the first argument to a user-defined function.
losses_model (str or function, default 'no_loss') – Valid strings are ‘pvwatts’, ‘no_loss’. The ModelChain instance will be passed as the first argument to a user-defined function.
name (None or str, default None) – Name of ModelChain instance.
**kwargs – Arbitrary keyword arguments. Included for compatibility, but not used.

__init__(system, location, orientation_strategy=None, clearsky_model='ineichen', transposition_model='haydavies', solar_position_method='nrel_numpy', airmass_model='kastenyoung1989', dc_model=None, ac_model=None, aoi_model=None, spectral_model=None, temperature_model=None, losses_model='no_loss', name=None, **kwargs)[source]¶: Initialize self. See help(type(self)) for accurate signature.

Methods

`__init__`(system, location[, …])	Initialize self.
`adrinverter`()
`ashrae_aoi_loss`()
`cec`()
`complete_irradiance`(weather[, times])	Determine the missing irradiation columns.
`desoto`()
`effective_irradiance_model`()
`faiman_temp`()
`first_solar_spectral_loss`()
`infer_ac_model`()
`infer_aoi_model`()
`infer_dc_model`()
`infer_losses_model`()
`infer_spectral_model`()
`infer_temperature_model`()
`martin_ruiz_aoi_loss`()
`no_aoi_loss`()
`no_extra_losses`()
`no_spectral_loss`()
`physical_aoi_loss`()
`prepare_inputs`(weather[, times])	Prepare the solar position, irradiance, and weather inputs to the model.
`pvsyst`()
`pvsyst_temp`()
`pvwatts_dc`()
`pvwatts_inverter`()
`pvwatts_losses`()
`run_model`(weather[, times])	Run the model.
`sapm`()
`sapm_aoi_loss`()
`sapm_spectral_loss`()
`sapm_temp`()
`snlinverter`()

Attributes

`ac_model`
`aoi_model`
`dc_model`
`losses_model`
`orientation_strategy`
`spectral_model`
`temperature_model`