Source code for pvlib.pvsystem

"""
The ``pvsystem`` module contains functions for modeling the output and
performance of PV modules and inverters.
"""

from collections import OrderedDict
import functools
import io
import itertools
import os
from urllib.request import urlopen
import numpy as np
import pandas as pd
from dataclasses import dataclass
from abc import ABC, abstractmethod
from typing import Optional

from pvlib._deprecation import deprecated

from pvlib import (atmosphere, iam, inverter, irradiance,
                   singlediode as _singlediode, temperature)
from pvlib.tools import _build_kwargs, _build_args


# a dict of required parameter names for each DC power model
_DC_MODEL_PARAMS = {
    'sapm': {
        'A0', 'A1', 'A2', 'A3', 'A4', 'B0', 'B1', 'B2', 'B3',
        'B4', 'B5', 'C0', 'C1', 'C2', 'C3', 'C4', 'C5', 'C6',
        'C7', 'Isco', 'Impo', 'Voco', 'Vmpo', 'Aisc', 'Aimp', 'Bvoco',
        'Mbvoc', 'Bvmpo', 'Mbvmp', 'N', 'Cells_in_Series',
        'IXO', 'IXXO', 'FD'},
    'desoto': {
        'alpha_sc', 'a_ref', 'I_L_ref', 'I_o_ref',
        'R_sh_ref', 'R_s'},
    'cec': {
        'alpha_sc', 'a_ref', 'I_L_ref', 'I_o_ref',
        'R_sh_ref', 'R_s', 'Adjust'},
    'pvsyst': {
        'gamma_ref', 'mu_gamma', 'I_L_ref', 'I_o_ref',
        'R_sh_ref', 'R_sh_0', 'R_s', 'alpha_sc', 'EgRef',
        'cells_in_series'},
    'singlediode': {
        'alpha_sc', 'a_ref', 'I_L_ref', 'I_o_ref',
        'R_sh_ref', 'R_s'},
    'pvwatts': {'pdc0', 'gamma_pdc'}
}


def _unwrap_single_value(func):
    """Decorator for functions that return iterables.

    If the length of the iterable returned by `func` is 1, then
    the single member of the iterable is returned. If the length is
    greater than 1, then entire iterable is returned.

    Adds 'unwrap' as a keyword argument that can be set to False
    to force the return value to be a tuple, regardless of its length.
    """
    @functools.wraps(func)
    def f(*args, **kwargs):
        unwrap = kwargs.pop('unwrap', True)
        x = func(*args, **kwargs)
        if unwrap and len(x) == 1:
            return x[0]
        return x
    return f


def _check_deprecated_passthrough(func):
    """
    Decorator to warn or error when getting and setting the "pass-through"
    PVSystem properties that have been moved to Array.  Emits a warning for
    PVSystems with only one Array and raises an error for PVSystems with
    more than one Array.
    """

    @functools.wraps(func)
    def wrapper(self, *args, **kwargs):
        pvsystem_attr = func.__name__
        class_name = self.__class__.__name__  # PVSystem or SingleAxisTracker
        overrides = {  # some Array attrs aren't the same as PVSystem
            'strings_per_inverter': 'strings',
        }
        array_attr = overrides.get(pvsystem_attr, pvsystem_attr)
        alternative = f'{class_name}.arrays[i].{array_attr}'

        if len(self.arrays) > 1:
            raise AttributeError(
                f'{class_name}.{pvsystem_attr} not supported for multi-array '
                f'systems. Set {array_attr} for each Array in '
                f'{class_name}.arrays instead.')

        wrapped = deprecated('0.9', alternative=alternative, removal='0.10',
                             name=f"{class_name}.{pvsystem_attr}")(func)
        return wrapped(self, *args, **kwargs)

    return wrapper


# not sure if this belongs in the pvsystem module.
# maybe something more like core.py? It may eventually grow to
# import a lot more functionality from other modules.
[docs]class PVSystem: """ The PVSystem class defines a standard set of PV system attributes and modeling functions. This class describes the collection and interactions of PV system components rather than an installed system on the ground. It is typically used in combination with :py:class:`~pvlib.location.Location` and :py:class:`~pvlib.modelchain.ModelChain` objects. The class supports basic system topologies consisting of: * `N` total modules arranged in series (`modules_per_string=N`, `strings_per_inverter=1`). * `M` total modules arranged in parallel (`modules_per_string=1`, `strings_per_inverter=M`). * `NxM` total modules arranged in `M` strings of `N` modules each (`modules_per_string=N`, `strings_per_inverter=M`). The class is complementary to the module-level functions. The attributes should generally be things that don't change about the system, such the type of module and the inverter. The instance methods accept arguments for things that do change, such as irradiance and temperature. Parameters ---------- arrays : iterable of Array, optional List of arrays that are part of the system. If not specified a single array is created from the other parameters (e.g. `surface_tilt`, `surface_azimuth`). Must contain at least one Array, if length of arrays is 0 a ValueError is raised. If `arrays` is specified the following parameters are ignored: - `surface_tilt` - `surface_azimuth` - `albedo` - `surface_type` - `module` - `module_type` - `module_parameters` - `temperature_model_parameters` - `modules_per_string` - `strings_per_inverter` surface_tilt: float or array-like, default 0 Surface tilt angles in decimal degrees. The tilt angle is defined as degrees from horizontal (e.g. surface facing up = 0, surface facing horizon = 90) surface_azimuth: float or array-like, default 180 Azimuth angle of the module surface. North=0, East=90, South=180, West=270. albedo : None or float, default None The ground albedo. If ``None``, will attempt to use ``surface_type`` and ``irradiance.SURFACE_ALBEDOS`` to lookup albedo. surface_type : None or string, default None The ground surface type. See ``irradiance.SURFACE_ALBEDOS`` for valid values. module : None or string, default None The model name of the modules. May be used to look up the module_parameters dictionary via some other method. module_type : None or string, default 'glass_polymer' Describes the module's construction. Valid strings are 'glass_polymer' and 'glass_glass'. Used for cell and module temperature calculations. module_parameters : None, dict or Series, default None Module parameters as defined by the SAPM, CEC, or other. temperature_model_parameters : None, dict or Series, default None. Temperature model parameters as required by one of the models in pvlib.temperature (excluding poa_global, temp_air and wind_speed). modules_per_string: int or float, default 1 See system topology discussion above. strings_per_inverter: int or float, default 1 See system topology discussion above. inverter : None or string, default None The model name of the inverters. May be used to look up the inverter_parameters dictionary via some other method. inverter_parameters : None, dict or Series, default None Inverter parameters as defined by the SAPM, CEC, or other. racking_model : None or string, default 'open_rack' Valid strings are 'open_rack', 'close_mount', and 'insulated_back'. Used to identify a parameter set for the SAPM cell temperature model. losses_parameters : None, dict or Series, default None Losses parameters as defined by PVWatts or other. name : None or string, default None **kwargs Arbitrary keyword arguments. Included for compatibility, but not used. Raises ------ ValueError If `arrays` is not None and has length 0. See also -------- pvlib.location.Location pvlib.tracking.SingleAxisTracker """
[docs] def __init__(self, arrays=None, surface_tilt=0, surface_azimuth=180, albedo=None, surface_type=None, module=None, module_type=None, module_parameters=None, temperature_model_parameters=None, modules_per_string=1, strings_per_inverter=1, inverter=None, inverter_parameters=None, racking_model=None, losses_parameters=None, name=None): if arrays is None: if losses_parameters is None: array_losses_parameters = {} else: array_losses_parameters = _build_kwargs(['dc_ohmic_percent'], losses_parameters) self.arrays = (Array( FixedMount(surface_tilt, surface_azimuth, racking_model), albedo, surface_type, module, module_type, module_parameters, temperature_model_parameters, modules_per_string, strings_per_inverter, array_losses_parameters, ),) elif len(arrays) == 0: raise ValueError("PVSystem must have at least one Array. " "If you want to create a PVSystem instance " "with a single Array pass `arrays=None` and pass " "values directly to PVSystem attributes, e.g., " "`surface_tilt=30`") else: self.arrays = tuple(arrays) self.inverter = inverter if inverter_parameters is None: self.inverter_parameters = {} else: self.inverter_parameters = inverter_parameters if losses_parameters is None: self.losses_parameters = {} else: self.losses_parameters = losses_parameters self.name = name
def __repr__(self): repr = f'PVSystem:\n name: {self.name}\n ' for array in self.arrays: repr += '\n '.join(array.__repr__().split('\n')) repr += '\n ' repr += f'inverter: {self.inverter}' return repr def _validate_per_array(self, values, system_wide=False): """Check that `values` is a tuple of the same length as `self.arrays`. If `values` is not a tuple it is packed in to a length-1 tuple before the check. If the lengths are not the same a ValueError is raised, otherwise the tuple `values` is returned. When `system_wide` is True and `values` is not a tuple, `values` is replicated to a tuple of the same length as `self.arrays` and that tuple is returned. """ if system_wide and not isinstance(values, tuple): return (values,) * self.num_arrays if not isinstance(values, tuple): values = (values,) if len(values) != len(self.arrays): raise ValueError("Length mismatch for per-array parameter") return values @_unwrap_single_value def _infer_cell_type(self): """ Examines module_parameters and maps the Technology key for the CEC database and the Material key for the Sandia database to a common list of strings for cell type. Returns ------- cell_type: str """ return tuple(array._infer_cell_type() for array in self.arrays)
[docs] @_unwrap_single_value def get_aoi(self, solar_zenith, solar_azimuth): """Get the angle of incidence on the Array(s) in the system. Parameters ---------- solar_zenith : float or Series. Solar zenith angle. solar_azimuth : float or Series. Solar azimuth angle. Returns ------- aoi : Series or tuple of Series The angle of incidence """ return tuple(array.get_aoi(solar_zenith, solar_azimuth) for array in self.arrays)
[docs] @_unwrap_single_value def get_irradiance(self, solar_zenith, solar_azimuth, dni, ghi, dhi, dni_extra=None, airmass=None, model='haydavies', **kwargs): """ Uses the :py:func:`irradiance.get_total_irradiance` function to calculate the plane of array irradiance components on a tilted surface defined by ``self.surface_tilt``, ``self.surface_azimuth``, and ``self.albedo``. Parameters ---------- solar_zenith : float or Series. Solar zenith angle. solar_azimuth : float or Series. Solar azimuth angle. dni : float or Series or tuple of float or Series Direct Normal Irradiance ghi : float or Series or tuple of float or Series Global horizontal irradiance dhi : float or Series or tuple of float or Series Diffuse horizontal irradiance dni_extra : None, float or Series, default None Extraterrestrial direct normal irradiance airmass : None, float or Series, default None Airmass model : String, default 'haydavies' Irradiance model. kwargs Extra parameters passed to :func:`irradiance.get_total_irradiance`. Notes ----- Each of `dni`, `ghi`, and `dni` parameters may be passed as a tuple to provide different irradiance for each array in the system. If not passed as a tuple then the same value is used for input to each Array. If passed as a tuple the length must be the same as the number of Arrays. Returns ------- poa_irradiance : DataFrame or tuple of DataFrame Column names are: ``'poa_global', 'poa_direct', 'poa_diffuse', 'poa_sky_diffuse', 'poa_ground_diffuse'``. """ dni = self._validate_per_array(dni, system_wide=True) ghi = self._validate_per_array(ghi, system_wide=True) dhi = self._validate_per_array(dhi, system_wide=True) return tuple( array.get_irradiance(solar_zenith, solar_azimuth, dni, ghi, dhi, dni_extra, airmass, model, **kwargs) for array, dni, ghi, dhi in zip( self.arrays, dni, ghi, dhi ) )
[docs] @_unwrap_single_value def get_iam(self, aoi, iam_model='physical'): """ Determine the incidence angle modifier using the method specified by ``iam_model``. Parameters for the selected IAM model are expected to be in ``PVSystem.module_parameters``. Default parameters are available for the 'physical', 'ashrae' and 'martin_ruiz' models. Parameters ---------- aoi : numeric or tuple of numeric The angle of incidence in degrees. aoi_model : string, default 'physical' The IAM model to be used. Valid strings are 'physical', 'ashrae', 'martin_ruiz' and 'sapm'. Returns ------- iam : numeric or tuple of numeric The AOI modifier. Raises ------ ValueError if `iam_model` is not a valid model name. """ aoi = self._validate_per_array(aoi) return tuple(array.get_iam(aoi, iam_model) for array, aoi in zip(self.arrays, aoi))
[docs] @_unwrap_single_value def get_cell_temperature(self, poa_global, temp_air, wind_speed, model, effective_irradiance=None): """ Determine cell temperature using the method specified by ``model``. Parameters ---------- poa_global : numeric or tuple of numeric Total incident irradiance in W/m^2. temp_air : numeric or tuple of numeric Ambient dry bulb temperature in degrees C. wind_speed : numeric or tuple of numeric Wind speed in m/s. model : str Supported models include ``'sapm'``, ``'pvsyst'``, ``'faiman'``, ``'fuentes'``, and ``'noct_sam'`` effective_irradiance : numeric or tuple of numeric, optional The irradiance that is converted to photocurrent in W/m^2. Only used for some models. Returns ------- numeric or tuple of numeric Values in degrees C. See Also -------- Array.get_cell_temperature Notes ----- The `temp_air` and `wind_speed` parameters may be passed as tuples to provide different values for each Array in the system. If passed as a tuple the length must be the same as the number of Arrays. If not passed as a tuple then the same value is used for each Array. """ poa_global = self._validate_per_array(poa_global) temp_air = self._validate_per_array(temp_air, system_wide=True) wind_speed = self._validate_per_array(wind_speed, system_wide=True) # Not used for all models, but Array.get_cell_temperature handles it effective_irradiance = self._validate_per_array(effective_irradiance, system_wide=True) return tuple( array.get_cell_temperature(poa_global, temp_air, wind_speed, model, effective_irradiance) for array, poa_global, temp_air, wind_speed, effective_irradiance in zip( self.arrays, poa_global, temp_air, wind_speed, effective_irradiance ) )
[docs] @_unwrap_single_value def calcparams_desoto(self, effective_irradiance, temp_cell): """ Use the :py:func:`calcparams_desoto` function, the input parameters and ``self.module_parameters`` to calculate the module currents and resistances. Parameters ---------- effective_irradiance : numeric or tuple of numeric The irradiance (W/m2) that is converted to photocurrent. temp_cell : float or Series or tuple of float or Series The average cell temperature of cells within a module in C. Returns ------- See pvsystem.calcparams_desoto for details """ effective_irradiance = self._validate_per_array(effective_irradiance) temp_cell = self._validate_per_array(temp_cell) build_kwargs = functools.partial( _build_kwargs, ['a_ref', 'I_L_ref', 'I_o_ref', 'R_sh_ref', 'R_s', 'alpha_sc', 'EgRef', 'dEgdT', 'irrad_ref', 'temp_ref'] ) return tuple( calcparams_desoto( effective_irradiance, temp_cell, **build_kwargs(array.module_parameters) ) for array, effective_irradiance, temp_cell in zip(self.arrays, effective_irradiance, temp_cell) )
[docs] @_unwrap_single_value def calcparams_cec(self, effective_irradiance, temp_cell): """ Use the :py:func:`calcparams_cec` function, the input parameters and ``self.module_parameters`` to calculate the module currents and resistances. Parameters ---------- effective_irradiance : numeric or tuple of numeric The irradiance (W/m2) that is converted to photocurrent. temp_cell : float or Series or tuple of float or Series The average cell temperature of cells within a module in C. Returns ------- See pvsystem.calcparams_cec for details """ effective_irradiance = self._validate_per_array(effective_irradiance) temp_cell = self._validate_per_array(temp_cell) build_kwargs = functools.partial( _build_kwargs, ['a_ref', 'I_L_ref', 'I_o_ref', 'R_sh_ref', 'R_s', 'alpha_sc', 'Adjust', 'EgRef', 'dEgdT', 'irrad_ref', 'temp_ref'] ) return tuple( calcparams_cec( effective_irradiance, temp_cell, **build_kwargs(array.module_parameters) ) for array, effective_irradiance, temp_cell in zip(self.arrays, effective_irradiance, temp_cell) )
[docs] @_unwrap_single_value def calcparams_pvsyst(self, effective_irradiance, temp_cell): """ Use the :py:func:`calcparams_pvsyst` function, the input parameters and ``self.module_parameters`` to calculate the module currents and resistances. Parameters ---------- effective_irradiance : numeric or tuple of numeric The irradiance (W/m2) that is converted to photocurrent. temp_cell : float or Series or tuple of float or Series The average cell temperature of cells within a module in C. Returns ------- See pvsystem.calcparams_pvsyst for details """ effective_irradiance = self._validate_per_array(effective_irradiance) temp_cell = self._validate_per_array(temp_cell) build_kwargs = functools.partial( _build_kwargs, ['gamma_ref', 'mu_gamma', 'I_L_ref', 'I_o_ref', 'R_sh_ref', 'R_sh_0', 'R_sh_exp', 'R_s', 'alpha_sc', 'EgRef', 'irrad_ref', 'temp_ref', 'cells_in_series'] ) return tuple( calcparams_pvsyst( effective_irradiance, temp_cell, **build_kwargs(array.module_parameters) ) for array, effective_irradiance, temp_cell in zip(self.arrays, effective_irradiance, temp_cell) )
[docs] @_unwrap_single_value def sapm(self, effective_irradiance, temp_cell): """ Use the :py:func:`sapm` function, the input parameters, and ``self.module_parameters`` to calculate Voc, Isc, Ix, Ixx, Vmp, and Imp. Parameters ---------- effective_irradiance : numeric or tuple of numeric The irradiance (W/m2) that is converted to photocurrent. temp_cell : float or Series or tuple of float or Series The average cell temperature of cells within a module in C. Returns ------- See pvsystem.sapm for details """ effective_irradiance = self._validate_per_array(effective_irradiance) temp_cell = self._validate_per_array(temp_cell) return tuple( sapm(effective_irradiance, temp_cell, array.module_parameters) for array, effective_irradiance, temp_cell in zip(self.arrays, effective_irradiance, temp_cell) )
[docs] @deprecated('0.9', alternative='PVSystem.get_cell_temperature', removal='0.10.0') def sapm_celltemp(self, poa_global, temp_air, wind_speed): """Uses :py:func:`pvlib.temperature.sapm_cell` to calculate cell temperatures. Parameters ---------- poa_global : numeric or tuple of numeric Total incident irradiance in W/m^2. temp_air : numeric or tuple of numeric Ambient dry bulb temperature in degrees C. wind_speed : numeric or tuple of numeric Wind speed in m/s at a height of 10 meters. Returns ------- numeric or tuple of numeric values in degrees C. Notes ----- The `temp_air` and `wind_speed` parameters may be passed as tuples to provide different values for each Array in the system. If not passed as a tuple then the same value is used for input to each Array. If passed as a tuple the length must be the same as the number of Arrays. """ return self.get_cell_temperature(poa_global, temp_air, wind_speed, model='sapm')
[docs] @_unwrap_single_value def sapm_spectral_loss(self, airmass_absolute): """ Use the :py:func:`sapm_spectral_loss` function, the input parameters, and ``self.module_parameters`` to calculate F1. Parameters ---------- airmass_absolute : numeric Absolute airmass. Returns ------- F1 : numeric or tuple of numeric The SAPM spectral loss coefficient. """ return tuple( sapm_spectral_loss(airmass_absolute, array.module_parameters) for array in self.arrays )
[docs] @_unwrap_single_value def sapm_effective_irradiance(self, poa_direct, poa_diffuse, airmass_absolute, aoi, reference_irradiance=1000): """ Use the :py:func:`sapm_effective_irradiance` function, the input parameters, and ``self.module_parameters`` to calculate effective irradiance. Parameters ---------- poa_direct : numeric or tuple of numeric The direct irradiance incident upon the module. [W/m2] poa_diffuse : numeric or tuple of numeric The diffuse irradiance incident on module. [W/m2] airmass_absolute : numeric Absolute airmass. [unitless] aoi : numeric or tuple of numeric Angle of incidence. [degrees] Returns ------- effective_irradiance : numeric or tuple of numeric The SAPM effective irradiance. [W/m2] """ poa_direct = self._validate_per_array(poa_direct) poa_diffuse = self._validate_per_array(poa_diffuse) aoi = self._validate_per_array(aoi) return tuple( sapm_effective_irradiance( poa_direct, poa_diffuse, airmass_absolute, aoi, array.module_parameters) for array, poa_direct, poa_diffuse, aoi in zip(self.arrays, poa_direct, poa_diffuse, aoi) )
[docs] @deprecated('0.9', alternative='PVSystem.get_cell_temperature', removal='0.10.0') def pvsyst_celltemp(self, poa_global, temp_air, wind_speed=1.0): """Uses :py:func:`pvlib.temperature.pvsyst_cell` to calculate cell temperature. Parameters ---------- poa_global : numeric or tuple of numeric Total incident irradiance in W/m^2. temp_air : numeric or tuple of numeric Ambient dry bulb temperature in degrees C. wind_speed : numeric or tuple of numeric, default 1.0 Wind speed in m/s measured at the same height for which the wind loss factor was determined. The default value is 1.0, which is the wind speed at module height used to determine NOCT. Returns ------- numeric or tuple of numeric values in degrees C. Notes ----- The `temp_air` and `wind_speed` parameters may be passed as tuples to provide different values for each Array in the system. If not passed as a tuple then the same value is used for input to each Array. If passed as a tuple the length must be the same as the number of Arrays. """ return self.get_cell_temperature(poa_global, temp_air, wind_speed, model='pvsyst')
[docs] @deprecated('0.9', alternative='PVSystem.get_cell_temperature', removal='0.10.0') def faiman_celltemp(self, poa_global, temp_air, wind_speed=1.0): """ Use :py:func:`pvlib.temperature.faiman` to calculate cell temperature. Parameters ---------- poa_global : numeric or tuple of numeric Total incident irradiance [W/m^2]. temp_air : numeric or tuple of numeric Ambient dry bulb temperature [C]. wind_speed : numeric or tuple of numeric, default 1.0 Wind speed in m/s measured at the same height for which the wind loss factor was determined. The default value 1.0 m/s is the wind speed at module height used to determine NOCT. [m/s] Returns ------- numeric or tuple of numeric values in degrees C. Notes ----- The `temp_air` and `wind_speed` parameters may be passed as tuples to provide different values for each Array in the system. If not passed as a tuple then the same value is used for input to each Array. If passed as a tuple the length must be the same as the number of Arrays. """ return self.get_cell_temperature(poa_global, temp_air, wind_speed, model='faiman')
[docs] @deprecated('0.9', alternative='PVSystem.get_cell_temperature', removal='0.10.0') def fuentes_celltemp(self, poa_global, temp_air, wind_speed): """ Use :py:func:`pvlib.temperature.fuentes` to calculate cell temperature. Parameters ---------- poa_global : pandas Series or tuple of Series Total incident irradiance [W/m^2] temp_air : pandas Series or tuple of Series Ambient dry bulb temperature [C] wind_speed : pandas Series or tuple of Series Wind speed [m/s] Returns ------- temperature_cell : Series or tuple of Series The modeled cell temperature [C] Notes ----- The Fuentes thermal model uses the module surface tilt for convection modeling. The SAM implementation of PVWatts hardcodes the surface tilt value at 30 degrees, ignoring whatever value is used for irradiance transposition. If you want to match the PVWatts behavior you can either leave ``surface_tilt`` unspecified to use the PVWatts default of 30, or specify a ``surface_tilt`` value in the Array's ``temperature_model_parameters``. The `temp_air`, `wind_speed`, and `surface_tilt` parameters may be passed as tuples to provide different values for each Array in the system. If not passed as a tuple then the same value is used for input to each Array. If passed as a tuple the length must be the same as the number of Arrays. """ return self.get_cell_temperature(poa_global, temp_air, wind_speed, model='fuentes')
[docs] @deprecated('0.9', alternative='PVSystem.get_cell_temperature', removal='0.10.0') def noct_sam_celltemp(self, poa_global, temp_air, wind_speed, effective_irradiance=None): """ Use :py:func:`pvlib.temperature.noct_sam` to calculate cell temperature. Parameters ---------- poa_global : numeric or tuple of numeric Total incident irradiance in W/m^2. temp_air : numeric or tuple of numeric Ambient dry bulb temperature in degrees C. wind_speed : numeric or tuple of numeric Wind speed in m/s at a height of 10 meters. effective_irradiance : numeric, tuple of numeric, or None. The irradiance that is converted to photocurrent. If None, assumed equal to ``poa_global``. [W/m^2] Returns ------- temperature_cell : numeric or tuple of numeric The modeled cell temperature [C] Notes ----- The `temp_air` and `wind_speed` parameters may be passed as tuples to provide different values for each Array in the system. If not passed as a tuple then the same value is used for input to each Array. If passed as a tuple the length must be the same as the number of Arrays. """ return self.get_cell_temperature( poa_global, temp_air, wind_speed, model='noct_sam', effective_irradiance=effective_irradiance)
[docs] @_unwrap_single_value def first_solar_spectral_loss(self, pw, airmass_absolute): """ Use :py:func:`pvlib.atmosphere.first_solar_spectral_correction` to calculate the spectral loss modifier. The model coefficients are specific to the module's cell type, and are determined by searching for one of the following keys in self.module_parameters (in order): - 'first_solar_spectral_coefficients' (user-supplied coefficients) - 'Technology' - a string describing the cell type, can be read from the CEC module parameter database - 'Material' - a string describing the cell type, can be read from the Sandia module database. Parameters ---------- pw : array-like atmospheric precipitable water (cm). airmass_absolute : array-like absolute (pressure corrected) airmass. Returns ------- modifier: array-like or tuple of array-like spectral mismatch factor (unitless) which can be multiplied with broadband irradiance reaching a module's cells to estimate effective irradiance, i.e., the irradiance that is converted to electrical current. """ pw = self._validate_per_array(pw, system_wide=True) def _spectral_correction(array, pw): if 'first_solar_spectral_coefficients' in \ array.module_parameters.keys(): coefficients = \ array.module_parameters[ 'first_solar_spectral_coefficients' ] module_type = None else: module_type = array._infer_cell_type() coefficients = None return atmosphere.first_solar_spectral_correction( pw, airmass_absolute, module_type, coefficients ) return tuple( itertools.starmap(_spectral_correction, zip(self.arrays, pw)) )
[docs] def singlediode(self, photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth, ivcurve_pnts=None): """Wrapper around the :py:func:`pvlib.pvsystem.singlediode` function. See :py:func:`pvsystem.singlediode` for details """ return singlediode(photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth, ivcurve_pnts=ivcurve_pnts)
[docs] def i_from_v(self, resistance_shunt, resistance_series, nNsVth, voltage, saturation_current, photocurrent): """Wrapper around the :py:func:`pvlib.pvsystem.i_from_v` function. See :py:func:`pvsystem.i_from_v` for details """ return i_from_v(resistance_shunt, resistance_series, nNsVth, voltage, saturation_current, photocurrent)
[docs] def get_ac(self, model, p_dc, v_dc=None): r"""Calculates AC power from p_dc using the inverter model indicated by model and self.inverter_parameters. Parameters ---------- model : str Must be one of 'sandia', 'adr', or 'pvwatts'. p_dc : numeric, or tuple, list or array of numeric DC power on each MPPT input of the inverter. Use tuple, list or array for inverters with multiple MPPT inputs. If type is array, p_dc must be 2d with axis 0 being the MPPT inputs. [W] v_dc : numeric, or tuple, list or array of numeric DC voltage on each MPPT input of the inverter. Required when model='sandia' or model='adr'. Use tuple, list or array for inverters with multiple MPPT inputs. If type is array, v_dc must be 2d with axis 0 being the MPPT inputs. [V] Returns ------- power_ac : numeric AC power output for the inverter. [W] Raises ------ ValueError If model is not one of 'sandia', 'adr' or 'pvwatts'. ValueError If model='adr' and the PVSystem has more than one array. See also -------- pvlib.inverter.sandia pvlib.inverter.sandia_multi pvlib.inverter.adr pvlib.inverter.pvwatts pvlib.inverter.pvwatts_multi """ model = model.lower() multiple_arrays = self.num_arrays > 1 if model == 'sandia': p_dc = self._validate_per_array(p_dc) v_dc = self._validate_per_array(v_dc) if multiple_arrays: return inverter.sandia_multi( v_dc, p_dc, self.inverter_parameters) return inverter.sandia(v_dc[0], p_dc[0], self.inverter_parameters) elif model == 'pvwatts': kwargs = _build_kwargs(['eta_inv_nom', 'eta_inv_ref'], self.inverter_parameters) p_dc = self._validate_per_array(p_dc) if multiple_arrays: return inverter.pvwatts_multi( p_dc, self.inverter_parameters['pdc0'], **kwargs) return inverter.pvwatts( p_dc[0], self.inverter_parameters['pdc0'], **kwargs) elif model == 'adr': if multiple_arrays: raise ValueError( 'The adr inverter function cannot be used for an inverter', ' with multiple MPPT inputs') # While this is only used for single-array systems, calling # _validate_per_arry lets us pass in singleton tuples. p_dc = self._validate_per_array(p_dc) v_dc = self._validate_per_array(v_dc) return inverter.adr(v_dc[0], p_dc[0], self.inverter_parameters) else: raise ValueError( model + ' is not a valid AC power model.', ' model must be one of "sandia", "adr" or "pvwatts"')
[docs] @deprecated('0.9', alternative='PVSystem.get_ac', removal='0.10') def snlinverter(self, v_dc, p_dc): """Uses :py:func:`pvlib.inverter.sandia` to calculate AC power based on ``self.inverter_parameters`` and the input voltage and power. See :py:func:`pvlib.inverter.sandia` for details """ return inverter.sandia(v_dc, p_dc, self.inverter_parameters)
[docs] @deprecated('0.9', alternative='PVSystem.get_ac', removal='0.10') def adrinverter(self, v_dc, p_dc): """Uses :py:func:`pvlib.inverter.adr` to calculate AC power based on ``self.inverter_parameters`` and the input voltage and power. See :py:func:`pvlib.inverter.adr` for details """ return inverter.adr(v_dc, p_dc, self.inverter_parameters)
[docs] @_unwrap_single_value def scale_voltage_current_power(self, data): """ Scales the voltage, current, and power of the `data` DataFrame by `self.modules_per_string` and `self.strings_per_inverter`. Parameters ---------- data: DataFrame or tuple of DataFrame May contain columns `'v_mp', 'v_oc', 'i_mp' ,'i_x', 'i_xx', 'i_sc', 'p_mp'`. Returns ------- scaled_data: DataFrame or tuple of DataFrame A scaled copy of the input data. """ data = self._validate_per_array(data) return tuple( scale_voltage_current_power(data, voltage=array.modules_per_string, current=array.strings) for array, data in zip(self.arrays, data) )
[docs] @_unwrap_single_value def pvwatts_dc(self, g_poa_effective, temp_cell): """ Calcuates DC power according to the PVWatts model using :py:func:`pvlib.pvsystem.pvwatts_dc`, `self.module_parameters['pdc0']`, and `self.module_parameters['gamma_pdc']`. See :py:func:`pvlib.pvsystem.pvwatts_dc` for details. """ g_poa_effective = self._validate_per_array(g_poa_effective) temp_cell = self._validate_per_array(temp_cell) return tuple( pvwatts_dc(g_poa_effective, temp_cell, array.module_parameters['pdc0'], array.module_parameters['gamma_pdc'], **_build_kwargs(['temp_ref'], array.module_parameters)) for array, g_poa_effective, temp_cell in zip(self.arrays, g_poa_effective, temp_cell) )
[docs] def pvwatts_losses(self): """ Calculates DC power losses according the PVwatts model using :py:func:`pvlib.pvsystem.pvwatts_losses` and ``self.losses_parameters``. See :py:func:`pvlib.pvsystem.pvwatts_losses` for details. """ kwargs = _build_kwargs(['soiling', 'shading', 'snow', 'mismatch', 'wiring', 'connections', 'lid', 'nameplate_rating', 'age', 'availability'], self.losses_parameters) return pvwatts_losses(**kwargs)
[docs] @deprecated('0.9', alternative='PVSystem.get_ac', removal='0.10') def pvwatts_ac(self, pdc): """ Calculates AC power according to the PVWatts model using :py:func:`pvlib.inverter.pvwatts`, `self.module_parameters["pdc0"]`, and `eta_inv_nom=self.inverter_parameters["eta_inv_nom"]`. See :py:func:`pvlib.inverter.pvwatts` for details. """ kwargs = _build_kwargs(['eta_inv_nom', 'eta_inv_ref'], self.inverter_parameters) return inverter.pvwatts(pdc, self.inverter_parameters['pdc0'], **kwargs)
[docs] @_unwrap_single_value def dc_ohms_from_percent(self): """ Calculates the equivalent resistance of the wires for each array using :py:func:`pvlib.pvsystem.dc_ohms_from_percent` See :py:func:`pvlib.pvsystem.dc_ohms_from_percent` for details. """ return tuple(array.dc_ohms_from_percent() for array in self.arrays)
@property @_unwrap_single_value @_check_deprecated_passthrough def module_parameters(self): return tuple(array.module_parameters for array in self.arrays) @module_parameters.setter @_check_deprecated_passthrough def module_parameters(self, value): for array in self.arrays: array.module_parameters = value @property @_unwrap_single_value @_check_deprecated_passthrough def module(self): return tuple(array.module for array in self.arrays) @module.setter @_check_deprecated_passthrough def module(self, value): for array in self.arrays: array.module = value @property @_unwrap_single_value @_check_deprecated_passthrough def module_type(self): return tuple(array.module_type for array in self.arrays) @module_type.setter @_check_deprecated_passthrough def module_type(self, value): for array in self.arrays: array.module_type = value @property @_unwrap_single_value @_check_deprecated_passthrough def temperature_model_parameters(self): return tuple(array.temperature_model_parameters for array in self.arrays) @temperature_model_parameters.setter @_check_deprecated_passthrough def temperature_model_parameters(self, value): for array in self.arrays: array.temperature_model_parameters = value @property @_unwrap_single_value @_check_deprecated_passthrough def surface_tilt(self): return tuple(array.mount.surface_tilt for array in self.arrays) @surface_tilt.setter @_check_deprecated_passthrough def surface_tilt(self, value): for array in self.arrays: array.mount.surface_tilt = value @property @_unwrap_single_value @_check_deprecated_passthrough def surface_azimuth(self): return tuple(array.mount.surface_azimuth for array in self.arrays) @surface_azimuth.setter @_check_deprecated_passthrough def surface_azimuth(self, value): for array in self.arrays: array.mount.surface_azimuth = value @property @_unwrap_single_value @_check_deprecated_passthrough def albedo(self): return tuple(array.albedo for array in self.arrays) @albedo.setter @_check_deprecated_passthrough def albedo(self, value): for array in self.arrays: array.albedo = value @property @_unwrap_single_value @_check_deprecated_passthrough def racking_model(self): return tuple(array.mount.racking_model for array in self.arrays) @racking_model.setter @_check_deprecated_passthrough def racking_model(self, value): for array in self.arrays: array.mount.racking_model = value @property @_unwrap_single_value @_check_deprecated_passthrough def modules_per_string(self): return tuple(array.modules_per_string for array in self.arrays) @modules_per_string.setter @_check_deprecated_passthrough def modules_per_string(self, value): for array in self.arrays: array.modules_per_string = value @property @_unwrap_single_value @_check_deprecated_passthrough def strings_per_inverter(self): return tuple(array.strings for array in self.arrays) @strings_per_inverter.setter @_check_deprecated_passthrough def strings_per_inverter(self, value): for array in self.arrays: array.strings = value @property def num_arrays(self): """The number of Arrays in the system.""" return len(self.arrays)
[docs]class Array: """ An Array is a set of of modules at the same orientation. Specifically, an array is defined by its mount, the module parameters, the number of parallel strings of modules and the number of modules on each string. Parameters ---------- mount: FixedMount, SingleAxisTrackerMount, or other Mounting for the array, either on fixed-tilt racking or horizontal single axis tracker. Mounting is used to determine module orientation. If not provided, a FixedMount with zero tilt is used. albedo : None or float, default None The ground albedo. If ``None``, will attempt to use ``surface_type`` to look up an albedo value in ``irradiance.SURFACE_ALBEDOS``. If a surface albedo cannot be found then 0.25 is used. surface_type : None or string, default None The ground surface type. See ``irradiance.SURFACE_ALBEDOS`` for valid values. module : None or string, default None The model name of the modules. May be used to look up the module_parameters dictionary via some other method. module_type : None or string, default None Describes the module's construction. Valid strings are 'glass_polymer' and 'glass_glass'. Used for cell and module temperature calculations. module_parameters : None, dict or Series, default None Parameters for the module model, e.g., SAPM, CEC, or other. temperature_model_parameters : None, dict or Series, default None. Parameters for the module temperature model, e.g., SAPM, Pvsyst, or other. modules_per_string: int, default 1 Number of modules per string in the array. strings: int, default 1 Number of parallel strings in the array. array_losses_parameters: None, dict or Series, default None. Supported keys are 'dc_ohmic_percent'. name: None or str, default None Name of Array instance. """
[docs] def __init__(self, mount, albedo=None, surface_type=None, module=None, module_type=None, module_parameters=None, temperature_model_parameters=None, modules_per_string=1, strings=1, array_losses_parameters=None, name=None): self.mount = mount self.surface_type = surface_type if albedo is None: self.albedo = irradiance.SURFACE_ALBEDOS.get(surface_type, 0.25) else: self.albedo = albedo self.module = module if module_parameters is None: self.module_parameters = {} else: self.module_parameters = module_parameters self.module_type = module_type self.strings = strings self.modules_per_string = modules_per_string if temperature_model_parameters is None: self.temperature_model_parameters = \ self._infer_temperature_model_params() else: self.temperature_model_parameters = temperature_model_parameters if array_losses_parameters is None: self.array_losses_parameters = {} else: self.array_losses_parameters = array_losses_parameters self.name = name
def __repr__(self): attrs = ['name', 'mount', 'module', 'albedo', 'module_type', 'temperature_model_parameters', 'strings', 'modules_per_string'] return 'Array:\n ' + '\n '.join( f'{attr}: {getattr(self, attr)}' for attr in attrs ) def _infer_temperature_model_params(self): # try to infer temperature model parameters from from racking_model # and module_type param_set = f'{self.mount.racking_model}_{self.module_type}' if param_set in temperature.TEMPERATURE_MODEL_PARAMETERS['sapm']: return temperature._temperature_model_params('sapm', param_set) elif 'freestanding' in param_set: return temperature._temperature_model_params('pvsyst', 'freestanding') elif 'insulated' in param_set: # after SAPM to avoid confusing keys return temperature._temperature_model_params('pvsyst', 'insulated') else: return {} def _infer_cell_type(self): """ Examines module_parameters and maps the Technology key for the CEC database and the Material key for the Sandia database to a common list of strings for cell type. Returns ------- cell_type: str """ _cell_type_dict = {'Multi-c-Si': 'multisi', 'Mono-c-Si': 'monosi', 'Thin Film': 'cigs', 'a-Si/nc': 'asi', 'CIS': 'cigs', 'CIGS': 'cigs', '1-a-Si': 'asi', 'CdTe': 'cdte', 'a-Si': 'asi', '2-a-Si': None, '3-a-Si': None, 'HIT-Si': 'monosi', 'mc-Si': 'multisi', 'c-Si': 'multisi', 'Si-Film': 'asi', 'EFG mc-Si': 'multisi', 'GaAs': None, 'a-Si / mono-Si': 'monosi'} if 'Technology' in self.module_parameters.keys(): # CEC module parameter set cell_type = _cell_type_dict[self.module_parameters['Technology']] elif 'Material' in self.module_parameters.keys(): # Sandia module parameter set cell_type = _cell_type_dict[self.module_parameters['Material']] else: cell_type = None return cell_type
[docs] def get_aoi(self, solar_zenith, solar_azimuth): """ Get the angle of incidence on the array. Parameters ---------- solar_zenith : float or Series Solar zenith angle. solar_azimuth : float or Series Solar azimuth angle Returns ------- aoi : Series Then angle of incidence. """ orientation = self.mount.get_orientation(solar_zenith, solar_azimuth) return irradiance.aoi(orientation['surface_tilt'], orientation['surface_azimuth'], solar_zenith, solar_azimuth)
[docs] def get_irradiance(self, solar_zenith, solar_azimuth, dni, ghi, dhi, dni_extra=None, airmass=None, model='haydavies', **kwargs): """ Get plane of array irradiance components. Uses the :py:func:`pvlib.irradiance.get_total_irradiance` function to calculate the plane of array irradiance components for a surface defined by ``self.surface_tilt`` and ``self.surface_azimuth`` with albedo ``self.albedo``. Parameters ---------- solar_zenith : float or Series. Solar zenith angle. solar_azimuth : float or Series. Solar azimuth angle. dni : float or Series Direct Normal Irradiance ghi : float or Series Global horizontal irradiance dhi : float or Series Diffuse horizontal irradiance dni_extra : None, float or Series, default None Extraterrestrial direct normal irradiance airmass : None, float or Series, default None Airmass model : String, default 'haydavies' Irradiance model. kwargs Extra parameters passed to :py:func:`pvlib.irradiance.get_total_irradiance`. Returns ------- poa_irradiance : DataFrame Column names are: ``'poa_global', 'poa_direct', 'poa_diffuse', 'poa_sky_diffuse', 'poa_ground_diffuse'``. """ # not needed for all models, but this is easier if dni_extra is None: dni_extra = irradiance.get_extra_radiation(solar_zenith.index) if airmass is None: airmass = atmosphere.get_relative_airmass(solar_zenith) orientation = self.mount.get_orientation(solar_zenith, solar_azimuth) return irradiance.get_total_irradiance(orientation['surface_tilt'], orientation['surface_azimuth'], solar_zenith, solar_azimuth, dni, ghi, dhi, dni_extra=dni_extra, airmass=airmass, model=model, albedo=self.albedo, **kwargs)
[docs] def get_iam(self, aoi, iam_model='physical'): """ Determine the incidence angle modifier using the method specified by ``iam_model``. Parameters for the selected IAM model are expected to be in ``Array.module_parameters``. Default parameters are available for the 'physical', 'ashrae' and 'martin_ruiz' models. Parameters ---------- aoi : numeric The angle of incidence in degrees. aoi_model : string, default 'physical' The IAM model to be used. Valid strings are 'physical', 'ashrae', 'martin_ruiz' and 'sapm'. Returns ------- iam : numeric The AOI modifier. Raises ------ ValueError if `iam_model` is not a valid model name. """ model = iam_model.lower() if model in ['ashrae', 'physical', 'martin_ruiz']: param_names = iam._IAM_MODEL_PARAMS[model] kwargs = _build_kwargs(param_names, self.module_parameters) func = getattr(iam, model) return func(aoi, **kwargs) elif model == 'sapm': return iam.sapm(aoi, self.module_parameters) elif model == 'interp': raise ValueError(model + ' is not implemented as an IAM model ' 'option for Array') else: raise ValueError(model + ' is not a valid IAM model')
[docs] def get_cell_temperature(self, poa_global, temp_air, wind_speed, model, effective_irradiance=None): """ Determine cell temperature using the method specified by ``model``. Parameters ---------- poa_global : numeric Total incident irradiance [W/m^2] temp_air : numeric Ambient dry bulb temperature [C] wind_speed : numeric Wind speed [m/s] model : str Supported models include ``'sapm'``, ``'pvsyst'``, ``'faiman'``, ``'fuentes'``, and ``'noct_sam'`` effective_irradiance : numeric, optional The irradiance that is converted to photocurrent in W/m^2. Only used for some models. Returns ------- numeric Values in degrees C. See Also -------- pvlib.temperature.sapm_cell, pvlib.temperature.pvsyst_cell, pvlib.temperature.faiman, pvlib.temperature.fuentes, pvlib.temperature.noct_sam Notes ----- Some temperature models have requirements for the input types; see the documentation of the underlying model function for details. """ # convenience wrapper to avoid passing args 2 and 3 every call _build_tcell_args = functools.partial( _build_args, input_dict=self.temperature_model_parameters, dict_name='temperature_model_parameters') if model == 'sapm': func = temperature.sapm_cell required = _build_tcell_args(['a', 'b', 'deltaT']) optional = _build_kwargs(['irrad_ref'], self.temperature_model_parameters) elif model == 'pvsyst': func = temperature.pvsyst_cell required = tuple() optional = { # TODO remove 'eta_m' after deprecation of this parameter **_build_kwargs(['eta_m', 'module_efficiency', 'alpha_absorption'], self.module_parameters), **_build_kwargs(['u_c', 'u_v'], self.temperature_model_parameters) } elif model == 'faiman': func = temperature.faiman required = tuple() optional = _build_kwargs(['u0', 'u1'], self.temperature_model_parameters) elif model == 'fuentes': func = temperature.fuentes required = _build_tcell_args(['noct_installed']) optional = _build_kwargs([ 'wind_height', 'emissivity', 'absorption', 'surface_tilt', 'module_width', 'module_length'], self.temperature_model_parameters) if self.mount.module_height is not None: optional['module_height'] = self.mount.module_height elif model == 'noct_sam': func = functools.partial(temperature.noct_sam, effective_irradiance=effective_irradiance) required = _build_tcell_args(['noct', 'module_efficiency']) optional = _build_kwargs(['transmittance_absorptance', 'array_height', 'mount_standoff'], self.temperature_model_parameters) else: raise ValueError(f'{model} is not a valid cell temperature model') temperature_cell = func(poa_global, temp_air, wind_speed, *required, **optional) return temperature_cell
[docs] def dc_ohms_from_percent(self): """ Calculates the equivalent resistance of the wires using :py:func:`pvlib.pvsystem.dc_ohms_from_percent` Makes use of array module parameters according to the following DC models: CEC: * `self.module_parameters["V_mp_ref"]` * `self.module_parameters["I_mp_ref"]` SAPM: * `self.module_parameters["Vmpo"]` * `self.module_parameters["Impo"]` PVsyst-like or other: * `self.module_parameters["Vmpp"]` * `self.module_parameters["Impp"]` Other array parameters that are used are: `self.losses_parameters["dc_ohmic_percent"]`, `self.modules_per_string`, and `self.strings`. See :py:func:`pvlib.pvsystem.dc_ohms_from_percent` for more details. """ # get relevent Vmp and Imp parameters from CEC parameters if all([elem in self.module_parameters for elem in ['V_mp_ref', 'I_mp_ref']]): vmp_ref = self.module_parameters['V_mp_ref'] imp_ref = self.module_parameters['I_mp_ref'] # get relevant Vmp and Imp parameters from SAPM parameters elif all([elem in self.module_parameters for elem in ['Vmpo', 'Impo']]): vmp_ref = self.module_parameters['Vmpo'] imp_ref = self.module_parameters['Impo'] # get relevant Vmp and Imp parameters if they are PVsyst-like elif all([elem in self.module_parameters for elem in ['Vmpp', 'Impp']]): vmp_ref = self.module_parameters['Vmpp'] imp_ref = self.module_parameters['Impp'] # raise error if relevant Vmp and Imp parameters are not found else: raise ValueError('Parameters for Vmp and Imp could not be found ' 'in the array module parameters. Module ' 'parameters must include one set of ' '{"V_mp_ref", "I_mp_Ref"}, ' '{"Vmpo", "Impo"}, or ' '{"Vmpp", "Impp"}.' ) return dc_ohms_from_percent( vmp_ref, imp_ref, self.array_losses_parameters['dc_ohmic_percent'], self.modules_per_string, self.strings)
@dataclass class AbstractMount(ABC): """ A base class for Mount classes to extend. It is not intended to be instantiated directly. """ @abstractmethod def get_orientation(self, solar_zenith, solar_azimuth): """ Determine module orientation. Parameters ---------- solar_zenith : numeric Solar apparent zenith angle [degrees] solar_azimuth : numeric Solar azimuth angle [degrees] Returns ------- orientation : dict-like A dict-like object with keys `'surface_tilt', 'surface_azimuth'` (typically a dict or pandas.DataFrame) """
[docs]@dataclass class FixedMount(AbstractMount): """ Racking at fixed (static) orientation. Parameters ---------- surface_tilt : float, default 0 Surface tilt angle. The tilt angle is defined as angle from horizontal (e.g. surface facing up = 0, surface facing horizon = 90) [degrees] surface_azimuth : float, default 180 Azimuth angle of the module surface. North=0, East=90, South=180, West=270. [degrees] racking_model : str, optional Valid strings are 'open_rack', 'close_mount', and 'insulated_back'. Used to identify a parameter set for the SAPM cell temperature model. module_height : float, optional The height above ground of the center of the module [m]. Used for the Fuentes cell temperature model. """ surface_tilt: float = 0.0 surface_azimuth: float = 180.0 racking_model: Optional[str] = None module_height: Optional[float] = None
[docs] def get_orientation(self, solar_zenith, solar_azimuth): # note -- docstring is automatically inherited from AbstractMount return { 'surface_tilt': self.surface_tilt, 'surface_azimuth': self.surface_azimuth, }
[docs]@dataclass class SingleAxisTrackerMount(AbstractMount): """ Single-axis tracker racking for dynamic solar tracking. Parameters ---------- axis_tilt : float, default 0 The tilt of the axis of rotation (i.e, the y-axis defined by axis_azimuth) with respect to horizontal. [degrees] axis_azimuth : float, default 180 A value denoting the compass direction along which the axis of rotation lies, measured east of north. [degrees] max_angle : float, default 90 A value denoting the maximum rotation angle of the one-axis tracker from its horizontal position (horizontal if axis_tilt = 0). A max_angle of 90 degrees allows the tracker to rotate to a vertical position to point the panel towards a horizon. max_angle of 180 degrees allows for full rotation. [degrees] backtrack : bool, default True Controls whether the tracker has the capability to "backtrack" to avoid row-to-row shading. False denotes no backtrack capability. True denotes backtrack capability. gcr : float, default 2.0/7.0 A value denoting the ground coverage ratio of a tracker system which utilizes backtracking; i.e. the ratio between the PV array surface area to total ground area. A tracker system with modules 2 meters wide, centered on the tracking axis, with 6 meters between the tracking axes has a gcr of 2/6=0.333. If gcr is not provided, a gcr of 2/7 is default. gcr must be <=1. [unitless] cross_axis_tilt : float, default 0.0 The angle, relative to horizontal, of the line formed by the intersection between the slope containing the tracker axes and a plane perpendicular to the tracker axes. Cross-axis tilt should be specified using a right-handed convention. For example, trackers with axis azimuth of 180 degrees (heading south) will have a negative cross-axis tilt if the tracker axes plane slopes down to the east and positive cross-axis tilt if the tracker axes plane slopes up to the east. Use :func:`~pvlib.tracking.calc_cross_axis_tilt` to calculate `cross_axis_tilt`. [degrees] racking_model : str, optional Valid strings are 'open_rack', 'close_mount', and 'insulated_back'. Used to identify a parameter set for the SAPM cell temperature model. module_height : float, optional The height above ground of the center of the module [m]. Used for the Fuentes cell temperature model. """ axis_tilt: float = 0.0 axis_azimuth: float = 0.0 max_angle: float = 90.0 backtrack: bool = True gcr: float = 2.0/7.0 cross_axis_tilt: float = 0.0 racking_model: Optional[str] = None module_height: Optional[float] = None
[docs] def get_orientation(self, solar_zenith, solar_azimuth): # note -- docstring is automatically inherited from AbstractMount from pvlib import tracking # avoid circular import issue tracking_data = tracking.singleaxis( solar_zenith, solar_azimuth, self.axis_tilt, self.axis_azimuth, self.max_angle, self.backtrack, self.gcr, self.cross_axis_tilt ) return tracking_data
[docs]def calcparams_desoto(effective_irradiance, temp_cell, alpha_sc, a_ref, I_L_ref, I_o_ref, R_sh_ref, R_s, EgRef=1.121, dEgdT=-0.0002677, irrad_ref=1000, temp_ref=25): ''' Calculates five parameter values for the single diode equation at effective irradiance and cell temperature using the De Soto et al. model described in [1]_. The five values returned by calcparams_desoto can be used by singlediode to calculate an IV curve. Parameters ---------- effective_irradiance : numeric The irradiance (W/m2) that is converted to photocurrent. temp_cell : numeric The average cell temperature of cells within a module in C. alpha_sc : float The short-circuit current temperature coefficient of the module in units of A/C. a_ref : float The product of the usual diode ideality factor (n, unitless), number of cells in series (Ns), and cell thermal voltage at reference conditions, in units of V. I_L_ref : float The light-generated current (or photocurrent) at reference conditions, in amperes. I_o_ref : float The dark or diode reverse saturation current at reference conditions, in amperes. R_sh_ref : float The shunt resistance at reference conditions, in ohms. R_s : float The series resistance at reference conditions, in ohms. EgRef : float The energy bandgap at reference temperature in units of eV. 1.121 eV for crystalline silicon. EgRef must be >0. For parameters from the SAM CEC module database, EgRef=1.121 is implicit for all cell types in the parameter estimation algorithm used by NREL. dEgdT : float The temperature dependence of the energy bandgap at reference conditions in units of 1/K. May be either a scalar value (e.g. -0.0002677 as in [1]_) or a DataFrame (this may be useful if dEgdT is a modeled as a function of temperature). For parameters from the SAM CEC module database, dEgdT=-0.0002677 is implicit for all cell types in the parameter estimation algorithm used by NREL. irrad_ref : float (optional, default=1000) Reference irradiance in W/m^2. temp_ref : float (optional, default=25) Reference cell temperature in C. Returns ------- Tuple of the following results: photocurrent : numeric Light-generated current in amperes saturation_current : numeric Diode saturation curent in amperes resistance_series : float Series resistance in ohms resistance_shunt : numeric Shunt resistance in ohms nNsVth : numeric The product of the usual diode ideality factor (n, unitless), number of cells in series (Ns), and cell thermal voltage at specified effective irradiance and cell temperature. References ---------- .. [1] W. De Soto et al., "Improvement and validation of a model for photovoltaic array performance", Solar Energy, vol 80, pp. 78-88, 2006. .. [2] System Advisor Model web page. https://sam.nrel.gov. .. [3] A. Dobos, "An Improved Coefficient Calculator for the California Energy Commission 6 Parameter Photovoltaic Module Model", Journal of Solar Energy Engineering, vol 134, 2012. .. [4] O. Madelung, "Semiconductors: Data Handbook, 3rd ed." ISBN 3-540-40488-0 See Also -------- singlediode retrieve_sam Notes ----- If the reference parameters in the ModuleParameters struct are read from a database or library of parameters (e.g. System Advisor Model), it is important to use the same EgRef and dEgdT values that were used to generate the reference parameters, regardless of the actual bandgap characteristics of the semiconductor. For example, in the case of the System Advisor Model library, created as described in [3], EgRef and dEgdT for all modules were 1.121 and -0.0002677, respectively. This table of reference bandgap energies (EgRef), bandgap energy temperature dependence (dEgdT), and "typical" airmass response (M) is provided purely as reference to those who may generate their own reference module parameters (a_ref, IL_ref, I0_ref, etc.) based upon the various PV semiconductors. Again, we stress the importance of using identical EgRef and dEgdT when generation reference parameters and modifying the reference parameters (for irradiance, temperature, and airmass) per DeSoto's equations. Crystalline Silicon (Si): * EgRef = 1.121 * dEgdT = -0.0002677 >>> M = np.polyval([-1.26E-4, 2.816E-3, -0.024459, 0.086257, 0.9181], ... AMa) # doctest: +SKIP Source: [1] Cadmium Telluride (CdTe): * EgRef = 1.475 * dEgdT = -0.0003 >>> M = np.polyval([-2.46E-5, 9.607E-4, -0.0134, 0.0716, 0.9196], ... AMa) # doctest: +SKIP Source: [4] Copper Indium diSelenide (CIS): * EgRef = 1.010 * dEgdT = -0.00011 >>> M = np.polyval([-3.74E-5, 0.00125, -0.01462, 0.0718, 0.9210], ... AMa) # doctest: +SKIP Source: [4] Copper Indium Gallium diSelenide (CIGS): * EgRef = 1.15 * dEgdT = ???? >>> M = np.polyval([-9.07E-5, 0.0022, -0.0202, 0.0652, 0.9417], ... AMa) # doctest: +SKIP Source: Wikipedia Gallium Arsenide (GaAs): * EgRef = 1.424 * dEgdT = -0.000433 * M = unknown Source: [4] ''' # Boltzmann constant in eV/K k = 8.617332478e-05 # reference temperature Tref_K = temp_ref + 273.15 Tcell_K = temp_cell + 273.15 E_g = EgRef * (1 + dEgdT*(Tcell_K - Tref_K)) nNsVth = a_ref * (Tcell_K / Tref_K) # In the equation for IL, the single factor effective_irradiance is # used, in place of the product S*M in [1]. effective_irradiance is # equivalent to the product of S (irradiance reaching a module's cells) * # M (spectral adjustment factor) as described in [1]. IL = effective_irradiance / irrad_ref * \ (I_L_ref + alpha_sc * (Tcell_K - Tref_K)) I0 = (I_o_ref * ((Tcell_K / Tref_K) ** 3) * (np.exp(EgRef / (k*(Tref_K)) - (E_g / (k*(Tcell_K)))))) # Note that the equation for Rsh differs from [1]. In [1] Rsh is given as # Rsh = Rsh_ref * (S_ref / S) where S is broadband irradiance reaching # the module's cells. If desired this model behavior can be duplicated # by applying reflection and soiling losses to broadband plane of array # irradiance and not applying a spectral loss modifier, i.e., # spectral_modifier = 1.0. # use errstate to silence divide by warning with np.errstate(divide='ignore'): Rsh = R_sh_ref * (irrad_ref / effective_irradiance) Rs = R_s return IL, I0, Rs, Rsh, nNsVth
[docs]def calcparams_cec(effective_irradiance, temp_cell, alpha_sc, a_ref, I_L_ref, I_o_ref, R_sh_ref, R_s, Adjust, EgRef=1.121, dEgdT=-0.0002677, irrad_ref=1000, temp_ref=25): ''' Calculates five parameter values for the single diode equation at effective irradiance and cell temperature using the CEC model. The CEC model [1]_ differs from the De soto et al. model [3]_ by the parameter Adjust. The five values returned by calcparams_cec can be used by singlediode to calculate an IV curve. Parameters ---------- effective_irradiance : numeric The irradiance (W/m2) that is converted to photocurrent. temp_cell : numeric The average cell temperature of cells within a module in C. alpha_sc : float The short-circuit current temperature coefficient of the module in units of A/C. a_ref : float The product of the usual diode ideality factor (n, unitless), number of cells in series (Ns), and cell thermal voltage at reference conditions, in units of V. I_L_ref : float The light-generated current (or photocurrent) at reference conditions, in amperes. I_o_ref : float The dark or diode reverse saturation current at reference conditions, in amperes. R_sh_ref : float The shunt resistance at reference conditions, in ohms. R_s : float The series resistance at reference conditions, in ohms. Adjust : float The adjustment to the temperature coefficient for short circuit current, in percent EgRef : float The energy bandgap at reference temperature in units of eV. 1.121 eV for crystalline silicon. EgRef must be >0. For parameters from the SAM CEC module database, EgRef=1.121 is implicit for all cell types in the parameter estimation algorithm used by NREL. dEgdT : float The temperature dependence of the energy bandgap at reference conditions in units of 1/K. May be either a scalar value (e.g. -0.0002677 as in [3]) or a DataFrame (this may be useful if dEgdT is a modeled as a function of temperature). For parameters from the SAM CEC module database, dEgdT=-0.0002677 is implicit for all cell types in the parameter estimation algorithm used by NREL. irrad_ref : float (optional, default=1000) Reference irradiance in W/m^2. temp_ref : float (optional, default=25) Reference cell temperature in C. Returns ------- Tuple of the following results: photocurrent : numeric Light-generated current in amperes saturation_current : numeric Diode saturation curent in amperes resistance_series : float Series resistance in ohms resistance_shunt : numeric Shunt resistance in ohms nNsVth : numeric The product of the usual diode ideality factor (n, unitless), number of cells in series (Ns), and cell thermal voltage at specified effective irradiance and cell temperature. References ---------- .. [1] A. Dobos, "An Improved Coefficient Calculator for the California Energy Commission 6 Parameter Photovoltaic Module Model", Journal of Solar Energy Engineering, vol 134, 2012. .. [2] System Advisor Model web page. https://sam.nrel.gov. .. [3] W. De Soto et al., "Improvement and validation of a model for photovoltaic array performance", Solar Energy, vol 80, pp. 78-88, 2006. See Also -------- calcparams_desoto singlediode retrieve_sam ''' # pass adjusted temperature coefficient to desoto return calcparams_desoto(effective_irradiance, temp_cell, alpha_sc*(1.0 - Adjust/100), a_ref, I_L_ref, I_o_ref, R_sh_ref, R_s, EgRef=EgRef, dEgdT=dEgdT, irrad_ref=irrad_ref, temp_ref=temp_ref)
[docs]def calcparams_pvsyst(effective_irradiance, temp_cell, alpha_sc, gamma_ref, mu_gamma, I_L_ref, I_o_ref, R_sh_ref, R_sh_0, R_s, cells_in_series, R_sh_exp=5.5, EgRef=1.121, irrad_ref=1000, temp_ref=25): ''' Calculates five parameter values for the single diode equation at effective irradiance and cell temperature using the PVsyst v6 model. The PVsyst v6 model is described in [1]_, [2]_, [3]_. The five values returned by calcparams_pvsyst can be used by singlediode to calculate an IV curve. Parameters ---------- effective_irradiance : numeric The irradiance (W/m2) that is converted to photocurrent. temp_cell : numeric The average cell temperature of cells within a module in C. alpha_sc : float The short-circuit current temperature coefficient of the module in units of A/C. gamma_ref : float The diode ideality factor mu_gamma : float The temperature coefficient for the diode ideality factor, 1/K I_L_ref : float The light-generated current (or photocurrent) at reference conditions, in amperes. I_o_ref : float The dark or diode reverse saturation current at reference conditions, in amperes. R_sh_ref : float The shunt resistance at reference conditions, in ohms. R_sh_0 : float The shunt resistance at zero irradiance conditions, in ohms. R_s : float The series resistance at reference conditions, in ohms. cells_in_series : integer The number of cells connected in series. R_sh_exp : float The exponent in the equation for shunt resistance, unitless. Defaults to 5.5. EgRef : float The energy bandgap at reference temperature in units of eV. 1.121 eV for crystalline silicon. EgRef must be >0. irrad_ref : float (optional, default=1000) Reference irradiance in W/m^2. temp_ref : float (optional, default=25) Reference cell temperature in C. Returns ------- Tuple of the following results: photocurrent : numeric Light-generated current in amperes saturation_current : numeric Diode saturation current in amperes resistance_series : float Series resistance in ohms resistance_shunt : numeric Shunt resistance in ohms nNsVth : numeric The product of the usual diode ideality factor (n, unitless), number of cells in series (Ns), and cell thermal voltage at specified effective irradiance and cell temperature. References ---------- .. [1] K. Sauer, T. Roessler, C. W. Hansen, Modeling the Irradiance and Temperature Dependence of Photovoltaic Modules in PVsyst, IEEE Journal of Photovoltaics v5(1), January 2015. .. [2] A. Mermoud, PV modules modelling, Presentation at the 2nd PV Performance Modeling Workshop, Santa Clara, CA, May 2013 .. [3] A. Mermoud, T. Lejeune, Performance Assessment of a Simulation Model for PV modules of any available technology, 25th European Photovoltaic Solar Energy Conference, Valencia, Spain, Sept. 2010 See Also -------- calcparams_desoto singlediode ''' # Boltzmann constant in J/K k = 1.38064852e-23 # elementary charge in coulomb q = 1.6021766e-19 # reference temperature Tref_K = temp_ref + 273.15 Tcell_K = temp_cell + 273.15 gamma = gamma_ref + mu_gamma * (Tcell_K - Tref_K) nNsVth = gamma * k / q * cells_in_series * Tcell_K IL = effective_irradiance / irrad_ref * \ (I_L_ref + alpha_sc * (Tcell_K - Tref_K)) I0 = I_o_ref * ((Tcell_K / Tref_K) ** 3) * \ (np.exp((q * EgRef) / (k * gamma) * (1 / Tref_K - 1 / Tcell_K))) Rsh_tmp = \ (R_sh_ref - R_sh_0 * np.exp(-R_sh_exp)) / (1.0 - np.exp(-R_sh_exp)) Rsh_base = np.maximum(0.0, Rsh_tmp) Rsh = Rsh_base + (R_sh_0 - Rsh_base) * \ np.exp(-R_sh_exp * effective_irradiance / irrad_ref) Rs = R_s return IL, I0, Rs, Rsh, nNsVth
[docs]def retrieve_sam(name=None, path=None): ''' Retrieve latest module and inverter info from a local file or the SAM website. This function will retrieve either: * CEC module database * Sandia Module database * CEC Inverter database * Anton Driesse Inverter database and return it as a pandas DataFrame. Parameters ---------- name : None or string, default None Name can be one of: * 'CECMod' - returns the CEC module database * 'CECInverter' - returns the CEC Inverter database * 'SandiaInverter' - returns the CEC Inverter database (CEC is only current inverter db available; tag kept for backwards compatibility) * 'SandiaMod' - returns the Sandia Module database * 'ADRInverter' - returns the ADR Inverter database path : None or string, default None Path to the SAM file. May also be a URL. Returns ------- samfile : DataFrame A DataFrame containing all the elements of the desired database. Each column represents a module or inverter, and a specific dataset can be retrieved by the command Raises ------ ValueError If no name or path is provided. Notes ----- Files available at https://github.com/NREL/SAM/tree/develop/deploy/libraries Documentation for module and inverter data sets: https://sam.nrel.gov/photovoltaic/pv-sub-page-2.html Examples -------- >>> from pvlib import pvsystem >>> invdb = pvsystem.retrieve_sam('CECInverter') >>> inverter = invdb.AE_Solar_Energy__AE6_0__277V__277V__CEC_2012_ >>> inverter Vac 277.000000 Paco 6000.000000 Pdco 6165.670000 Vdco 361.123000 Pso 36.792300 C0 -0.000002 C1 -0.000047 C2 -0.001861 C3 0.000721 Pnt 0.070000 Vdcmax 600.000000 Idcmax 32.000000 Mppt_low 200.000000 Mppt_high 500.000000 Name: AE_Solar_Energy__AE6_0__277V__277V__CEC_2012_, dtype: float64 ''' if name is not None: name = name.lower() data_path = os.path.join( os.path.dirname(os.path.abspath(__file__)), 'data') if name == 'cecmod': csvdata = os.path.join( data_path, 'sam-library-cec-modules-2019-03-05.csv') elif name == 'sandiamod': csvdata = os.path.join( data_path, 'sam-library-sandia-modules-2015-6-30.csv') elif name == 'adrinverter': csvdata = os.path.join(data_path, 'adr-library-2013-10-01.csv') elif name in ['cecinverter', 'sandiainverter']: # Allowing either, to provide for old code, # while aligning with current expectations csvdata = os.path.join( data_path, 'sam-library-cec-inverters-2019-03-05.csv') else: raise ValueError(f'invalid name {name}') elif path is not None: if path.startswith('http'): response = urlopen(path) csvdata = io.StringIO(response.read().decode(errors='ignore')) else: csvdata = path elif name is None and path is None: raise ValueError("A name or path must be provided!") return _parse_raw_sam_df(csvdata)
def _normalize_sam_product_names(names): ''' Replace special characters within the product names to make them more suitable for use as Dataframe column names. ''' # Contributed by Anton Driesse (@adriesse), PV Performance Labs. July, 2019 import warnings BAD_CHARS = ' -.()[]:+/",' GOOD_CHARS = '____________' mapping = str.maketrans(BAD_CHARS, GOOD_CHARS) names = pd.Series(data=names) norm_names = names.str.translate(mapping) n_duplicates = names.duplicated().sum() if n_duplicates > 0: warnings.warn('Original names contain %d duplicate(s).' % n_duplicates) n_duplicates = norm_names.duplicated().sum() if n_duplicates > 0: warnings.warn( 'Normalized names contain %d duplicate(s).' % n_duplicates) return norm_names.values def _parse_raw_sam_df(csvdata): df = pd.read_csv(csvdata, index_col=0, skiprows=[1, 2]) df.columns = df.columns.str.replace(' ', '_') df.index = _normalize_sam_product_names(df.index) df = df.transpose() if 'ADRCoefficients' in df.index: ad_ce = 'ADRCoefficients' # for each inverter, parses a string of coefficients like # ' 1.33, 2.11, 3.12' into a list containing floats: # [1.33, 2.11, 3.12] df.loc[ad_ce] = df.loc[ad_ce].map(lambda x: list( map(float, x.strip(' []').split()))) return df
[docs]def sapm(effective_irradiance, temp_cell, module): ''' The Sandia PV Array Performance Model (SAPM) generates 5 points on a PV module's I-V curve (Voc, Isc, Ix, Ixx, Vmp/Imp) according to SAND2004-3535. Assumes a reference cell temperature of 25 C. Parameters ---------- effective_irradiance : numeric Irradiance reaching the module's cells, after reflections and adjustment for spectrum. [W/m2] temp_cell : numeric Cell temperature [C]. module : dict-like A dict or Series defining the SAPM parameters. See the notes section for more details. Returns ------- A DataFrame with the columns: * i_sc : Short-circuit current (A) * i_mp : Current at the maximum-power point (A) * v_oc : Open-circuit voltage (V) * v_mp : Voltage at maximum-power point (V) * p_mp : Power at maximum-power point (W) * i_x : Current at module V = 0.5Voc, defines 4th point on I-V curve for modeling curve shape * i_xx : Current at module V = 0.5(Voc+Vmp), defines 5th point on I-V curve for modeling curve shape Notes ----- The SAPM parameters which are required in ``module`` are listed in the following table. The Sandia module database contains parameter values for a limited set of modules. The CEC module database does not contain these parameters. Both databases can be accessed using :py:func:`retrieve_sam`. ================ ======================================================== Key Description ================ ======================================================== A0-A4 The airmass coefficients used in calculating effective irradiance B0-B5 The angle of incidence coefficients used in calculating effective irradiance C0-C7 The empirically determined coefficients relating Imp, Vmp, Ix, and Ixx to effective irradiance Isco Short circuit current at reference condition (amps) Impo Maximum power current at reference condition (amps) Voco Open circuit voltage at reference condition (amps) Vmpo Maximum power voltage at reference condition (amps) Aisc Short circuit current temperature coefficient at reference condition (1/C) Aimp Maximum power current temperature coefficient at reference condition (1/C) Bvoco Open circuit voltage temperature coefficient at reference condition (V/C) Mbvoc Coefficient providing the irradiance dependence for the BetaVoc temperature coefficient at reference irradiance (V/C) Bvmpo Maximum power voltage temperature coefficient at reference condition Mbvmp Coefficient providing the irradiance dependence for the BetaVmp temperature coefficient at reference irradiance (V/C) N Empirically determined "diode factor" (dimensionless) Cells_in_Series Number of cells in series in a module's cell string(s) IXO Ix at reference conditions IXXO Ixx at reference conditions FD Fraction of diffuse irradiance used by module ================ ======================================================== References ---------- .. [1] King, D. et al, 2004, "Sandia Photovoltaic Array Performance Model", SAND Report 3535, Sandia National Laboratories, Albuquerque, NM. See Also -------- retrieve_sam pvlib.temperature.sapm_cell pvlib.temperature.sapm_module ''' # TODO: someday, change temp_ref and irrad_ref to reference_temperature and # reference_irradiance and expose temp_ref = 25 irrad_ref = 1000 q = 1.60218e-19 # Elementary charge in units of coulombs kb = 1.38066e-23 # Boltzmann's constant in units of J/K # avoid problem with integer input Ee = np.array(effective_irradiance, dtype='float64') / irrad_ref # set up masking for 0, positive, and nan inputs Ee_gt_0 = np.full_like(Ee, False, dtype='bool') Ee_eq_0 = np.full_like(Ee, False, dtype='bool') notnan = ~np.isnan(Ee) np.greater(Ee, 0, where=notnan, out=Ee_gt_0) np.equal(Ee, 0, where=notnan, out=Ee_eq_0) Bvmpo = module['Bvmpo'] + module['Mbvmp']*(1 - Ee) Bvoco = module['Bvoco'] + module['Mbvoc']*(1 - Ee) delta = module['N'] * kb * (temp_cell + 273.15) / q # avoid repeated computation logEe = np.full_like(Ee, np.nan) np.log(Ee, where=Ee_gt_0, out=logEe) logEe = np.where(Ee_eq_0, -np.inf, logEe) # avoid repeated __getitem__ cells_in_series = module['Cells_in_Series'] out = OrderedDict() out['i_sc'] = ( module['Isco'] * Ee * (1 + module['Aisc']*(temp_cell - temp_ref))) out['i_mp'] = ( module['Impo'] * (module['C0']*Ee + module['C1']*(Ee**2)) * (1 + module['Aimp']*(temp_cell - temp_ref))) out['v_oc'] = np.maximum(0, ( module['Voco'] + cells_in_series * delta * logEe + Bvoco*(temp_cell - temp_ref))) out['v_mp'] = np.maximum(0, ( module['Vmpo'] + module['C2'] * cells_in_series * delta * logEe + module['C3'] * cells_in_series * ((delta * logEe) ** 2) + Bvmpo*(temp_cell - temp_ref))) out['p_mp'] = out['i_mp'] * out['v_mp'] out['i_x'] = ( module['IXO'] * (module['C4']*Ee + module['C5']*(Ee**2)) * (1 + module['Aisc']*(temp_cell - temp_ref))) # the Ixx calculation in King 2004 has a typo (mixes up Aisc and Aimp) out['i_xx'] = ( module['IXXO'] * (module['C6']*Ee + module['C7']*(Ee**2)) * (1 + module['Aisc']*(temp_cell - temp_ref))) if isinstance(out['i_sc'], pd.Series): out = pd.DataFrame(out) return out
[docs]def sapm_spectral_loss(airmass_absolute, module): """ Calculates the SAPM spectral loss coefficient, F1. Parameters ---------- airmass_absolute : numeric Absolute airmass module : dict-like A dict, Series, or DataFrame defining the SAPM performance parameters. See the :py:func:`sapm` notes section for more details. Returns ------- F1 : numeric The SAPM spectral loss coefficient. Notes ----- nan airmass values will result in 0 output. """ am_coeff = [module['A4'], module['A3'], module['A2'], module['A1'], module['A0']] spectral_loss = np.polyval(am_coeff, airmass_absolute) spectral_loss = np.where(np.isnan(spectral_loss), 0, spectral_loss) spectral_loss = np.maximum(0, spectral_loss) if isinstance(airmass_absolute, pd.Series): spectral_loss = pd.Series(spectral_loss, airmass_absolute.index) return spectral_loss
[docs]def sapm_effective_irradiance(poa_direct, poa_diffuse, airmass_absolute, aoi, module): r""" Calculates the SAPM effective irradiance using the SAPM spectral loss and SAPM angle of incidence loss functions. Parameters ---------- poa_direct : numeric The direct irradiance incident upon the module. [W/m2] poa_diffuse : numeric The diffuse irradiance incident on module. [W/m2] airmass_absolute : numeric Absolute airmass. [unitless] aoi : numeric Angle of incidence. [degrees] module : dict-like A dict, Series, or DataFrame defining the SAPM performance parameters. See the :py:func:`sapm` notes section for more details. Returns ------- effective_irradiance : numeric Effective irradiance accounting for reflections and spectral content. [W/m2] Notes ----- The SAPM model for effective irradiance [1]_ translates broadband direct and diffuse irradiance on the plane of array to the irradiance absorbed by a module's cells. The model is .. math:: `Ee = f_1(AM_a) (E_b f_2(AOI) + f_d E_d)` where :math:`Ee` is effective irradiance (W/m2), :math:`f_1` is a fourth degree polynomial in air mass :math:`AM_a`, :math:`E_b` is beam (direct) irradiance on the plane of array, :math:`E_d` is diffuse irradiance on the plane of array, :math:`f_2` is a fifth degree polynomial in the angle of incidence :math:`AOI`, and :math:`f_d` is the fraction of diffuse irradiance on the plane of array that is not reflected away. References ---------- .. [1] D. King et al, "Sandia Photovoltaic Array Performance Model", SAND2004-3535, Sandia National Laboratories, Albuquerque, NM See also -------- pvlib.iam.sapm pvlib.pvsystem.sapm_spectral_loss pvlib.pvsystem.sapm """ F1 = sapm_spectral_loss(airmass_absolute, module) F2 = iam.sapm(aoi, module) Ee = F1 * (poa_direct * F2 + module['FD'] * poa_diffuse) return Ee
[docs]def singlediode(photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth, ivcurve_pnts=None, method='lambertw'): r""" Solve the single-diode equation to obtain a photovoltaic IV curve. Solves the single diode equation [1]_ .. math:: I = I_L - I_0 \left[ \exp \left(\frac{V+I R_s}{n N_s V_{th}} \right)-1 \right] - \frac{V + I R_s}{R_{sh}} for :math:`I` and :math:`V` when given :math:`I_L, I_0, R_s, R_{sh},` and :math:`n N_s V_{th}` which are described later. Returns a DataFrame which contains the 5 points on the I-V curve specified in [3]_. If all :math:`I_L, I_0, R_s, R_{sh},` and :math:`n N_s V_{th}` are scalar, a single curve is returned, if any are Series (of the same length), multiple IV curves are calculated. The input parameters can be calculated from meteorological data using a function for a single diode model, e.g., :py:func:`~pvlib.pvsystem.calcparams_desoto`. Parameters ---------- photocurrent : numeric Light-generated current :math:`I_L` (photocurrent) ``0 <= photocurrent``. [A] saturation_current : numeric Diode saturation :math:`I_0` current under desired IV curve conditions. ``0 < saturation_current``. [A] resistance_series : numeric Series resistance :math:`R_s` under desired IV curve conditions. ``0 <= resistance_series < numpy.inf``. [ohm] resistance_shunt : numeric Shunt resistance :math:`R_{sh}` under desired IV curve conditions. ``0 < resistance_shunt <= numpy.inf``. [ohm] nNsVth : numeric The product of three components: 1) the usual diode ideality factor :math:`n`, 2) the number of cells in series :math:`N_s`, and 3) the cell thermal voltage :math:`V_{th}`. The thermal voltage of the cell (in volts) may be calculated as :math:`k_B T_c / q`, where :math:`k_B` is Boltzmann's constant (J/K), :math:`T_c` is the temperature of the p-n junction in Kelvin, and :math:`q` is the charge of an electron (coulombs). ``0 < nNsVth``. [V] ivcurve_pnts : None or int, default None Number of points in the desired IV curve. If None or 0, no points on the IV curves will be produced. method : str, default 'lambertw' Determines the method used to calculate points on the IV curve. The options are ``'lambertw'``, ``'newton'``, or ``'brentq'``. Returns ------- OrderedDict or DataFrame The returned dict-like object always contains the keys/columns: * i_sc - short circuit current in amperes. * v_oc - open circuit voltage in volts. * i_mp - current at maximum power point in amperes. * v_mp - voltage at maximum power point in volts. * p_mp - power at maximum power point in watts. * i_x - current, in amperes, at ``v = 0.5*v_oc``. * i_xx - current, in amperes, at ``V = 0.5*(v_oc+v_mp)``. If ivcurve_pnts is greater than 0, the output dictionary will also include the keys: * i - IV curve current in amperes. * v - IV curve voltage in volts. The output will be an OrderedDict if photocurrent is a scalar, array, or ivcurve_pnts is not None. The output will be a DataFrame if photocurrent is a Series and ivcurve_pnts is None. See also -------- calcparams_desoto calcparams_cec calcparams_pvsyst sapm pvlib.singlediode.bishop88 Notes ----- If the method is ``'lambertw'`` then the solution employed to solve the implicit diode equation utilizes the Lambert W function to obtain an explicit function of :math:`V=f(I)` and :math:`I=f(V)` as shown in [2]_. If the method is ``'newton'`` then the root-finding Newton-Raphson method is used. It should be safe for well behaved IV-curves, but the ``'brentq'`` method is recommended for reliability. If the method is ``'brentq'`` then Brent's bisection search method is used that guarantees convergence by bounding the voltage between zero and open-circuit. If the method is either ``'newton'`` or ``'brentq'`` and ``ivcurve_pnts`` are indicated, then :func:`pvlib.singlediode.bishop88` [4]_ is used to calculate the points on the IV curve points at diode voltages from zero to open-circuit voltage with a log spacing that gets closer as voltage increases. If the method is ``'lambertw'`` then the calculated points on the IV curve are linearly spaced. References ---------- .. [1] S.R. Wenham, M.A. Green, M.E. Watt, "Applied Photovoltaics" ISBN 0 86758 909 4 .. [2] A. Jain, A. Kapoor, "Exact analytical solutions of the parameters of real solar cells using Lambert W-function", Solar Energy Materials and Solar Cells, 81 (2004) 269-277. .. [3] D. King et al, "Sandia Photovoltaic Array Performance Model", SAND2004-3535, Sandia National Laboratories, Albuquerque, NM .. [4] "Computer simulation of the effects of electrical mismatches in photovoltaic cell interconnection circuits" JW Bishop, Solar Cell (1988) https://doi.org/10.1016/0379-6787(88)90059-2 """ # Calculate points on the IV curve using the LambertW solution to the # single diode equation if method.lower() == 'lambertw': out = _singlediode._lambertw( photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth, ivcurve_pnts ) i_sc, v_oc, i_mp, v_mp, p_mp, i_x, i_xx = out[:7] if ivcurve_pnts: ivcurve_i, ivcurve_v = out[7:] else: # Calculate points on the IV curve using either 'newton' or 'brentq' # methods. Voltages are determined by first solving the single diode # equation for the diode voltage V_d then backing out voltage args = (photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth) # collect args v_oc = _singlediode.bishop88_v_from_i( 0.0, *args, method=method.lower() ) i_mp, v_mp, p_mp = _singlediode.bishop88_mpp( *args, method=method.lower() ) i_sc = _singlediode.bishop88_i_from_v( 0.0, *args, method=method.lower() ) i_x = _singlediode.bishop88_i_from_v( v_oc / 2.0, *args, method=method.lower() ) i_xx = _singlediode.bishop88_i_from_v( (v_oc + v_mp) / 2.0, *args, method=method.lower() ) # calculate the IV curve if requested using bishop88 if ivcurve_pnts: vd = v_oc * ( (11.0 - np.logspace(np.log10(11.0), 0.0, ivcurve_pnts)) / 10.0 ) ivcurve_i, ivcurve_v, _ = _singlediode.bishop88(vd, *args) out = OrderedDict() out['i_sc'] = i_sc out['v_oc'] = v_oc out['i_mp'] = i_mp out['v_mp'] = v_mp out['p_mp'] = p_mp out['i_x'] = i_x out['i_xx'] = i_xx if ivcurve_pnts: out['v'] = ivcurve_v out['i'] = ivcurve_i if isinstance(photocurrent, pd.Series) and not ivcurve_pnts: out = pd.DataFrame(out, index=photocurrent.index) return out
[docs]def max_power_point(photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth, d2mutau=0, NsVbi=np.Inf, method='brentq'): """ Given the single diode equation coefficients, calculates the maximum power point (MPP). Parameters ---------- photocurrent : numeric photo-generated current [A] saturation_current : numeric diode reverse saturation current [A] resistance_series : numeric series resitance [ohms] resistance_shunt : numeric shunt resitance [ohms] nNsVth : numeric product of thermal voltage ``Vth`` [V], diode ideality factor ``n``, and number of serices cells ``Ns`` d2mutau : numeric, default 0 PVsyst parameter for cadmium-telluride (CdTe) and amorphous-silicon (a-Si) modules that accounts for recombination current in the intrinsic layer. The value is the ratio of intrinsic layer thickness squared :math:`d^2` to the diffusion length of charge carriers :math:`\\mu \\tau`. [V] NsVbi : numeric, default np.inf PVsyst parameter for cadmium-telluride (CdTe) and amorphous-silicon (a-Si) modules that is the product of the PV module number of series cells ``Ns`` and the builtin voltage ``Vbi`` of the intrinsic layer. [V]. method : str either ``'newton'`` or ``'brentq'`` Returns ------- OrderedDict or pandas.Datafrane ``(i_mp, v_mp, p_mp)`` Notes ----- Use this function when you only want to find the maximum power point. Use :func:`singlediode` when you need to find additional points on the IV curve. This function uses Brent's method by default because it is guaranteed to converge. """ i_mp, v_mp, p_mp = _singlediode.bishop88_mpp( photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth, d2mutau=0, NsVbi=np.Inf, method=method.lower() ) if isinstance(photocurrent, pd.Series): ivp = {'i_mp': i_mp, 'v_mp': v_mp, 'p_mp': p_mp} out = pd.DataFrame(ivp, index=photocurrent.index) else: out = OrderedDict() out['i_mp'] = i_mp out['v_mp'] = v_mp out['p_mp'] = p_mp return out
[docs]def v_from_i(resistance_shunt, resistance_series, nNsVth, current, saturation_current, photocurrent, method='lambertw'): ''' Device voltage at the given device current for the single diode model. Uses the single diode model (SDM) as described in, e.g., Jain and Kapoor 2004 [1]_. The solution is per Eq 3 of [1]_ except when resistance_shunt=numpy.inf, in which case the explict solution for voltage is used. Ideal device parameters are specified by resistance_shunt=np.inf and resistance_series=0. Inputs to this function can include scalars and pandas.Series, but it is the caller's responsibility to ensure that the arguments are all float64 and within the proper ranges. Parameters ---------- resistance_shunt : numeric Shunt resistance in ohms under desired IV curve conditions. Often abbreviated ``Rsh``. 0 < resistance_shunt <= numpy.inf resistance_series : numeric Series resistance in ohms under desired IV curve conditions. Often abbreviated ``Rs``. 0 <= resistance_series < numpy.inf nNsVth : numeric The product of three components. 1) The usual diode ideal factor (n), 2) the number of cells in series (Ns), and 3) the cell thermal voltage under the desired IV curve conditions (Vth). The thermal voltage of the cell (in volts) may be calculated as ``k*temp_cell/q``, where k is Boltzmann's constant (J/K), temp_cell is the temperature of the p-n junction in Kelvin, and q is the charge of an electron (coulombs). 0 < nNsVth current : numeric The current in amperes under desired IV curve conditions. saturation_current : numeric Diode saturation current in amperes under desired IV curve conditions. Often abbreviated ``I_0``. 0 < saturation_current photocurrent : numeric Light-generated current (photocurrent) in amperes under desired IV curve conditions. Often abbreviated ``I_L``. 0 <= photocurrent method : str Method to use: ``'lambertw'``, ``'newton'``, or ``'brentq'``. *Note*: ``'brentq'`` is limited to 1st quadrant only. Returns ------- current : np.ndarray or scalar References ---------- .. [1] A. Jain, A. Kapoor, "Exact analytical solutions of the parameters of real solar cells using Lambert W-function", Solar Energy Materials and Solar Cells, 81 (2004) 269-277. ''' if method.lower() == 'lambertw': return _singlediode._lambertw_v_from_i( resistance_shunt, resistance_series, nNsVth, current, saturation_current, photocurrent ) else: # Calculate points on the IV curve using either 'newton' or 'brentq' # methods. Voltages are determined by first solving the single diode # equation for the diode voltage V_d then backing out voltage args = (current, photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth) V = _singlediode.bishop88_v_from_i(*args, method=method.lower()) # find the right size and shape for returns size, shape = _singlediode._get_size_and_shape(args) if size <= 1: if shape is not None: V = np.tile(V, shape) if np.isnan(V).any() and size <= 1: V = np.repeat(V, size) if shape is not None: V = V.reshape(shape) return V
[docs]def i_from_v(resistance_shunt, resistance_series, nNsVth, voltage, saturation_current, photocurrent, method='lambertw'): ''' Device current at the given device voltage for the single diode model. Uses the single diode model (SDM) as described in, e.g., Jain and Kapoor 2004 [1]_. The solution is per Eq 2 of [1] except when resistance_series=0, in which case the explict solution for current is used. Ideal device parameters are specified by resistance_shunt=np.inf and resistance_series=0. Inputs to this function can include scalars and pandas.Series, but it is the caller's responsibility to ensure that the arguments are all float64 and within the proper ranges. Parameters ---------- resistance_shunt : numeric Shunt resistance in ohms under desired IV curve conditions. Often abbreviated ``Rsh``. 0 < resistance_shunt <= numpy.inf resistance_series : numeric Series resistance in ohms under desired IV curve conditions. Often abbreviated ``Rs``. 0 <= resistance_series < numpy.inf nNsVth : numeric The product of three components. 1) The usual diode ideal factor (n), 2) the number of cells in series (Ns), and 3) the cell thermal voltage under the desired IV curve conditions (Vth). The thermal voltage of the cell (in volts) may be calculated as ``k*temp_cell/q``, where k is Boltzmann's constant (J/K), temp_cell is the temperature of the p-n junction in Kelvin, and q is the charge of an electron (coulombs). 0 < nNsVth voltage : numeric The voltage in Volts under desired IV curve conditions. saturation_current : numeric Diode saturation current in amperes under desired IV curve conditions. Often abbreviated ``I_0``. 0 < saturation_current photocurrent : numeric Light-generated current (photocurrent) in amperes under desired IV curve conditions. Often abbreviated ``I_L``. 0 <= photocurrent method : str Method to use: ``'lambertw'``, ``'newton'``, or ``'brentq'``. *Note*: ``'brentq'`` is limited to 1st quadrant only. Returns ------- current : np.ndarray or scalar References ---------- .. [1] A. Jain, A. Kapoor, "Exact analytical solutions of the parameters of real solar cells using Lambert W-function", Solar Energy Materials and Solar Cells, 81 (2004) 269-277. ''' if method.lower() == 'lambertw': return _singlediode._lambertw_i_from_v( resistance_shunt, resistance_series, nNsVth, voltage, saturation_current, photocurrent ) else: # Calculate points on the IV curve using either 'newton' or 'brentq' # methods. Voltages are determined by first solving the single diode # equation for the diode voltage V_d then backing out voltage args = (voltage, photocurrent, saturation_current, resistance_series, resistance_shunt, nNsVth) current = _singlediode.bishop88_i_from_v(*args, method=method.lower()) # find the right size and shape for returns size, shape = _singlediode._get_size_and_shape(args) if size <= 1: if shape is not None: current = np.tile(current, shape) if np.isnan(current).any() and size <= 1: current = np.repeat(current, size) if shape is not None: current = current.reshape(shape) return current
[docs]def scale_voltage_current_power(data, voltage=1, current=1): """ Scales the voltage, current, and power in data by the voltage and current factors. Parameters ---------- data: DataFrame May contain columns `'v_mp', 'v_oc', 'i_mp' ,'i_x', 'i_xx', 'i_sc', 'p_mp'`. voltage: numeric, default 1 The amount by which to multiply the voltages. current: numeric, default 1 The amount by which to multiply the currents. Returns ------- scaled_data: DataFrame A scaled copy of the input data. `'p_mp'` is scaled by `voltage * current`. """ # as written, only works with a DataFrame # could make it work with a dict, but it would be more verbose voltage_keys = ['v_mp', 'v_oc'] current_keys = ['i_mp', 'i_x', 'i_xx', 'i_sc'] power_keys = ['p_mp'] voltage_df = data.filter(voltage_keys, axis=1) * voltage current_df = data.filter(current_keys, axis=1) * current power_df = data.filter(power_keys, axis=1) * voltage * current df = pd.concat([voltage_df, current_df, power_df], axis=1) df_sorted = df[data.columns] # retain original column order return df_sorted
[docs]def pvwatts_dc(g_poa_effective, temp_cell, pdc0, gamma_pdc, temp_ref=25.): r""" Implements NREL's PVWatts DC power model. The PVWatts DC model [1]_ is: .. math:: P_{dc} = \frac{G_{poa eff}}{1000} P_{dc0} ( 1 + \gamma_{pdc} (T_{cell} - T_{ref})) Note that the pdc0 is also used as a symbol in :py:func:`pvlib.inverter.pvwatts`. pdc0 in this function refers to the DC power of the modules at reference conditions. pdc0 in :py:func:`pvlib.inverter.pvwatts` refers to the DC power input limit of the inverter. Parameters ---------- g_poa_effective: numeric Irradiance transmitted to the PV cells. To be fully consistent with PVWatts, the user must have already applied angle of incidence losses, but not soiling, spectral, etc. [W/m^2] temp_cell: numeric Cell temperature [C]. pdc0: numeric Power of the modules at 1000 W/m^2 and cell reference temperature. [W] gamma_pdc: numeric The temperature coefficient of power. Typically -0.002 to -0.005 per degree C. [1/C] temp_ref: numeric, default 25.0 Cell reference temperature. PVWatts defines it to be 25 C and is included here for flexibility. [C] Returns ------- pdc: numeric DC power. References ---------- .. [1] A. P. Dobos, "PVWatts Version 5 Manual" http://pvwatts.nrel.gov/downloads/pvwattsv5.pdf (2014). """ # noqa: E501 pdc = (g_poa_effective * 0.001 * pdc0 * (1 + gamma_pdc * (temp_cell - temp_ref))) return pdc
[docs]def pvwatts_losses(soiling=2, shading=3, snow=0, mismatch=2, wiring=2, connections=0.5, lid=1.5, nameplate_rating=1, age=0, availability=3): r""" Implements NREL's PVWatts system loss model. The PVWatts loss model [1]_ is: .. math:: L_{total}(\%) = 100 [ 1 - \Pi_i ( 1 - \frac{L_i}{100} ) ] All parameters must be in units of %. Parameters may be array-like, though all array sizes must match. Parameters ---------- soiling: numeric, default 2 shading: numeric, default 3 snow: numeric, default 0 mismatch: numeric, default 2 wiring: numeric, default 2 connections: numeric, default 0.5 lid: numeric, default 1.5 Light induced degradation nameplate_rating: numeric, default 1 age: numeric, default 0 availability: numeric, default 3 Returns ------- losses: numeric System losses in units of %. References ---------- .. [1] A. P. Dobos, "PVWatts Version 5 Manual" http://pvwatts.nrel.gov/downloads/pvwattsv5.pdf (2014). """ params = [soiling, shading, snow, mismatch, wiring, connections, lid, nameplate_rating, age, availability] # manually looping over params allows for numpy/pandas to handle any # array-like broadcasting that might be necessary. perf = 1 for param in params: perf *= 1 - param/100 losses = (1 - perf) * 100. return losses
[docs]def dc_ohms_from_percent(vmp_ref, imp_ref, dc_ohmic_percent, modules_per_string=1, strings=1): """ Calculates the equivalent resistance of the wires from a percent ohmic loss at STC. Equivalent resistance is calculated with the function: .. math:: Rw = (L_{stc} / 100) * (Varray / Iarray) :math:`Rw` is the equivalent resistance in ohms :math:`Varray` is the Vmp of the modules times modules per string :math:`Iarray` is the Imp of the modules times strings per array :math:`L_{stc}` is the input dc loss percent Parameters ---------- vmp_ref: numeric Voltage at maximum power in reference conditions [V] imp_ref: numeric Current at maximum power in reference conditions [V] dc_ohmic_percent: numeric, default 0 input dc loss as a percent, e.g. 1.5% loss is input as 1.5 modules_per_string: int, default 1 Number of modules per string in the array. strings: int, default 1 Number of parallel strings in the array. Returns ---------- Rw: numeric Equivalent resistance [ohm] See Also -------- :py:func:`~pvlib.pvsystem.dc_ohmic_losses` References ---------- .. [1] PVsyst 7 Help. "Array ohmic wiring loss". https://www.pvsyst.com/help/ohmic_loss.htm """ vmp = modules_per_string * vmp_ref imp = strings * imp_ref Rw = (dc_ohmic_percent / 100) * (vmp / imp) return Rw
[docs]def dc_ohmic_losses(resistance, current): """ Returns ohmic losses in units of power from the equivalent resistance of the wires and the operating current. Parameters ---------- resistance: numeric Equivalent resistance of wires [ohm] current: numeric, float or array-like Operating current [A] Returns ---------- loss: numeric Power Loss [W] See Also -------- :py:func:`~pvlib.pvsystem.dc_ohms_from_percent` References ---------- .. [1] PVsyst 7 Help. "Array ohmic wiring loss". https://www.pvsyst.com/help/ohmic_loss.htm """ return resistance * current * current
[docs]def combine_loss_factors(index, *losses, fill_method='ffill'): r""" Combines Series loss fractions while setting a common index. The separate losses are compounded using the following equation: .. math:: L_{total} = 1 - [ 1 - \Pi_i ( 1 - L_i ) ] :math:`L_{total}` is the total loss returned :math:`L_i` is each individual loss factor input Note the losses must each be a series with a DatetimeIndex. All losses will be resampled to match the index parameter using the fill method specified (defaults to "fill forward"). Parameters ---------- index : DatetimeIndex The index of the returned loss factors *losses : Series One or more Series of fractions to be compounded fill_method : {'ffill', 'bfill', 'nearest'}, default 'ffill' Method to use for filling holes in reindexed DataFrame Returns ------- Series Fractions resulting from the combination of each loss factor """ combined_factor = 1 for loss in losses: loss = loss.reindex(index, method=fill_method) combined_factor *= (1 - loss) return 1 - combined_factor