Source code for pypowsybl.network.impl.network

#
# Copyright (c) 2020-2023, RTE (http://www.rte-france.com)
# This Source Code Form is subject to the terms of the Mozilla Public
# License, v. 2.0. If a copy of the MPL was not distributed with this
# file, You can obtain one at http://mozilla.org/MPL/2.0/.
# SPDX-License-Identifier: MPL-2.0
#
from __future__ import annotations  # Necessary for type alias like _DataFrame to work with sphinx

import io
import sys

import datetime
from datetime import timezone
import warnings
from typing import (
    Sequence,
    List,
    Set,
    Dict,
    Optional,
    Union,
    Any
)

from numpy import inf
from numpy.typing import ArrayLike
from pandas import DataFrame
import pandas as pd

import pypowsybl._pypowsybl as _pp
from pypowsybl._pypowsybl import ElementType, ValidationLevel
from pypowsybl.utils import (
    _adapt_df_or_kwargs,
    _create_c_dataframe,
    _create_properties_c_dataframe,
    _adapt_properties_kwargs,
    _get_c_dataframes,
    path_to_str, PathOrStr
)
from pypowsybl.report import ReportNode
from .bus_breaker_topology import BusBreakerTopology
from .node_breaker_topology import NodeBreakerTopology
from .sld_parameters import SldParameters
from .nad_parameters import NadParameters
from .svg import Svg
from .util import create_data_frame_from_series_array, ParamsDict

DEPRECATED_REPORTER_WARNING = "Use of deprecated attribute reporter. Use report_node instead."


[docs]class Network: # pylint: disable=too-many-public-methods def __init__(self, handle: _pp.JavaHandle): self._handle = handle self.__init_from_handle() self._nominal_apparent_power = 100.0 self._per_unit = False @property def id(self) -> str: """ ID of this network """ return self._id @property def name(self) -> str: """ Name of this network """ return self._name @property def source_format(self) -> str: """ Format of the source where this network came from. """ return self._source_format @property def case_date(self) -> datetime.datetime: """ Date of this network case, in UTC timezone. """ return self._case_date @property def forecast_distance(self) -> datetime.timedelta: """ The forecast distance: 0 for a snapshot. """ return self._forecast_distance @property def nominal_apparent_power(self) -> float: """ The nominal power to per unit the network (kVA) """ return self._nominal_apparent_power @nominal_apparent_power.setter def nominal_apparent_power(self, value: float) -> None: self._nominal_apparent_power = value @property def per_unit(self) -> bool: """ The nominal power to per unit the network (kVA) """ return self._per_unit @per_unit.setter def per_unit(self, value: bool) -> None: self._per_unit = value def __str__(self) -> str: return f'Network(id={self.id}, name={self.name}, case_date={self.case_date}, ' \ f'forecast_distance={self.forecast_distance}, source_format={self.source_format})' def __repr__(self) -> str: return str(self) def __getstate__(self) -> Dict[str, Any]: return {'biidm': self.save_to_binary_buffer('BIIDM', {}), 'per_unit': self._per_unit, 'nominal_apparent_power': self._nominal_apparent_power} def __setstate__(self, state: Dict[str, Any]) -> None: self._handle = _pp.load_network_from_binary_buffers([state['biidm'].getbuffer()], {}, [], None) self._per_unit = state['per_unit'] self._nominal_apparent_power = state['nominal_apparent_power'] self.__init_from_handle() def __init_from_handle(self) -> None: att = _pp.get_network_metadata(self._handle) self._id = att.id self._name = att.name self._source_format = att.source_format self._forecast_distance = datetime.timedelta(minutes=att.forecast_distance) self._case_date = datetime.datetime.fromtimestamp(att.case_date, timezone.utc)
[docs] def open_switch(self, id: str) -> bool: return _pp.update_switch_position(self._handle, id, True)
[docs] def close_switch(self, id: str) -> bool: return _pp.update_switch_position(self._handle, id, False)
[docs] def connect(self, id: str) -> bool: return _pp.update_connectable_status(self._handle, id, True)
[docs] def disconnect(self, id: str) -> bool: return _pp.update_connectable_status(self._handle, id, False)
[docs] def dump(self, file: PathOrStr, format: str = 'XIIDM', parameters: ParamsDict = None, reporter: ReportNode = None) -> None: """ .. deprecated:: 1.1.0 Use :meth:`save` instead. """ warnings.warn("dump is deprecated, use save instead", DeprecationWarning) self.save(file, format, parameters, reporter)
[docs] def save(self, file: PathOrStr, format: str = 'XIIDM', parameters: ParamsDict = None, reporter: ReportNode = None, report_node: ReportNode = None) -> None: """ Save a network to a file using the specified format. Basic compression formats are also supported: for example if file name ends with '.gz', the resulting files will be gzipped. Args: file: path to the exported file format: format to save the network, defaults to 'XIIDM' parameters: a dictionary of export parameters reporter: deprecated, use report_node instead report_node: the reporter to be used to create an execution report, default is None (no report) Examples: Various usage examples: .. code-block:: python network.save('network.xiidm') network.save('network.xiidm.gz') # produces a gzipped file network.save('/path/to/network.uct', format='UCTE') """ if reporter is not None: warnings.warn(DEPRECATED_REPORTER_WARNING, DeprecationWarning) report_node = reporter file = path_to_str(file) if parameters is None: parameters = {} _pp.save_network(self._handle, file, format, parameters, None if report_node is None else report_node._report_node) # pylint: disable=protected-access
[docs] def dump_to_string(self, format: str = 'XIIDM', parameters: ParamsDict = None, reporter: ReportNode = None) -> str: """ .. deprecated:: 1.1.0 Use :meth:`save_to_string` instead. """ warnings.warn("dump_to_string is deprecated, use save_to_string instead", DeprecationWarning) return self.save_to_string(format, parameters, reporter)
[docs] def save_to_string(self, format: str = 'XIIDM', parameters: ParamsDict = None, reporter: ReportNode = None, report_node: ReportNode = None) -> str: """ Save a network to a string using a specified format. Args: format: format to export, only support mono file type, defaults to 'XIIDM' parameters: a dictionary of export parameters reporter: deprecated, use report_node instead report_node: the reporter to be used to create an execution report, default is None (no report) Returns: A string representing this network """ if reporter is not None: warnings.warn(DEPRECATED_REPORTER_WARNING, DeprecationWarning) report_node = reporter if parameters is None: parameters = {} return _pp.save_network_to_string(self._handle, format, parameters, None if report_node is None else report_node._report_node) # pylint: disable=protected-access
[docs] def save_to_binary_buffer(self, format: str = 'XIIDM', parameters: ParamsDict = None, reporter: ReportNode = None, report_node: ReportNode = None) -> io.BytesIO: """ Save a network to a binary buffer using a specified format. In the current implementation, whatever the specified format is (so a format creating a single file or a format creating multiple files), the created binary buffer is a zip file. Args: format: format to export, only support mono file type, defaults to 'XIIDM' parameters: a dictionary of export parameters reporter: deprecated, use report_node instead report_node: the reporter to be used to create an execution report, default is None (no report) Returns: A BytesIO data buffer representing this network """ if reporter is not None: warnings.warn(DEPRECATED_REPORTER_WARNING, DeprecationWarning) report_node = reporter if parameters is None: parameters = {} return io.BytesIO(_pp.save_network_to_binary_buffer(self._handle, format, parameters, None if report_node is None else report_node._report_node)) # pylint: disable=protected-access
[docs] def reduce(self, v_min: float = 0, v_max: float = sys.float_info.max, ids: List[str] = None, vl_depths: tuple = (), with_dangling_lines: bool = False) -> None: """ Reduce to a smaller network according to the following parameters :param v_min: minimum voltage of the voltage levels kept after reducing :param v_max: voltage maximum of the voltage levels kept after reducing :param ids: ids of the voltage levels that will be kept :param vl_depths: depth around voltage levels which are indicated by their id, that will be kept :param with_dangling_lines: keeping the dangling lines """ if ids is None: ids = [] vls = [] depths = [] for v in vl_depths: vls.append(v[0]) depths.append(v[1]) _pp.reduce_network(self._handle, v_min, v_max, ids, vls, depths, with_dangling_lines)
[docs] def write_single_line_diagram_svg(self, container_id: str, svg_file: PathOrStr, metadata_file: PathOrStr = None, parameters: SldParameters = None) -> None: """ Create a single line diagram in SVG format from a voltage level or a substation and write to a file. Args: container_id: a voltage level id or a substation id svg_file: a svg file path metadata_file: a json metadata file path parameters: single-line diagram parameters to adjust the rendering of the diagram """ svg_file = path_to_str(svg_file) p = parameters._to_c_parameters() if parameters is not None else _pp.SldParameters() # pylint: disable=protected-access _pp.write_single_line_diagram_svg(self._handle, container_id, svg_file, '' if metadata_file is None else path_to_str(metadata_file), p)
[docs] def write_matrix_multi_substation_single_line_diagram_svg(self, matrix_ids: List[List[str]], svg_file: PathOrStr, metadata_file: PathOrStr = None, parameters: SldParameters = None) -> None: """ Create a single line diagram in SVG format from a voltage level or a substation and write to a file. Args: matrix_ids: a two-dimensional list of substation id svg_file: a svg file path metadata_file: a json metadata file path parameters: single-line diagram parameters to adjust the rendering of the diagram """ svg_file = path_to_str(svg_file) p = parameters._to_c_parameters() if parameters is not None else _pp.SldParameters() # pylint: disable=protected-access _pp.write_matrix_multi_substation_single_line_diagram_svg(self._handle, matrix_ids, svg_file, '' if metadata_file is None else path_to_str( metadata_file), p)
[docs] def get_single_line_diagram(self, container_id: str, parameters: SldParameters = None) -> Svg: """ Create a single line diagram from a voltage level or a substation. Args: container_id: a voltage level id or a substation id parameters: single-line diagram parameters to adjust the rendering of the diagram Returns: the single line diagram """ p = parameters._to_c_parameters() if parameters is not None else _pp.SldParameters() # pylint: disable=protected-access svg_and_metadata: List[str] = _pp.get_single_line_diagram_svg_and_metadata(self._handle, container_id, p) return Svg(svg_and_metadata[0], svg_and_metadata[1])
[docs] def get_matrix_multi_substation_single_line_diagram(self, matrix_ids: List[List[str]], parameters: SldParameters = None) -> Svg: """ Create a single line diagram from multiple substations Args: matrix_ids: a two-dimensional list of substation id parameters:single-line diagram parameters to adjust the rendering of the diagram Returns: the single line diagram """ p = parameters._to_c_parameters() if parameters is not None else _pp.SldParameters() # pylint: disable=protected-access svg_and_metadata: List[str] = _pp.get_matrix_multi_substation_single_line_diagram_svg_and_metadata(self._handle, matrix_ids, p) return Svg(svg_and_metadata[0], svg_and_metadata[1])
[docs] def write_network_area_diagram_svg(self, svg_file: PathOrStr, voltage_level_ids: Union[str, List[str]] = None, depth: int = 0, high_nominal_voltage_bound: float = -1, low_nominal_voltage_bound: float = -1, edge_name_displayed: bool = False) -> None: """ .. deprecated:: 1.1.0 Use :class:`write_network_area_diagram` with `NadParameters` instead. Create a network area diagram in SVG format and write it to a file. Args: svg_file: a svg file path voltage_level_ids: the voltage level ID, center of the diagram (None for the full diagram) depth: the diagram depth around the voltage level high_nominal_voltage_bound: high bound to filter voltage level according to nominal voltage low_nominal_voltage_bound: low bound to filter voltage level according to nominal voltage edge_name_displayed: if true displays the edge's names """ nad_p = NadParameters(edge_name_displayed=edge_name_displayed) self.write_network_area_diagram(svg_file, voltage_level_ids, depth, high_nominal_voltage_bound, low_nominal_voltage_bound, nad_p)
def write_network_area_diagram(self, svg_file: PathOrStr, voltage_level_ids: Union[str, List[str]] = None, depth: int = 0, high_nominal_voltage_bound: float = -1, low_nominal_voltage_bound: float = -1, nad_parameters: NadParameters = None, metadata_file: PathOrStr = None) -> None: """ Create a network area diagram in SVG format and write it to a file. Args: svg_file: a svg file path metadata_file: a json metadata file path (optional) voltage_level_ids: the voltage level ID, center of the diagram (None for the full diagram) depth: the diagram depth around the voltage level high_nominal_voltage_bound: high bound to filter voltage level according to nominal voltage low_nominal_voltage_bound: low bound to filter voltage level according to nominal voltage nad_parameters: parameters for network area diagram """ svg_file = path_to_str(svg_file) if voltage_level_ids is None: voltage_level_ids = [] if isinstance(voltage_level_ids, str): voltage_level_ids = [voltage_level_ids] nad_p = nad_parameters._to_c_parameters() if nad_parameters is not None else _pp.NadParameters() # pylint: disable=protected-access _pp.write_network_area_diagram_svg(self._handle, svg_file, '' if metadata_file is None else path_to_str(metadata_file), voltage_level_ids, depth, high_nominal_voltage_bound, low_nominal_voltage_bound, nad_p)
[docs] def get_network_area_diagram(self, voltage_level_ids: Union[str, List[str]] = None, depth: int = 0, high_nominal_voltage_bound: float = -1, low_nominal_voltage_bound: float = -1, nad_parameters: NadParameters = None) -> Svg: """ Create a network area diagram. Args: voltage_level_ids: the voltage level IDs, centers of the diagram (None for the full diagram) depth: the diagram depth around the voltage level high_nominal_voltage_bound: high bound to filter voltage level according to nominal voltage low_nominal_voltage_bound: low bound to filter voltage level according to nominal voltage nad_parameters: parameters for network area diagram Returns: the network area diagram """ if voltage_level_ids is None: voltage_level_ids = [] if isinstance(voltage_level_ids, str): voltage_level_ids = [voltage_level_ids] nad_p = nad_parameters._to_c_parameters() if nad_parameters is not None else _pp.NadParameters() # pylint: disable=protected-access svg_and_metadata: List[str] = _pp.get_network_area_diagram_svg_and_metadata(self._handle, voltage_level_ids, depth, high_nominal_voltage_bound, low_nominal_voltage_bound, nad_p) return Svg(svg_and_metadata[0], svg_and_metadata[1])
[docs] def get_network_area_diagram_displayed_voltage_levels(self, voltage_level_ids: Union[str, List[str]], depth: int = 0) -> List[str]: """ Gathers the name of the displayed voltage levels of a network-area diagram in a list, according to the input voltage level(s) and the depth of the diagram. Args: voltage_level_ids: the voltage level ID(s), center(s) of the diagram depth: the diagram depth around the voltage level Returns: a list of the displayed voltage levels """ if isinstance(voltage_level_ids, str): voltage_level_ids = [voltage_level_ids] return _pp.get_network_area_diagram_displayed_voltage_levels(self._handle, voltage_level_ids, depth)
def get_elements_ids(self, element_type: ElementType, nominal_voltages: Set[float] = None, countries: Set[str] = None, main_connected_component: bool = True, main_synchronous_component: bool = True, not_connected_to_same_bus_at_both_sides: bool = False) -> List[str]: return _pp.get_network_elements_ids(self._handle, element_type, [] if nominal_voltages is None else list(nominal_voltages), [] if countries is None else list(countries), main_connected_component, main_synchronous_component, not_connected_to_same_bus_at_both_sides) def get_elements(self, element_type: ElementType, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: """ Get network elements as a :class:`~pandas.DataFrame` for a specified element type. Args: element_type: the element type all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 optional parameters are mutually exclusive. If no optional parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Keyword Args: kwargs: the data to be selected, as named arguments. Returns: a network elements dataframe for the specified element type """ filter_attributes = _pp.FilterAttributesType.DEFAULT_ATTRIBUTES if all_attributes: filter_attributes = _pp.FilterAttributesType.ALL_ATTRIBUTES elif attributes is not None: filter_attributes = _pp.FilterAttributesType.SELECTION_ATTRIBUTES if attributes is None: attributes = [] if all_attributes and len(attributes) > 0: raise RuntimeError('parameters "all_attributes" and "attributes" are mutually exclusive') if kwargs: metadata = _pp.get_network_elements_dataframe_metadata(element_type) df = _adapt_df_or_kwargs(metadata, None, **kwargs) elements_array = _create_c_dataframe(df, metadata) else: elements_array = None series_array = _pp.create_network_elements_series_array(self._handle, element_type, filter_attributes, attributes, elements_array, self._per_unit, self._nominal_apparent_power) result = create_data_frame_from_series_array(series_array) if attributes: result = result[attributes] return result def get_sub_networks(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: """ Get a dataframe of sub networks Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. Returns: A dataframe of sub networks. """ return self.get_elements(ElementType.SUB_NETWORK, all_attributes, attributes, **kwargs) def get_sub_network(self, sub_network_id: str) -> Network: """ Get a sub network from its parent network. Args: sub_network_id: the id of the sub network Returns: The sub network. """ return Network(_pp.get_sub_network(self._handle, sub_network_id)) def detach(self) -> None: """ Detach a sub network from its parent network. """ self._handle = _pp.detach_sub_network(self._handle)
[docs] def get_buses(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of buses from the bus view. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of buses from the bus view Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **v_mag**: Get the voltage magnitude of the bus (in kV) - **v_angle**: the voltage angle of the bus (in degree) - **connected_component**: the number of terminals connected to this bus - **synchronous_component**: the number of synchronous components that the bus is part of - **voltage_level_id**: at which substation the bus is connected This dataframe is indexed on the bus ID. Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_buses() It outputs something like: ======= ======== ======= =================== ===================== ================ \ v_mag v_angle connected_component synchronous_component voltage_level_id ======= ======== ======= =================== ===================== ================ id S1VL1_0 224.6139 2.2822 0 1 S1VL1 S1VL2_0 400.0000 0.0000 0 1 S1VL2 S2VL1_0 408.8470 0.7347 0 0 S2VL1 S3VL1_0 400.0000 0.0000 0 0 S3VL1 S4VL1_0 400.0000 -1.1259 0 0 S4VL1 ======= ======== ======= =================== ===================== ================ .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_buses(all_attributes=True) It outputs something like: ======= ======== ======= =================== ===================== ================ \ v_mag v_angle connected_component synchronous_component voltage_level_id ======= ======== ======= =================== ===================== ================ id S1VL1_0 224.6139 2.2822 0 1 S1VL1 S1VL2_0 400.0000 0.0000 0 1 S1VL2 S2VL1_0 408.8470 0.7347 0 0 S2VL1 S3VL1_0 400.0000 0.0000 0 0 S3VL1 S4VL1_0 400.0000 -1.1259 0 0 S4VL1 ======= ======== ======= =================== ===================== ================ .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_buses(attributes=['v_mag','v_angle','voltage_level_id']) It outputs something like: ======= ======== ======= ================ \ v_mag v_angle voltage_level_id ======= ======== ======= ================ id S1VL1_0 224.6139 2.2822 S1VL1 S1VL2_0 400.0000 0.0000 S1VL2 S2VL1_0 408.8470 0.7347 S2VL1 S3VL1_0 400.0000 0.0000 S3VL1 S4VL1_0 400.0000 -1.1259 S4VL1 ======= ======== ======= ================ """ return self.get_elements(ElementType.BUS, all_attributes, attributes, **kwargs)
def get_bus_breaker_view_buses(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of buses from the bus/breaker view. See :meth:`get_buses` for documentation as attributes are the same. """ return self.get_elements(ElementType.BUS_FROM_BUS_BREAKER_VIEW, all_attributes, attributes, **kwargs)
[docs] def get_generators(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of generators. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: the generators dataframe. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **energy_source**: the energy source used to fuel the generator - **target_p**: the target active value for the generator (in MW) - **max_p**: the maximum active value for the generator (MW) - **min_p**: the minimum active value for the generator (MW) - **max_q**: the maximum reactive value for the generator only if reactive_limits_kind is MIN_MAX (MVar) - **min_q**: the minimum reactive value for the generator only if reactive_limits_kind is MIN_MAX (MVar) - **max_q_at_target_p** (optional): the maximum reactive value for the generator for the target p specified (MVar) - **min_q_at_target_p** (optional): the minimum reactive value for the generator for the target p specified (MVar) - **max_q_at_p** (optional): the maximum reactive value for the generator at current p (MVar) - **min_q_at_p** (optional): the minimum reactive value for the generator at current p (MVar) - **rated_s**: The rated nominal power (MVA) - **reactive_limits_kind**: type of the reactive limit of the generator (can be MIN_MAX, CURVE or NONE) - **target_v**: the target voltage magnitude value for the generator (in kV) - **target_q**: the target reactive value for the generator (in MVAr) - **voltage_regulator_on**: ``True`` if the generator regulates voltage - **regulated_element_id**: the ID of the network element where voltage is regulated - **p**: the actual active production of the generator (``NaN`` if no loadflow has been computed) - **q**: the actual reactive production of the generator (``NaN`` if no loadflow has been computed) - **i**: the current on the generator, ``NaN`` if no loadflow has been computed (in A) - **voltage_level_id**: at which substation this generator is connected - **bus_id**: bus where this generator is connected - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this generator is connected - **node** (optional): node where this generator is connected, in node-breaker voltage levels - **connected**: ``True`` if the generator is connected to a bus - **fictitious** (optional): ``True`` if the generator is part of the model and not of the actual network This dataframe is indexed on the generator ID. Examples: .. code-block:: python net = pp.network.create_ieee14() net.get_generators() will output something like: ==== ============= ======== ====== ======= ======== ======== ==================== === === ================ ====== \ energy_source target_p max_p min_p target_v target_q voltage_regulator_on p q voltage_level_id bus_id ==== ============= ======== ====== ======= ======== ======== ==================== === === ================ ====== id B1-G OTHER 232.4 9999.0 -9999.0 1.060 -16.9 True NaN NaN VL1 VL1_0 B2-G OTHER 40.0 9999.0 -9999.0 1.045 42.4 True NaN NaN VL2 VL2_0 B3-G OTHER 0.0 9999.0 -9999.0 1.010 23.4 True NaN NaN VL3 VL3_0 B6-G OTHER 0.0 9999.0 -9999.0 1.070 12.2 True NaN NaN VL6 VL6_0 B8-G OTHER 0.0 9999.0 -9999.0 1.090 17.4 True NaN NaN VL8 VL8_0 ==== ============= ======== ====== ======= ======== ======== ==================== === === ================ ====== .. code-block:: python net = pp.network.create_ieee14() net.get_generators(all_attributes=True) will output something like: ==== ============= ======== ====== ======= ======== ======== ==================== === === ================ ====== \ energy_source target_p max_p min_p target_v target_q voltage_regulator_on p q voltage_level_id bus_id ==== ============= ======== ====== ======= ======== ======== ==================== === === ================ ====== id B1-G OTHER 232.4 9999.0 -9999.0 1.060 -16.9 True NaN NaN VL1 VL1_0 B2-G OTHER 40.0 9999.0 -9999.0 1.045 42.4 True NaN NaN VL2 VL2_0 B3-G OTHER 0.0 9999.0 -9999.0 1.010 23.4 True NaN NaN VL3 VL3_0 B6-G OTHER 0.0 9999.0 -9999.0 1.070 12.2 True NaN NaN VL6 VL6_0 B8-G OTHER 0.0 9999.0 -9999.0 1.090 17.4 True NaN NaN VL8 VL8_0 ==== ============= ======== ====== ======= ======== ======== ==================== === === ================ ====== .. code-block:: python net = pp.network.create_ieee14() net.get_generators(attributes=['energy_source','target_p','max_p','min_p','p','voltage_level_id','bus_id']) will output something like: ==== ============= ======== ====== ======= === ================ ====== \ energy_source target_p max_p min_p p voltage_level_id bus_id ==== ============= ======== ====== ======= === ================ ====== id B1-G OTHER 232.4 9999.0 -9999.0 NaN VL1 VL1_0 B2-G OTHER 40.0 9999.0 -9999.0 NaN VL2 VL2_0 B3-G OTHER 0.0 9999.0 -9999.0 NaN VL3 VL3_0 B6-G OTHER 0.0 9999.0 -9999.0 NaN VL6 VL6_0 B8-G OTHER 0.0 9999.0 -9999.0 NaN VL8 VL8_0 ==== ============= ======== ====== ======= === ================ ====== .. warning:: The "generator convention" is used for the "input" columns (`target_p`, `max_p`, `min_p`, `target_v` and `target_q`) while the "load convention" is used for the ouput columns (`p` and `q`). Most of the time, this means that `p` and `target_p` will have opposite sign. This also entails that `p` can be lower than `min_p`. Actually, the relation: :math:`\\text{min_p} <= -p <= \\text{max_p}` should hold. """ return self.get_elements(ElementType.GENERATOR, all_attributes, attributes, **kwargs)
[docs] def get_loads(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of loads. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: the loads dataframe Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **type**: type of load - **p0**: the active load consumption setpoint (MW) - **q0**: the reactive load consumption setpoint (MVAr) - **p**: the result active load consumption, it is ``NaN`` is not loadflow has been computed (MW) - **q**: the result reactive load consumption, it is ``NaN`` is not loadflow has been computed (MVAr) - **i**: the current on the load, ``NaN`` if no loadflow has been computed (in A) - **voltage_level_id**: at which substation this load is connected - **bus_id**: bus where this load is connected - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this load is connected - **node** (optional): node where this load is connected, in node-breaker voltage levels - **connected**: ``True`` if the load is connected to a bus - **fictitious** (optional): ``True`` if the load is part of the model and not of the actual network This dataframe is indexed on the load ID. Examples: .. code-block:: python net = pp.network.create_ieee14() net.get_loads() will output something like: ===== ========== ===== ===== === === ================ ======= ========= \ type p0 q0 p q voltage_level_id bus_id connected ===== ========== ===== ===== === === ================ ======= ========= id B2-L UNDEFINED 21.7 12.7 NaN NaN VL2 VL2_0 True B3-L UNDEFINED 94.2 19.0 NaN NaN VL3 VL3_0 True B4-L UNDEFINED 47.8 -3.9 NaN NaN VL4 VL4_0 True B5-L UNDEFINED 7.6 1.6 NaN NaN VL5 VL5_0 True B6-L UNDEFINED 11.2 7.5 NaN NaN VL6 VL6_0 True B9-L UNDEFINED 29.5 16.6 NaN NaN VL9 VL9_0 True B10-L UNDEFINED 9.0 5.8 NaN NaN VL10 VL10_0 True B11-L UNDEFINED 3.5 1.8 NaN NaN VL11 VL11_0 True B12-L UNDEFINED 6.1 1.6 NaN NaN VL12 VL12_0 True B13-L UNDEFINED 13.5 5.8 NaN NaN VL13 VL13_0 True B14-L UNDEFINED 14.9 5.0 NaN NaN VL14 VL14_0 True ===== ========== ===== ===== === === ================ ======= ========= .. code-block:: python net = pp.network.create_ieee14() net.get_loads(all_attributes=True) will output something like: ===== ========== ===== ===== === === ================ ======= ========= \ type p0 q0 p q voltage_level_id bus_id connected ===== ========== ===== ===== === === ================ ======= ========= id B2-L UNDEFINED 21.7 12.7 NaN NaN VL2 VL2_0 True B3-L UNDEFINED 94.2 19.0 NaN NaN VL3 VL3_0 True B4-L UNDEFINED 47.8 -3.9 NaN NaN VL4 VL4_0 True B5-L UNDEFINED 7.6 1.6 NaN NaN VL5 VL5_0 True B6-L UNDEFINED 11.2 7.5 NaN NaN VL6 VL6_0 True B9-L UNDEFINED 29.5 16.6 NaN NaN VL9 VL9_0 True B10-L UNDEFINED 9.0 5.8 NaN NaN VL10 VL10_0 True B11-L UNDEFINED 3.5 1.8 NaN NaN VL11 VL11_0 True B12-L UNDEFINED 6.1 1.6 NaN NaN VL12 VL12_0 True B13-L UNDEFINED 13.5 5.8 NaN NaN VL13 VL13_0 True B14-L UNDEFINED 14.9 5.0 NaN NaN VL14 VL14_0 True ===== ========== ===== ===== === === ================ ======= ========= .. code-block:: python net = pp.network.create_ieee14() net.get_loads(attributes=['type','p','q','voltage_level_id','bus_id','connected']) will output something like: ===== ========== === === ================ ======= ========= \ type p q voltage_level_id bus_id connected ===== ========== === === ================ ======= ========= id B2-L UNDEFINED NaN NaN VL2 VL2_0 True B3-L UNDEFINED NaN NaN VL3 VL3_0 True B4-L UNDEFINED NaN NaN VL4 VL4_0 True B5-L UNDEFINED NaN NaN VL5 VL5_0 True B6-L UNDEFINED NaN NaN VL6 VL6_0 True B9-L UNDEFINED NaN NaN VL9 VL9_0 True B10-L UNDEFINED NaN NaN VL10 VL10_0 True B11-L UNDEFINED NaN NaN VL11 VL11_0 True B12-L UNDEFINED NaN NaN VL12 VL12_0 True B13-L UNDEFINED NaN NaN VL13 VL13_0 True B14-L UNDEFINED NaN NaN VL14 VL14_0 True ===== ========== === === ================ ======= ========= """ return self.get_elements(ElementType.LOAD, all_attributes, attributes, **kwargs)
[docs] def get_batteries(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of batteries. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of batteries. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **name**: type of load - **max_p**: the maximum active value for the battery (MW) - **min_p**: the minimum active value for the battery (MW) - **min_q**: the maximum reactive value for the battery only if reactive_limits_kind is MIN_MAX (MVar) - **max_q**: the minimum reactive value for the battery only if reactive_limits_kind is MIN_MAX (MVar) - **target_p**: The active power setpoint (MW) - **target_q**: The reactive power setpoint (MVAr) - **p**: the result active battery consumption, it is ``NaN`` is not loadflow has been computed (MW) - **q**: the result reactive battery consumption, it is ``NaN`` is not loadflow has been computed (MVAr) - **i**: the current on the battery, ``NaN`` if no loadflow has been computed (in A) - **voltage_level_id**: at which substation this load is connected - **bus_id**: bus where this load is connected - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this battery is connected - **node** (optional): node where this battery is connected, in node-breaker voltage levels - **connected**: ``True`` if the battery is connected to a bus - **fictitious** (optional): ``True`` if the battery is part of the model and not of the actual network This dataframe is indexed on the battery ID. """ return self.get_elements(ElementType.BATTERY, all_attributes, attributes, **kwargs)
[docs] def get_lines(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of lines data. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of lines data. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **r**: the resistance of the line (in Ohm) - **x**: the reactance of the line (in Ohm) - **g1**: the conductance of line at its "1" side (in Siemens) - **b1**: the susceptance of line at its "1" side (in Siemens) - **g2**: the conductance of line at its "2" side (in Siemens) - **b2**: the susceptance of line at its "2" side (in Siemens) - **p1**: the active flow on the line at its "1" side, ``NaN`` if no loadflow has been computed (in MW) - **q1**: the reactive flow on the line at its "1" side, ``NaN`` if no loadflow has been computed (in MVAr) - **i1**: the current on the line at its "1" side, ``NaN`` if no loadflow has been computed (in A) - **p2**: the active flow on the line at its "2" side, ``NaN`` if no loadflow has been computed (in MW) - **q2**: the reactive flow on the line at its "2" side, ``NaN`` if no loadflow has been computed (in MVAr) - **i2**: the current on the line at its "2" side, ``NaN`` if no loadflow has been computed (in A) - **voltage_level1_id**: voltage level where the line is connected, on side 1 - **voltage_level2_id**: voltage level where the line is connected, on side 2 - **bus1_id**: bus where this line is connected, on side 1 - **bus2_id**: bus where this line is connected, on side 2 - **bus_breaker_bus1_id** (optional): bus of the bus-breaker view where this line is connected, on side 1 - **bus_breaker_bus2_id** (optional): bus of the bus-breaker view where this line is connected, on side 2 - **node1** (optional): node where this line is connected on side 1, in node-breaker voltage levels - **node2** (optional): node where this line is connected on side 2, in node-breaker voltage levels - **connected1**: ``True`` if the side "1" of the line is connected to a bus - **connected2**: ``True`` if the side "2" of the line is connected to a bus - **fictitious** (optional): ``True`` if the line is part of the model and not of the actual network - **selected_limits_group_1** (optional): Name of the selected operational limits group selected for side 1 - **selected_limits_group_2** (optional): Name of the selected operational limits group selected for side 2 This dataframe is indexed by the id of the lines. Examples: .. code-block:: python net = pp.network.create_ieee14() net.get_lines() will output something like: ======== ======== ======== === ==== === ==== === === === === === === ================= ================= ======= ======= ========== ========== \ r x g1 b1 g2 b2 p1 q1 i1 p2 q2 i2 voltage_level1_id voltage_level2_id bus1_id bus2_id connected1 connected2 ======== ======== ======== === ==== === ==== === === === === === === ================= ================= ======= ======= ========== ========== id L1-2-1 0.000194 0.000592 0.0 2.64 0.0 2.64 NaN NaN NaN NaN NaN NaN VL1 VL2 VL1_0 VL2_0 True True L1-5-1 0.000540 0.002230 0.0 2.46 0.0 2.46 NaN NaN NaN NaN NaN NaN VL1 VL5 VL1_0 VL5_0 True True ======== ======== ======== === ==== === ==== === === === === === === ================= ================= ======= ======= ========== ========== .. code-block:: python net = pp.network.create_ieee14() net.get_lines(all_attributes=True) will output something like: ======== ======== ======== === ==== === ==== === === === === === === ================= ================= ======= ======= ========== ========== \ r x g1 b1 g2 b2 p1 q1 i1 p2 q2 i2 voltage_level1_id voltage_level2_id bus1_id bus2_id connected1 connected2 ======== ======== ======== === ==== === ==== === === === === === === ================= ================= ======= ======= ========== ========== id L1-2-1 0.000194 0.000592 0.0 2.64 0.0 2.64 NaN NaN NaN NaN NaN NaN VL1 VL2 VL1_0 VL2_0 True True L1-5-1 0.000540 0.002230 0.0 2.46 0.0 2.46 NaN NaN NaN NaN NaN NaN VL1 VL5 VL1_0 VL5_0 True True ======== ======== ======== === ==== === ==== === === === === === === ================= ================= ======= ======= ========== ========== .. code-block:: python net = pp.network.create_ieee14() net.get_lines(attributes=['p1','q1','i1','p2','q2','i2','voltage_level1_id','voltage_level2_id','bus1_id','bus2_id','connected1','connected2']) will output something like: ======== === === === === === === ================= ================= ======= ======= ========== ========== \ p1 q1 i1 p2 q2 i2 voltage_level1_id voltage_level2_id bus1_id bus2_id connected1 connected2 ======== === === === === === === ================= ================= ======= ======= ========== ========== id L1-2-1 NaN NaN NaN NaN NaN NaN VL1 VL2 VL1_0 VL2_0 True True L1-5-1 NaN NaN NaN NaN NaN NaN VL1 VL5 VL1_0 VL5_0 True True ======== === === === === === === ================= ================= ======= ======= ========== ========== """ return self.get_elements(ElementType.LINE, all_attributes, attributes, **kwargs)
[docs] def get_2_windings_transformers(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of 2 windings transformers. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of 2 windings transformers. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **r**: the resistance of the transformer at its "2" side (in Ohm) - **x**: the reactance of the transformer at its "2" side (in Ohm) - **b**: the susceptance of transformer at its "2" side (in Siemens) - **g**: the conductance of transformer at its "2" side (in Siemens) - **rated_u1**: The rated voltage of the transformer at side 1 (in kV) - **rated_u2**: The rated voltage of the transformer at side 2 (in kV) - **rated_s**: - **p1**: the active flow on the transformer at its "1" side, ``NaN`` if no loadflow has been computed (in MW) - **q1**: the reactive flow on the transformer at its "1" side, ``NaN`` if no loadflow has been computed (in MVAr) - **i1**: the current on the transformer at its "1" side, ``NaN`` if no loadflow has been computed (in A) - **p2**: the active flow on the transformer at its "2" side, ``NaN`` if no loadflow has been computed (in MW) - **q2**: the reactive flow on the transformer at its "2" side, ``NaN`` if no loadflow has been computed (in MVAr) - **i2**: the current on the transformer at its "2" side, ``NaN`` if no loadflow has been computed (in A) - **voltage_level1_id**: voltage level where the transformer is connected, on side 1 - **voltage_level2_id**: voltage level where the transformer is connected, on side 2 - **bus1_id**: bus where this transformer is connected, on side 1 - **bus2_id**: bus where this transformer is connected, on side 2 - **bus_breaker_bus1_id** (optional): bus of the bus-breaker view where this transformer is connected, on side 1 - **bus_breaker_bus2_id** (optional): bus of the bus-breaker view where this transformer is connected, on side 2 - **node1** (optional): node where this transformer is connected on side 1, in node-breaker voltage levels - **node2** (optional): node where this transformer is connected on side 2, in node-breaker voltage levels - **connected1**: ``True`` if the side "1" of the transformer is connected to a bus - **connected2**: ``True`` if the side "2" of the transformer is connected to a bus - **fictitious** (optional): ``True`` if the transformer is part of the model and not of the actual network - **selected_limits_group_1** (optional): Name of the selected operational limits group selected for side 1 - **selected_limits_group_2** (optional): Name of the selected operational limits group selected for side 2 This dataframe is indexed by the id of the two windings transformers Examples: .. code-block:: python net = pp.network.create_ieee14() net.get_2_windings_transformers() will output something like: ====== ==== ======== === === ======== ======== ======= === === === === === === ================= ================= ======= ======= ========== ========== \ r x g b rated_u1 rated_u2 rated_s p1 q1 i1 p2 q2 i2 voltage_level1_id voltage_level2_id bus1_id bus2_id connected1 connected2 ====== ==== ======== === === ======== ======== ======= === === === === === === ================= ================= ======= ======= ========== ========== id T4-7-1 0.0 0.409875 0.0 0.0 132.030 14.0 NaN NaN NaN NaN NaN NaN NaN VL4 VL7 VL4_0 VL7_0 True True T4-9-1 0.0 0.800899 0.0 0.0 130.815 12.0 NaN NaN NaN NaN NaN NaN NaN VL4 VL9 VL4_0 VL9_0 True True T5-6-1 0.0 0.362909 0.0 0.0 125.820 12.0 NaN NaN NaN NaN NaN NaN NaN VL5 VL6 VL5_0 VL6_0 True True ====== ==== ======== === === ======== ======== ======= === === === === === === ================= ================= ======= ======= ========== ========== .. code-block:: python net = pp.network.create_ieee14() net.get_2_windings_transformers(all_attributes=True) will output something like: ====== ==== ======== === === ======== ======== ======= === === === === === === ================= ================= ======= ======= ========== ========== \ r x g b rated_u1 rated_u2 rated_s p1 q1 i1 p2 q2 i2 voltage_level1_id voltage_level2_id bus1_id bus2_id connected1 connected2 ====== ==== ======== === === ======== ======== ======= === === === === === === ================= ================= ======= ======= ========== ========== id T4-7-1 0.0 0.409875 0.0 0.0 132.030 14.0 NaN NaN NaN NaN NaN NaN NaN VL4 VL7 VL4_0 VL7_0 True True T4-9-1 0.0 0.800899 0.0 0.0 130.815 12.0 NaN NaN NaN NaN NaN NaN NaN VL4 VL9 VL4_0 VL9_0 True True T5-6-1 0.0 0.362909 0.0 0.0 125.820 12.0 NaN NaN NaN NaN NaN NaN NaN VL5 VL6 VL5_0 VL6_0 True True ====== ==== ======== === === ======== ======== ======= === === === === === === ================= ================= ======= ======= ========== ========== .. code-block:: python net = pp.network.create_ieee14() net.get_2_windings_transformers(attributes=['p1','q1','i1','p2','q2','i2','voltage_level1_id','voltage_level2_id','bus1_id','bus2_id','connected1','connected2']) will output something like: ====== === === === === === === ================= ================= ======= ======= ========== ========== \ p1 q1 i1 p2 q2 i2 voltage_level1_id voltage_level2_id bus1_id bus2_id connected1 connected2 ====== === === === === === === ================= ================= ======= ======= ========== ========== id T4-7-1 NaN NaN NaN NaN NaN NaN VL4 VL7 VL4_0 VL7_0 True True T4-9-1 NaN NaN NaN NaN NaN NaN VL4 VL9 VL4_0 VL9_0 True True T5-6-1 NaN NaN NaN NaN NaN NaN VL5 VL6 VL5_0 VL6_0 True True ====== === === === === === === ================= ================= ======= ======= ========== ========== """ return self.get_elements(ElementType.TWO_WINDINGS_TRANSFORMER, all_attributes, attributes, **kwargs)
[docs] def get_3_windings_transformers(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of 3 windings transformers. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of 3 windings transformers. """ return self.get_elements(ElementType.THREE_WINDINGS_TRANSFORMER, all_attributes, attributes, **kwargs)
[docs] def get_shunt_compensators(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of shunt compensators. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of shunt compensators. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **model_type**: - **max_section_count**: The maximum number of sections that may be switched on - **section_count**: The current number of section that may be switched on - **p**: the active flow on the shunt, ``NaN`` if no loadflow has been computed (in MW) - **q**: the reactive flow on the shunt, ``NaN`` if no loadflow has been computed (in MVAr) - **i**: the current in the shunt, ``NaN`` if no loadflow has been computed (in A) - **voltage_level_id**: at which substation the shunt is connected - **bus_id**: bus where this shunt is connected - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this shunt is connected - **node** (optional): node where this shunt is connected, in node-breaker voltage levels - **connected**: ``True`` if the shunt is connected to a bus - **fictitious** (optional): ``True`` if the shunt is part of the model and not of the actual network This dataframe is indexed by the id of the shunt compensators Examples: .. code-block:: python net = pp.network.create_ieee14() net.get_shunt_compensators() will output something like: ===== ========== ================= ============= === === === ================ ====== ========= \ model_type max_section_count section_count p q i voltage_level_id bus_id connected ===== ========== ================= ============= === === === ================ ====== ========= id B9-SH LINEAR 1 1 NaN NaN NaN VL9 VL9_0 True ===== ========== ================= ============= === === === ================ ====== ========= .. code-block:: python net = pp.network.create_ieee14() net.get_shunt_compensators(all_attributes=True) will output something like: ===== ========== ================= ============= === === === ================ ====== ========= \ model_type max_section_count section_count p q i voltage_level_id bus_id connected ===== ========== ================= ============= === === === ================ ====== ========= id B9-SH LINEAR 1 1 NaN NaN NaN VL9 VL9_0 True ===== ========== ================= ============= === === === ================ ====== ========= .. code-block:: python net = pp.network.create_ieee14() net.get_shunt_compensators(attributes=['model_type','p','q','i','voltage_level_id','bus_id','connected']) will output something like: ===== ========== === === === ================ ====== ========= \ model_type p q i voltage_level_id bus_id connected ===== ========== === === === ================ ====== ========= id B9-SH LINEAR NaN NaN NaN VL9 VL9_0 True ===== ========== === === === ================ ====== ========= """ return self.get_elements(ElementType.SHUNT_COMPENSATOR, all_attributes, attributes, **kwargs)
[docs] def get_non_linear_shunt_compensator_sections(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of shunt compensators sections for non linear model. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Notes: The resulting dataframe will have the following columns: - **g**: the accumulated conductance in S if the section and all the previous ones are activated. - **b**: the accumulated susceptance in S if the section and all the previous ones are activated This dataframe is multi-indexed, by the tuple (id of shunt, section number). Returns: A dataframe of non linear model shunt compensators sections. """ return self.get_elements(ElementType.NON_LINEAR_SHUNT_COMPENSATOR_SECTION, all_attributes, attributes, **kwargs)
[docs] def get_linear_shunt_compensator_sections(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of shunt compensators sections for linear model. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **g_per_section**: the conductance per section in S - **b_per_section**: the susceptance per section in S - **max_section_count**: the maximum number of sections This dataframe is indexed by the shunt compensator ID. Returns: A dataframe of linear models of shunt compensators. """ return self.get_elements(ElementType.LINEAR_SHUNT_COMPENSATOR_SECTION, all_attributes, attributes, **kwargs)
[docs] def get_dangling_lines(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of dangling lines. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of dangling lines. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **r**: The resistance of the dangling line (Ohm) - **x**: The reactance of the dangling line (Ohm) - **g**: the conductance of dangling line (in Siemens) - **b**: the susceptance of dangling line (in Siemens) - **p0**: The active power setpoint - **q0**: The reactive power setpoint - **p**: active flow on the dangling line, ``NaN`` if no loadflow has been computed (in MW) - **q**: the reactive flow on the dangling line, ``NaN`` if no loadflow has been computed (in MVAr) - **i**: The current on the dangling line, ``NaN`` if no loadflow has been computed (in A) - **boundary_p** (optional): active flow on the dangling line at boundary bus side, ``NaN`` if no loadflow has been computed (in MW) - **boundary_q** (optional): reactive flow on the dangling line at boundary bus side, ``NaN`` if no loadflow has been computed (in MW) - **boundary_v_mag** (optional): voltage magnitude of the boundary bus, ``NaN`` if no loadflow has been computed (in kV) - **boundary_v_angle** (optional): voltage angle of the boundary bus, ``NaN`` if no loadflow has been computed (in degree) - **voltage_level_id**: at which substation the dangling line is connected - **bus_id**: bus where this line is connected - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this line is connected - **node** (optional): node where this line is connected, in node-breaker voltage levels - **connected**: ``True`` if the dangling line is connected to a bus - **fictitious** (optional): ``True`` if the dangling line is part of the model and not of the actual network - **pairing_key**: the pairing key associated to the dangling line, to be used for creating tie lines. - **ucte-xnode-code**: deprecated for pairing key. - **paired**: if the dangling line is paired with a tie line - **tie_line_id**: the ID of the tie line if the dangling line is paired This dataframe is indexed by the id of the dangling lines Examples: .. code-block:: python net = pp.network._create_dangling_lines_network() net.get_dangling_lines() will output something like: == ==== === ====== ======= ==== ==== === === === ================ ====== ========= \ r x g b p0 q0 p q i voltage_level_id bus_id connected == ==== === ====== ======= ==== ==== === === === ================ ====== ========= id DL 10.0 1.0 0.0001 0.00001 50.0 30.0 NaN NaN NaN VL VL_0 True == ==== === ====== ======= ==== ==== === === === ================ ====== ========= .. code-block:: python net = pp.network._create_dangling_lines_network() net.get_dangling_lines(all_attributes=True) will output something like: == ==== === ====== ======= ==== ==== === === === ================ ====== ========= \ r x g b p0 q0 p q i voltage_level_id bus_id connected == ==== === ====== ======= ==== ==== === === === ================ ====== ========= id DL 10.0 1.0 0.0001 0.00001 50.0 30.0 NaN NaN NaN VL VL_0 True == ==== === ====== ======= ==== ==== === === === ================ ====== ========= .. code-block:: python net = pp.network._create_dangling_lines_network() net.get_dangling_lines(attributes=['p','q','i','voltage_level_id','bus_id','connected']) will output something like: == === === === ================ ====== ========= \ p q i voltage_level_id bus_id connected == === === === ================ ====== ========= id DL NaN NaN NaN VL VL_0 True == === === === ================ ====== ========= """ return self.get_elements(ElementType.DANGLING_LINE, all_attributes, attributes, **kwargs)
[docs] def get_tie_lines(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of tie lines. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of tie lines. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **dangling_line1_id**: The ID of the first dangling line - **dangling_line2_id**: The ID of the second dangling line - **ucte_xnode_code**: The UCTE xnode code of the tie line, obtained from the dangling lines. - **fictitious** (optional): ``True`` if the tie line is part of the model and not of the actual network This dataframe is indexed by the id of the dangling lines """ return self.get_elements(ElementType.TIE_LINE, all_attributes, attributes, **kwargs)
[docs] def get_lcc_converter_stations(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of LCC converter stations. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of LCC converter stations. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **power_factor**: the power factor - **loss_factor**: the loss factor - **p**: active flow on the LCC converter station, ``NaN`` if no loadflow has been computed (in MW) - **q**: the reactive flow on the LCC converter station, ``NaN`` if no loadflow has been computed (in MVAr) - **i**: The current on the LCC converter station, ``NaN`` if no loadflow has been computed (in A) - **voltage_level_id**: at which substation the LCC converter station is connected - **bus_id**: bus where this station is connected - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this station is connected - **node** (optional): node where this station is connected, in node-breaker voltage levels - **connected**: ``True`` if the LCC converter station is connected to a bus - **fictitious** (optional): ``True`` if the LCC converter is part of the model and not of the actual network This dataframe is indexed by the id of the LCC converter Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_lcc_converter_stations() will output something like: ======== ============ =========== ====== === === ================ ======= ========= . power_factor loss_factor p q i voltage_level_id bus_id connected ======== ============ =========== ====== === === ================ ======= ========= id LCC1 0.6 1.1 80.88 NaN NaN S1VL2 S1VL2_0 True LCC2 0.6 1.1 -79.12 NaN NaN S3VL1 S3VL1_0 True ======== ============ =========== ====== === === ================ ======= ========= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_lcc_converter_stations(all_attributes=True) will output something like: ======== ============ =========== ====== === === ================ ======= ========= . power_factor loss_factor p q i voltage_level_id bus_id connected ======== ============ =========== ====== === === ================ ======= ========= id LCC1 0.6 1.1 80.88 NaN NaN S1VL2 S1VL2_0 True LCC2 0.6 1.1 -79.12 NaN NaN S3VL1 S3VL1_0 True ======== ============ =========== ====== === === ================ ======= ========= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_lcc_converter_stations(attributes=['p','q','i','voltage_level_id','bus_id','connected']) will output something like: ======== ====== === === ================ ======= ========= . p q i voltage_level_id bus_id connected ======== ====== === === ================ ======= ========= id LCC1 80.88 NaN NaN S1VL2 S1VL2_0 True LCC2 -79.12 NaN NaN S3VL1 S3VL1_0 True ======== ====== === === ================ ======= ========= """ return self.get_elements(ElementType.LCC_CONVERTER_STATION, all_attributes, attributes, **kwargs)
[docs] def get_vsc_converter_stations(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of VSC converter stations. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of VCS converter stations. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **loss_factor**: correspond to the loss of power due to ac dc conversion - **target_v**: The voltage setpoint - **target_q**: The reactive power setpoint - **max_q**: the maximum reactive value for the generator only if reactive_limits_kind is MIN_MAX (MVar) - **min_q**: the minimum reactive value for the generator only if reactive_limits_kind is MIN_MAX (MVar) - **max_q_at_p** (optional): the maximum reactive value for the generator at current p (MVar) - **min_q_at_p** (optional): the minimum reactive value for the generator at current p (MVar) - **reactive_limits_kind**: type of the reactive limit of the vsc converter station (can be MIN_MAX, CURVE or NONE) - **voltage_regulator_on**: The voltage regulator status - **regulated_element_id**: The ID of the network element where voltage is regulated - **p**: active flow on the VSC converter station, ``NaN`` if no loadflow has been computed (in MW) - **q**: the reactive flow on the VSC converter station, ``NaN`` if no loadflow has been computed (in MVAr) - **i**: The current on the VSC converter station, ``NaN`` if no loadflow has been computed (in A) - **voltage_level_id**: at which substation the VSC converter station is connected - **bus_id**: bus where this station is connected - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this station is connected - **node** (optional): node where this station is connected, in node-breaker voltage levels - **connected**: ``True`` if the VSC converter station is connected to a bus - **fictitious** (optional): ``True`` if the VSC converter is part of the model and not of the actual network This dataframe is indexed by the id of the VSC converter Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_vsc_converter_stations() will output something like: ======== =========== ================ ======================= ==================== ==================== ====== ========= ========== ================ ======= ========= \ loss_factor voltage_setpoint reactive_power_setpoint voltage_regulator_on regulated_element_id p q i voltage_level_id bus_id connected ======== =========== ================ ======================= ==================== ==================== ====== ========= ========== ================ ======= ========= id VSC1 1.1 400.0 500.0 True VSC1 10.11 -512.0814 739.269871 S1VL2 S1VL2_0 True VSC2 1.1 0.0 120.0 False VSC2 -9.89 -120.0000 170.031658 S2VL1 S2VL1_0 True ======== =========== ================ ======================= ==================== ==================== ====== ========= ========== ================ ======= ========= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_vsc_converter_stations(all_attributes=True) will output something like: ======== =========== ================ ======================= ==================== ==================== ====== ========= ========== ================ ======= ========= \ loss_factor target_v target_q voltage_regulator_on regulated_element_id p q i voltage_level_id bus_id connected ======== =========== ================ ======================= ==================== ==================== ====== ========= ========== ================ ======= ========= id VSC1 1.1 400.0 500.0 True VSC1 10.11 -512.0814 739.269871 S1VL2 S1VL2_0 True VSC2 1.1 0.0 120.0 False VSC2 -9.89 -120.0000 170.031658 S2VL1 S2VL1_0 True ======== =========== ================ ======================= ==================== ==================== ====== ========= ========== ================ ======= ========= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_vsc_converter_stations(attributes=['p','q','i','voltage_level_id','bus_id','connected']) will output something like: ======== ====== ========= ========== ================ ======= ========= \ p q i voltage_level_id bus_id connected ======== ====== ========= ========== ================ ======= ========= id VSC1 10.11 -512.0814 739.269871 S1VL2 S1VL2_0 True VSC2 -9.89 -120.0000 170.031658 S2VL1 S2VL1_0 True ======== ====== ========= ========== ================ ======= ========= """ return self.get_elements(ElementType.VSC_CONVERTER_STATION, all_attributes, attributes, **kwargs)
[docs] def get_static_var_compensators(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of static var compensators. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of static var compensators. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **b_min**: the minimum susceptance - **b_max**: the maximum susceptance - **target_v**: The voltage setpoint - **target_q**: The reactive power setpoint - **regulation_mode**: The regulation mode - **regulated_element_id**: The ID of the network element where voltage is regulated - **p**: active flow on the var compensator, ``NaN`` if no loadflow has been computed (in MW) - **q**: the reactive flow on the var compensator, ``NaN`` if no loadflow has been computed (in MVAr) - **i**: The current on the var compensator, ``NaN`` if no loadflow has been computed (in A) - **voltage_level_id**: at which substation the var compensator is connected - **bus_id**: bus where this SVC is connected - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this SVC is connected - **node** (optional): node where this SVC is connected, in node-breaker voltage levels - **connected**: ``True`` if the var compensator is connected to a bus - **fictitious** (optional): ``True`` if the var compensator is part of the model and not of the actual network This dataframe is indexed by the id of the var compensator Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_static_var_compensators() will output something like: ======== ===== ===== ================ ======================= =============== ==================== === ======== === ================ ======= ========= \ b_min b_max target_v target_q regulation_mode regulated_element_id p q i voltage_level_id bus_id connected ======== ===== ===== ================ ======================= =============== ==================== === ======== === ================ ======= ========= id SVC -0.05 0.05 400.0 NaN VOLTAGE SVC NaN -12.5415 NaN S4VL1 S4VL1_0 True ======== ===== ===== ================ ======================= =============== ==================== === ======== === ================ ======= ========= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_static_var_compensators(all_attributes=True) will output something like: ======== ===== ===== ================ ======================= =============== ==================== === ======== === ================ ======= ========= \ b_min b_max voltage_setpoint reactive_power_setpoint regulation_mode regulated_element_id p q i voltage_level_id bus_id connected ======== ===== ===== ================ ======================= =============== ==================== === ======== === ================ ======= ========= id SVC -0.05 0.05 400.0 NaN VOLTAGE SVC NaN -12.5415 NaN S4VL1 S4VL1_0 True ======== ===== ===== ================ ======================= =============== ==================== === ======== === ================ ======= ========= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_static_var_compensators(attributes=['p','q','i','voltage_level_id','bus_id','connected']) will output something like: ======== === ======== === ================ ======= ========= \ p q i voltage_level_id bus_id connected ======== === ======== === ================ ======= ========= id SVC NaN -12.5415 NaN S4VL1 S4VL1_0 True ======== === ======== === ================ ======= ========= """ return self.get_elements(ElementType.STATIC_VAR_COMPENSATOR, all_attributes, attributes, **kwargs)
[docs] def get_voltage_levels(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of voltage levels. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of voltage levels. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **substation_id**: at which substation the voltage level belongs - **nominal_v**: The nominal voltage - **high_voltage_limit**: the high voltage limit - **low_voltage_limit**: the low voltage limit - **fictitious** (optional): ``True`` if the voltage level is part of the model and not of the actual network - **topology_kind** (optional): the voltage level topology kind (NODE_BREAKER or BUS_BREAKER) This dataframe is indexed by the id of the voltage levels Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_voltage_levels() will output something like: ========= ============= ========= ================== ================= \ substation_id nominal_v high_voltage_limit low_voltage_limit ========= ============= ========= ================== ================= id S1VL1 S1 225.0 240.0 220.0 S1VL2 S1 400.0 440.0 390.0 S2VL1 S2 400.0 440.0 390.0 S3VL1 S3 400.0 440.0 390.0 S4VL1 S4 400.0 440.0 390.0 ========= ============= ========= ================== ================= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_voltage_levels(all_attributes=True) will output something like: ========= ============= ========= ================== ================= \ substation_id nominal_v high_voltage_limit low_voltage_limit ========= ============= ========= ================== ================= id S1VL1 S1 225.0 240.0 220.0 S1VL2 S1 400.0 440.0 390.0 S2VL1 S2 400.0 440.0 390.0 S3VL1 S3 400.0 440.0 390.0 S4VL1 S4 400.0 440.0 390.0 ========= ============= ========= ================== ================= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_voltage_levels(attributes=['substation_id','nominal_v']) will output something like: ========= ============= ========= \ substation_id nominal_v ========= ============= ========= id S1VL1 S1 225.0 S1VL2 S1 400.0 S2VL1 S2 400.0 S3VL1 S3 400.0 S4VL1 S4 400.0 ========= ============= ========= """ return self.get_elements(ElementType.VOLTAGE_LEVEL, all_attributes, attributes, **kwargs)
[docs] def get_busbar_sections(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of busbar sections. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of busbar sections. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **fictitious** (optional): ``True`` if the busbar section is part of the model and not of the actual network - **v**: The voltage magnitude of the busbar section (in kV) - **angle**: the voltage angle of the busbar section (in degree) - **voltage_level_id**: at which substation the busbar section is connected - **bus_id**: bus this busbar section belongs to - **bus_breaker_bus_id** (optional): bus of the bus-breaker view this busbar section belongs to - **node** (optional): node associated to the this busbar section, in node-breaker voltage levels - **connected**: ``True`` if the busbar section is connected to a bus This dataframe is indexed by the id of the busbar sections Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_busbar_sections() will output something like: ========== ========== ======== ======== ================ ========= \ fictitious v angle voltage_level_id connected ========== ========== ======== ======== ================ ========= id S1VL1_BBS False 224.6139 2.2822 S1VL1 True S1VL2_BBS1 False 400.0000 0.0000 S1VL2 True S1VL2_BBS2 False 400.0000 0.0000 S1VL2 True S2VL1_BBS False 408.8470 0.7347 S2VL1 True S3VL1_BBS False 400.0000 0.0000 S3VL1 True S4VL1_BBS False 400.0000 -1.1259 S4VL1 True ========== ========== ======== ======== ================ ========= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_busbar_sections(all_attributes=True) will output something like: ========== ========== ======== ======== ================ ========= \ fictitious v angle voltage_level_id connected ========== ========== ======== ======== ================ ========= id S1VL1_BBS False 224.6139 2.2822 S1VL1 True S1VL2_BBS1 False 400.0000 0.0000 S1VL2 True S1VL2_BBS2 False 400.0000 0.0000 S1VL2 True S2VL1_BBS False 408.8470 0.7347 S2VL1 True S3VL1_BBS False 400.0000 0.0000 S3VL1 True S4VL1_BBS False 400.0000 -1.1259 S4VL1 True ========== ========== ======== ======== ================ ========= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_busbar_sections(attributes=['v','angle','voltage_level_id','connected']) will output something like: ========== ======== ======== ================ ========= \ v angle voltage_level_id connected ========== ======== ======== ================ ========= id S1VL1_BBS 224.6139 2.2822 S1VL1 True S1VL2_BBS1 400.0000 0.0000 S1VL2 True S1VL2_BBS2 400.0000 0.0000 S1VL2 True S2VL1_BBS 408.8470 0.7347 S2VL1 True S3VL1_BBS 400.0000 0.0000 S3VL1 True S4VL1_BBS 400.0000 -1.1259 S4VL1 True ========== ======== ======== ================ ========= """ return self.get_elements(ElementType.BUSBAR_SECTION, all_attributes, attributes, **kwargs)
[docs] def get_substations(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get substations :class:`~pandas.DataFrame`. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of substations. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **name**: the name of the substations - **TSO**: the TSO which the substation belongs to - **geo_tags**: additional geographical information about the substation - **country**: the country which the substation belongs to - **fictitious** (optional): ``True`` if the substation is part of the model and not of the actual network This dataframe is indexed on the substation ID. """ return self.get_elements(ElementType.SUBSTATION, all_attributes, attributes, **kwargs)
[docs] def get_hvdc_lines(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of HVDC lines. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of HVDC lines. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **converters_mode**: the mode of the converter stations. It can be either SIDE_1_RECTIFIER_SIDE_2_INVERTER or SIDE_1_INVERTER_SIDE_2_RECTIFIER - **target_p**: active power target (in MW) - **max_p**: the maximum of active power that can pass through the hvdc line (in MW) - **nominal_v**: nominal voltage (in kV) - **r**: the resistance of the hvdc line (in Ohm) - **converter_station1_id**: at which converter station the hvdc line is connected on side "1" - **converter_station2_id**: at which converter station the hvdc line is connected on side "2" - **connected1**: ``True`` if the busbar section on side "1" is connected to a bus - **connected2**: ``True`` if the busbar section on side "2" is connected to a bus - **fictitious** (optional): ``True`` if the hvdc is part of the model and not of the actual network This dataframe is indexed by the id of the hvdc lines Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_hvdc_lines() will output something like: ===== ================================ ===================== ===== ========= ==== ===================== ===================== ========== ========== \ converters_mode target_p max_p nominal_v r converter_station1_id converter_station2_id connected1 connected2 ===== ================================ ===================== ===== ========= ==== ===================== ===================== ========== ========== id HVDC1 SIDE_1_RECTIFIER_SIDE_2_INVERTER 10.0 300.0 400.0 1.0 VSC1 VSC2 True True HVDC2 SIDE_1_RECTIFIER_SIDE_2_INVERTER 80.0 300.0 400.0 1.0 LCC1 LCC2 True True ===== ================================ ===================== ===== ========= ==== ===================== ===================== ========== ========== .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_hvdc_lines(all_attributes=True) will output something like: ===== ================================ ===================== ===== ========= ==== ===================== ===================== ========== ========== \ converters_mode active_power_setpoint max_p nominal_v r converter_station1_id converter_station2_id connected1 connected2 ===== ================================ ===================== ===== ========= ==== ===================== ===================== ========== ========== id HVDC1 SIDE_1_RECTIFIER_SIDE_2_INVERTER 10.0 300.0 400.0 1.0 VSC1 VSC2 True True HVDC2 SIDE_1_RECTIFIER_SIDE_2_INVERTER 80.0 300.0 400.0 1.0 LCC1 LCC2 True True ===== ================================ ===================== ===== ========= ==== ===================== ===================== ========== ========== .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_hvdc_lines(attributes=['converters_mode','active_power_setpoint','nominal_v','converter_station1_id','converter_station2_id','connected1','connected2']) will output something like: ===== ================================ ===================== ========= ===================== ===================== ========== ========== \ converters_mode active_power_setpoint nominal_v converter_station1_id converter_station2_id connected1 connected2 ===== ================================ ===================== ========= ===================== ===================== ========== ========== id HVDC1 SIDE_1_RECTIFIER_SIDE_2_INVERTER 10.0 400.0 VSC1 VSC2 True True HVDC2 SIDE_1_RECTIFIER_SIDE_2_INVERTER 80.0 400.0 LCC1 LCC2 True True ===== ================================ ===================== ========= ===================== ===================== ========== ========== """ return self.get_elements(ElementType.HVDC_LINE, all_attributes, attributes, **kwargs)
[docs] def get_switches(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of switches. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of switches. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **kind**: the kind of switch - **open**: the open status of the switch - **retained**: the retain status of the switch - **voltage_level_id**: at which substation the switch is connected - **bus_breaker_bus1_id** (optional): bus where this switch is connected on side 1, in bus-breaker voltage levels - **bus_breaker_bus1_id** (optional): bus where this switch is connected on side 1, in bus-breaker voltage levels - **node1** (optional): node where this switch is connected on side 1, in node-breaker voltage levels - **node2** (optional): node where this switch is connected on side 2, in node-breaker voltage levels - **fictitious** (optional): ``True`` if the switch is part of the model and not of the actual network This dataframe is indexed by the id of the switches Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_switches() will output something like: ============================ ============ ====== ======== ================ \ kind open retained voltage_level_id ============================ ============ ====== ======== ================ id S1VL1_BBS_LD1_DISCONNECTOR DISCONNECTOR False False S1VL1 S1VL1_LD1_BREAKER BREAKER False True S1VL1 S1VL1_BBS_TWT_DISCONNECTOR DISCONNECTOR False False S1VL1 S1VL1_TWT_BREAKER BREAKER False True S1VL1 S1VL2_BBS1_TWT_DISCONNECTOR DISCONNECTOR False False S1VL2 S1VL2_BBS2_TWT_DISCONNECTOR DISCONNECTOR True False S1VL2 S1VL2_TWT_BREAKER BREAKER False True S1VL2 S1VL2_BBS1_VSC1_DISCONNECTOR DISCONNECTOR True False S1VL2 ... ... ... ... ... ============================ ============ ====== ======== ================ .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_switches(all_attributes=True) will output something like: ============================ ============ ====== ======== ================ \ kind open retained voltage_level_id ============================ ============ ====== ======== ================ id S1VL1_BBS_LD1_DISCONNECTOR DISCONNECTOR False False S1VL1 S1VL1_LD1_BREAKER BREAKER False True S1VL1 S1VL1_BBS_TWT_DISCONNECTOR DISCONNECTOR False False S1VL1 S1VL1_TWT_BREAKER BREAKER False True S1VL1 S1VL2_BBS1_TWT_DISCONNECTOR DISCONNECTOR False False S1VL2 S1VL2_BBS2_TWT_DISCONNECTOR DISCONNECTOR True False S1VL2 S1VL2_TWT_BREAKER BREAKER False True S1VL2 S1VL2_BBS1_VSC1_DISCONNECTOR DISCONNECTOR True False S1VL2 ... ... ... ... ... ============================ ============ ====== ======== ================ .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_switches(attributes=['kind','open','nominal_v','voltage_level_id']) will output something like: ============================ ============ ====== ================ \ kind open voltage_level_id ============================ ============ ====== ================ id S1VL1_BBS_LD1_DISCONNECTOR DISCONNECTOR False S1VL1 S1VL1_LD1_BREAKER BREAKER False S1VL1 S1VL1_BBS_TWT_DISCONNECTOR DISCONNECTOR False S1VL1 S1VL1_TWT_BREAKER BREAKER False S1VL1 S1VL2_BBS1_TWT_DISCONNECTOR DISCONNECTOR False S1VL2 S1VL2_BBS2_TWT_DISCONNECTOR DISCONNECTOR True S1VL2 S1VL2_TWT_BREAKER BREAKER False S1VL2 S1VL2_BBS1_VSC1_DISCONNECTOR DISCONNECTOR True S1VL2 ... ... ... ... ============================ ============ ====== ================ """ return self.get_elements(ElementType.SWITCH, all_attributes, attributes, **kwargs)
[docs] def get_ratio_tap_changer_steps(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of ratio tap changer steps. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of ratio tap changer steps. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **rho**: The voltage ratio in per unit of the rated voltages (in per unit) - **r**: The resistance deviation in percent of nominal value (%) - **x**: The reactance deviation in percent of nominal value (%) - **g**: The conductance deviation in percent of nominal value (%) - **b**: The susceptance deviation in percent of nominal value (%) This dataframe is index by the id of the transformer and the position of the ratio tap changer step Examples: .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_network() net.get_ratio_tap_changer_steps() will output something like: ========== ======== ======== === === === === \ rho r x g b ========== ======== ======== === === === === id position NHV2_NLOAD 0 0.850567 0.0 0.0 0.0 0.0 \ 1 1.000667 0.0 0.0 0.0 0.0 \ 2 1.150767 0.0 0.0 0.0 0.0 ========== ======== ======== === === === === .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_network() net.get_ratio_tap_changer_steps(all_attributes=True) will output something like: ========== ======== ======== === === === === \ rho r x g b ========== ======== ======== === === === === id position NHV2_NLOAD 0 0.850567 0.0 0.0 0.0 0.0 \ 1 1.000667 0.0 0.0 0.0 0.0 \ 2 1.150767 0.0 0.0 0.0 0.0 ========== ======== ======== === === === === .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_network() net.get_ratio_tap_changer_steps(attributes=['rho','r','x']) will output something like: ========== ======== ======== === === \ rho r x ========== ======== ======== === === id position NHV2_NLOAD 0 0.850567 0.0 0.0 \ 1 1.000667 0.0 0.0 \ 2 1.150767 0.0 0.0 ========== ======== ======== === === """ return self.get_elements(ElementType.RATIO_TAP_CHANGER_STEP, all_attributes, attributes, **kwargs)
[docs] def get_phase_tap_changer_steps(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of phase tap changer steps. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: A dataframe of phase tap changer steps. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **rho**: The voltage ratio in per unit of the rated voltages (in per unit) - **alpha**: the angle difference (in degree) - **r**: The resistance deviation in percent of nominal value (%) - **x**: The reactance deviation in percent of nominal value (%) - **g**: The conductance deviation in percent of nominal value (%) - **b**: The susceptance deviation in percent of nominal value (%) This dataframe is index by the id of the transformer and the position of the phase tap changer step Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_phase_tap_changer_steps() will output something like: === ======== ==== ====== ========= ========= === === \ rho alpha r x g b === ======== ==== ====== ========= ========= === === id position TWT 0 1.0 -42.80 39.784730 29.784725 0.0 0.0 \ 1 1.0 -40.18 31.720245 21.720242 0.0 0.0 \ 2 1.0 -37.54 23.655737 13.655735 0.0 0.0 ... ... ... ... ... ... ... ... === ======== ==== ====== ========= ========= === === .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_phase_tap_changer_steps(all_attributes=True) will output something like: === ======== ==== ====== ========= ========= === === \ rho alpha r x g b === ======== ==== ====== ========= ========= === === id position TWT 0 1.0 -42.80 39.784730 29.784725 0.0 0.0 \ 1 1.0 -40.18 31.720245 21.720242 0.0 0.0 \ 2 1.0 -37.54 23.655737 13.655735 0.0 0.0 ... ... ... ... ... ... ... ... === ======== ==== ====== ========= ========= === === .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_phase_tap_changer_steps(attributes=['rho','r','x']) will output something like: === ======== ==== ========= ========= \ rho r x === ======== ==== ========= ========= id position TWT 0 1.0 39.784730 29.784725 \ 1 1.0 31.720245 21.720242 \ 2 1.0 23.655737 13.655735 ... ... ... ... ... === ======== ==== ========= ========= """ return self.get_elements(ElementType.PHASE_TAP_CHANGER_STEP, all_attributes, attributes, **kwargs)
[docs] def get_ratio_tap_changers(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Create a ratio tap changers:class:`~pandas.DataFrame`. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: the ratio tap changers dataframe Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **tap**: the current tap position - **low_tap**: the low tap position (usually 0, but could be different depending on the data origin) - **high_tap**: the high tap position - **step_count**: the count of taps, should be equal to (high_tap - low_tap) - **on_load**: true if the tap changer has on-load regulation capability - **regulating**: true if the tap changer is in regulation - **target_v**: the target voltage in kV, if the tap changer is in regulation - **target_deadband**: the regulation deadband around the target voltage, in kV - **regulating_bus_id**: the bus where the tap changer regulates voltage - **regulated_side** (optional): the side where the tap changer regulates voltage (redundant with regulating_bus_id) - **fictitious** (optional): ``True`` if the tap changer is part of the model and not of the actual network This dataframe is indexed by the id of the transformer Examples: .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_network() net.get_ratio_tap_changers() will output something like: ========== === ======= ======== ========== ======= ========== ======== =============== ================= \ tap low_tap high_tap step_count on_load regulating target_v target_deadband regulating_bus_id ========== === ======= ======== ========== ======= ========== ======== =============== ================= id NHV2_NLOAD 1 0 2 3 True True 158.0 0.0 VLLOAD_0 ========== === ======= ======== ========== ======= ========== ======== =============== ================= .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_network() net.get_ratio_tap_changers(all_attributes=True) will output something like: ========== === ======= ======== ========== ======= ========== ======== =============== ================= \ tap low_tap high_tap step_count on_load regulating target_v target_deadband regulating_bus_id ========== === ======= ======== ========== ======= ========== ======== =============== ================= id NHV2_NLOAD 1 0 2 3 True True 158.0 0.0 VLLOAD_0 ========== === ======= ======== ========== ======= ========== ======== =============== ================= .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_network() net.get_ratio_tap_changers(attributes=['tap','low_tap','high_tap','step_count','target_v','regulating_bus_id']) will output something like: ========== === ======= ======== ========== ======== ================= \ tap low_tap high_tap step_count target_v regulating_bus_id ========== === ======= ======== ========== ======== ================= id NHV2_NLOAD 1 0 2 3 158.0 VLLOAD_0 ========== === ======= ======== ========== ======== ================= """ return self.get_elements(ElementType.RATIO_TAP_CHANGER, all_attributes, attributes, **kwargs)
[docs] def get_phase_tap_changers(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Create a phase tap changers:class:`~pandas.DataFrame`. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: the phase tap changers dataframe Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **tap**: the current tap position - **low_tap**: the low tap position (usually 0, but could be different depending on the data origin) - **high_tap**: the high tap position - **step_count**: the count of taps, should be equal to (high_tap - low_tap) - **regulating**: true if the phase shifter is in regulation - **regulation_mode**: regulation mode, among CURRENT_LIMITER, ACTIVE_POWER_CONTROL, and FIXED_TAP - **regulation_value**: the target value, in A or MW, depending on regulation_mode - **target_deadband**: the regulation deadband around the target value - **regulating_bus_id**: the bus where the phase shifter regulates - **regulated_side** (optional): the side bus where the phase shifter regulates current or active power - **fictitious** (optional): ``True`` if the tap changer is part of the model and not of the actual network This dataframe is indexed by the id of the transformer Examples: .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_phase_tap_changers() will output something like: === === ======= ======== ========== ========== =============== ================ =============== ================= \ tap low_tap high_tap step_count regulating regulation_mode regulation_value target_deadband regulating_bus_id === === ======= ======== ========== ========== =============== ================ =============== ================= id TWT 15 0 32 33 False FIXED_TAP NaN NaN S1VL1_0 === === ======= ======== ========== ========== =============== ================ =============== ================= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_phase_tap_changers(all_attributes=True) will output something like: === === ======= ======== ========== ========== =============== ================ =============== ================= \ tap low_tap high_tap step_count regulating regulation_mode regulation_value target_deadband regulating_bus_id === === ======= ======== ========== ========== =============== ================ =============== ================= id TWT 15 0 32 33 False FIXED_TAP NaN NaN S1VL1_0 === === ======= ======== ========== ========== =============== ================ =============== ================= .. code-block:: python net = pp.network.create_four_substations_node_breaker_network() net.get_phase_tap_changers(attributes=['tap','low_tap','high_tap','step_count','regulating_bus_id']) will output something like: === === ======= ======== ========== ================= \ tap low_tap high_tap step_count regulating_bus_id === === ======= ======== ========== ================= id TWT 15 0 32 33 S1VL1_0 === === ======= ======== ========== ================= """ return self.get_elements(ElementType.PHASE_TAP_CHANGER, all_attributes, attributes, **kwargs)
[docs] def get_reactive_capability_curve_points(self, all_attributes: bool = False, attributes: List[str] = None) -> DataFrame: """ Get a dataframe of reactive capability curve points. For each generator, the min/max reactive capabilities can be represented as curves. This dataframe describes those curves as a list of points, which associate a min and a max value of Q to a given value of P. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. Returns: A dataframe of reactive capability curve points. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **num**: the point position in the curve description (starts 0 for a given generator) - **p**: the active power of the point, in MW - **min_q**: the minimum value of reactive power, in MVar, for this value of P - **max_q**: the maximum value of reactive power, in MVar, for this value of P This dataframe is indexed on the generator ID. """ return self.get_elements(ElementType.REACTIVE_CAPABILITY_CURVE_POINT, all_attributes, attributes)
[docs] def get_aliases(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: """ Get a dataframe of aliases of all network elements. Args: Returns: A dataframe of aliases """ return self.get_elements(ElementType.ALIAS, all_attributes, attributes, **kwargs)
[docs] def get_identifiables(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: """ Get a dataframe of identifiables Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. Returns: A dataframe of identifiables. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **type**: the type of the identifiable This dataframe is indexed on the identifiable ID. """ return self.get_elements(ElementType.IDENTIFIABLE, all_attributes, attributes, **kwargs)
[docs] def get_injections(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: """ Get a dataframe of injections Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. Returns: A dataframe of injections. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **type**: the type of the injection - **voltage_level_id**: at which substation the injection is connected - **node** (optional): node where this injection is connected, in node-breaker voltage levels - **bus_breaker_bus_id** (optional): bus of the bus-breaker view where this injection is connected - **connected**: ``True`` if the injection is connected to a bus - **bus_id**: bus where this injection is connected - **p**: the actual active production of the injection (``NaN`` if no loadflow has been computed) - **q**: the actual reactive production of the injection (``NaN`` if no loadflow has been computed) - **i**: the current on the injection, ``NaN`` if no loadflow has been computed (in A) This dataframe is indexed on the injections ID. """ return self.get_elements(ElementType.INJECTION, all_attributes, attributes, **kwargs)
[docs] def get_branches(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: """ Get a dataframe of branches Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. Returns: A dataframe of branches. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **type**: the type of the branch (line or 2 windings transformer) - **voltage_level1_id**: voltage level where the branch is connected, on side 1 - **node1** (optional): node where this branch is connected on side 1, in node-breaker voltage levels - **bus_breaker_bus1_id** (optional): bus of the bus-breaker view where this branch is connected, on side "1" - **connected1**: ``True`` if the side "1" of the branch is connected to a bus - **bus1_id**: bus where this branch is connected, on side 1 - **voltage_level2_id**: voltage level where the branch is connected, on side 2 - **node2** (optional): node where this branch is connected on side 2, in node-breaker voltage levels - **bus_breaker_bus2_id** (optional): bus of the bus-breaker view where this branch is connected, on side "2" - **connected2**: ``True`` if the side "2" of the branch is connected to a bus - **bus2_id**: bus where this branch is connected, on side 2 - **p1**: the active flow on the branch at its "1" side, ``NaN`` if no loadflow has been computed (in MW) - **q1**: the reactive flow on the branch at its "1" side, ``NaN`` if no loadflow has been computed (in MVAr) - **i1**: the current on the branch at its "1" side, ``NaN`` if no loadflow has been computed (in A) - **p2**: the active flow on the branch at its "2" side, ``NaN`` if no loadflow has been computed (in MW) - **q2**: the reactive flow on the branch at its "2" side, ``NaN`` if no loadflow has been computed (in MVAr) - **i2**: the current on the branch at its "2" side, ``NaN`` if no loadflow has been computed (in A) - **selected_limits_group_1** (optional): Name of the selected operational limits group selected for side 1 - **selected_limits_group_2** (optional): Name of the selected operational limits group selected for side 2 This dataframe is indexed on the branch ID. """ return self.get_elements(ElementType.BRANCH, all_attributes, attributes, **kwargs)
[docs] def get_terminals(self, all_attributes: bool = False, attributes: List[str] = None) -> DataFrame: """ Get a dataframe of terminal Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. Returns: A dataframe of terminals. Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **voltage_level_id**: voltage level where the terminal is connected - **bus_id**: bus where this terminal is - **element_side**: if it is a terminal of a branch it will indicate his side else it is "" This dataframe is indexed on the element ID of the terminal. """ return self.get_elements(ElementType.TERMINAL, all_attributes, attributes)
[docs] def get_areas(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of areas. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: the areas dataframe See Also: - :meth:`get_areas_voltage_levels` to retrieve the voltage levels of the areas - :meth:`get_areas_boundaries` to retrieve the voltage levels of the areas boundaries - :meth:`create_areas` to create areas - :meth:`update_areas` to update areas Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **area_type**: the type of area (e.g. ControlArea, BiddingZone, ...) - **interchange_target**: target active power interchange (MW) - **interchange**: total (AC + DC) active power interchange, in load sign convention (negative is export, positive is import) (MW) - **ac_interchange**: AC active power interchange, in load sign convention (negative is export, positive is import) (MW) - **dc_interchange**: DC active power interchange, in load sign convention (negative is export, positive is import) (MW) - **fictitious** (optional): ``True`` if the area is part of the model and not of the actual network This dataframe is indexed on the area ID. Examples: .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_with_tie_lines_and_areas() net.get_areas() will output something like: ============= ============== =========== ================== =========== ============== ============== \ name area_type interchange_target interchange ac_interchange dc_interchange ============= ============== =========== ================== =========== ============== ============== id ControlArea_A Control Area A ControlArea -602.6 -602.948693 -602.948693 0.0 ControlArea_B Control Area B ControlArea 602.6 602.944639 602.944639 0.0 Region_AB Region AB Region NaN 0.000000 0.000000 0.0 ============= ============== =========== ================== =========== ============== ============== """ return self.get_elements(ElementType.AREA, all_attributes, attributes, **kwargs)
[docs] def get_areas_voltage_levels(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of areas voltage levels. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: the areas voltage levels dataframe See Also: :meth:`create_areas_voltage_levels` Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **id**: area identifier - **voltage_level_id**: voltage level identifier This dataframe is indexed on the area ID. Examples: .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_with_tie_lines_and_areas() net.get_areas_voltage_levels() will output something like: ============= ================ \ voltage_level_id ============= ================ id ControlArea_A VLGEN ControlArea_A VLHV1 ControlArea_B VLHV2 ControlArea_B VLLOAD Region_AB VLGEN Region_AB VLHV1 Region_AB VLHV2 Region_AB VLLOAD ============= ================ """ return self.get_elements(ElementType.AREA_VOLTAGE_LEVELS, all_attributes, attributes, **kwargs)
[docs] def get_areas_boundaries(self, all_attributes: bool = False, attributes: List[str] = None, **kwargs: ArrayLike) -> DataFrame: r""" Get a dataframe of areas boundaries. Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. kwargs: the data to be selected, as named arguments. Returns: the areas boundaries dataframe See Also: :meth:`create_areas_boundaries` Notes: The resulting dataframe, depending on the parameters, will include the following columns: - **id**: area identifier - **boundary_type** (optional): either `DANGLING_LINE` or `TERMINAL` - **element**: either identifier of the Dangling Line or the equipment terminal - **side** (optional): equipment side - **ac**: True if the boundary is considered as AC and not DC - **p**: Active power at boundary (MW) - **q**: Reactive power at boundary (MW) This dataframe is indexed on the area ID. Examples: .. code-block:: python net = pp.network.create_eurostag_tutorial_example1_with_tie_lines_and_areas() net.get_areas_boundaries() will output something like: ============= ================ ===== =========== =========== \ element ac p q ============= ================ ===== =========== =========== id ControlArea_A NHV1_XNODE1 True -301.474347 -116.518644 ControlArea_A NVH1_XNODE2 True -301.474347 -116.518644 ControlArea_B XNODE1_NHV2 True 301.472320 116.434157 ControlArea_B XNODE2_NHV2 True 301.472320 116.434157 ============= ================ ===== =========== =========== """ return self.get_elements(ElementType.AREA_BOUNDARIES, all_attributes, attributes, **kwargs)
def _update_elements(self, element_type: ElementType, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update network elements with data provided as a :class:`~pandas.DataFrame` or as named arguments.for a specified element type. The dataframe columns are mapped to IIDM element attributes and each row is mapped to an element using the index. Args: element_type: the element type df: the data to be updated kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. """ metadata = _pp.get_network_elements_dataframe_metadata(element_type) df = _adapt_df_or_kwargs(metadata, df, **kwargs) c_df = _create_c_dataframe(df, metadata) _pp.update_network_elements_with_series(self._handle, c_df, element_type, self._per_unit, self._nominal_apparent_power)
[docs] def update_buses(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update buses with data provided as a dataframe or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `v_mag` - `v_angle` - `fictitious` See Also: :meth:`get_buses` Examples: Some examples using keyword arguments: .. code-block:: python network.update_buses(id='B1', v_mag=400.0) network.update_buses(id=['B1', 'B2'], v_mag=[400.0, 63.5]) """ return self._update_elements(ElementType.BUS, df, **kwargs)
[docs] def update_switches(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update switches with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `open` - `retained` - `fictitious` See Also: :meth:`get_switches` Examples: Some examples using keyword arguments: .. code-block:: python network.update_switches(id='BREAKER-1', open=True) network.update_switches(id=['BREAKER-1', 'DISC-2'], open=[True, False]) """ return self._update_elements(ElementType.SWITCH, df, **kwargs)
[docs] def update_generators(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update generators with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `target_p` - `max_p` - `min_p` - `rated_s` - `target_v` - `target_q` - `voltage_regulator_on` - `regulated_element_id`: you may define any injection or busbar section as the regulated location. Only supported in node breaker voltage levels. - `p` - `q` - `connected` - `fictitious` See Also: :meth:`get_generators` Examples: Some examples using keyword arguments: .. code-block:: python network.update_generators(id='G-1', connected=True, target_p=500) network.update_generators(id=['G-1', 'G-2'], target_v=[403, 401]) """ return self._update_elements(ElementType.GENERATOR, df, **kwargs)
[docs] def update_loads(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update loads with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `p0` - `q0` - `connected` - `fictitious` See Also: :meth:`get_loads` Examples: Some examples using keyword arguments: .. code-block:: python network.update_loads(id='L-1', p0=10, q0=3) network.update_loads(id=['L-1', 'L-2'], p0=[10, 20], q0=[3, 5]) """ return self._update_elements(ElementType.LOAD, df, **kwargs)
[docs] def update_batteries(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update batteries with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `target_p` - `target_q` - `connected` - `max_q` - `min_q` - `fictitious` See Also: :meth:`get_batteries` Examples: Some examples using keyword arguments: .. code-block:: python network.update_batteries(id='B-1', p0=10, q0=3) network.update_batteries(id=['B-1', 'B-2'], p0=[10, 20], q0=[3, 5]) """ return self._update_elements(ElementType.BATTERY, df, **kwargs)
[docs] def update_dangling_lines(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update dangling lines with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `r` - `x` - `g` - `b` - `p0` - `q0` - `p` - `q` - `connected` - `fictitious` - `pairing_key` - `bus_breaker_bus_id` if the dangling line is in a voltage level with `BUS_BREAKER` topology - `selected_limits_group` See Also: :meth:`get_dangling_lines` Examples: Some examples using keyword arguments: .. code-block:: python network.update_dangling_lines(id='L-1', p0=10, q0=3) network.update_dangling_lines(id=['L-1', 'L-2'], p0=[10, 20], q0=[3, 5]) """ return self._update_elements(ElementType.DANGLING_LINE, df, **kwargs)
[docs] def update_vsc_converter_stations(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update VSC converter stations with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `loss_factor` - `target_v` - `target_q` - `voltage_regulator_on` - `p` - `q` - `connected` - `regulated_element_id` - `fictitious` See Also: :meth:`get_vsc_converter_stations` Examples: Some examples using keyword arguments: .. code-block:: python network.update_vsc_converter_stations(id='S-1', target_v=400, voltage_regulator_on=True) network.update_vsc_converter_stations(id=['S-1', 'S-2'], target_v=[400, 400]) """ return self._update_elements(ElementType.VSC_CONVERTER_STATION, df, **kwargs)
[docs] def update_lcc_converter_stations(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update VSC converter stations with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `power_factor` - `loss_factor` - `p` - `q` - `connected` - `fictitious` See Also: :meth:`get_vsc_converter_stations` Examples: Some examples using keyword arguments: .. code-block:: python network.update_lcc_converter_stations(id='S-1', connected=True) network.update_lcc_converter_stations(id=['S-1', 'S-2'], connected=[True, False]) """ return self._update_elements(ElementType.LCC_CONVERTER_STATION, df, **kwargs)
[docs] def update_static_var_compensators(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update static var compensators with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `b_min` - `b_max` - `target_v` - `target_q` - `regulation_mode` - `p` - `q` - `connected` - `regulated_element_id` - `fictitious` See Also: :meth:`get_static_var_compensators` Examples: Some examples using keyword arguments: .. code-block:: python network.update_static_var_compensators(id='SVC-1', target_v=225) network.update_static_var_compensators(id=['SVC-1', 'SVC-2'], target_v=[226, 405]) """ return self._update_elements(ElementType.STATIC_VAR_COMPENSATOR, df, **kwargs)
[docs] def update_hvdc_lines(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update HVDC lines with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `converters_mode` - `target_p` - `max_p` - `nominal_v` - `r` - `connected1` - `connected2` - `fictitious` See Also: :meth:`get_hvdc_lines` Examples: Some examples using keyword arguments: .. code-block:: python network.update_hvdc_lines(id='HVDC-1', target_p=800) network.update_hvdc_lines(id=['HVDC-1', 'HVDC-2'], target_p=[800, 600]) """ return self._update_elements(ElementType.HVDC_LINE, df, **kwargs)
[docs] def update_lines(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update lines data with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `r` - `x` - `g1` - `b1` - `g2` - `b2` - `p1` - `q1` - `p2` - `q2` - `connected1` - `connected2` - `fictitious` - `selected_limits_group_1` - `selected_limits_group_2` See Also: :meth:`get_lines` Examples: Some examples using keyword arguments: .. code-block:: python network.update_lines(id='L-1', connected1=False, connected2=True) network.update_lines(id=['L-1', 'L-2'], r=[0.5, 2.0], x=[5, 10]) """ return self._update_elements(ElementType.LINE, df, **kwargs)
[docs] def update_2_windings_transformers(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update 2 windings transformers with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `r` - `x` - `g` - `b` - `rated_u1` - `rated_u2` - `rated_s` - `p1` - `q1` - `p2` - `q2` - `connected1` - `connected2` - `fictitious` - `selected_limits_group_1` - `selected_limits_group_2` See Also: :meth:`get_2_windings_transformers` Examples: Some examples using keyword arguments: .. code-block:: python network.update_2_windings_transformers(id='T-1', connected1=False, connected2=False) network.update_2_windings_transformers(id=['T-1', 'T-2'], r=[0.5, 2.0], x=[5, 10]) """ return self._update_elements(ElementType.TWO_WINDINGS_TRANSFORMER, df, **kwargs)
[docs] def update_3_windings_transformers(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update 3 windings transformers with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `r1` - `x1` - `g1` - `b1` - `rated_u1` - `rated_s1` - `p1` - `q1` - `connected1` - `ratio_tap_position1` - `phase_tap_position1` - `selected_limits_group_1` - `r2` - `x2` - `g2` - `b2` - `rated_u2` - `rated_s2` - `p2` - `q2` - `connected2` - `ratio_tap_position2` - `phase_tap_position2` - `selected_limits_group_2` - `r3` - `x3` - `g3` - `b3` - `rated_u3` - `rated_s3` - `p3` - `q3` - `connected3` - `ratio_tap_position3` - `phase_tap_position3` - `selected_limits_group_3` - `fictitious` See Also: :meth:`get_3_windings_transformers` Examples: Some examples using keyword arguments: .. code-block:: python network.update_3_windings_transformers(id='T-1', connected1=False, connected2=False, connected3=False) network.update_3_windings_transformers(id=['T-1', 'T-2'], r3=[0.5, 2.0], x3=[5, 10]) """ return self._update_elements(ElementType.THREE_WINDINGS_TRANSFORMER, df, **kwargs)
[docs] def update_ratio_tap_changers(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update ratio tap changers with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `tap` - `on_load` - `regulating`, - `regulated_side`, - `target_v` - `target_deadband` - `fictitious` See Also: :meth:`get_ratio_tap_changers` Examples: Some examples using keyword arguments: .. code-block:: python network.update_ratio_tap_changers(id='T-1', tap=12) network.update_ratio_tap_changers(id=['T-1', 'T-2'], target_v=[64, 65], regulating=[True, True]) """ return self._update_elements(ElementType.RATIO_TAP_CHANGER, df, **kwargs)
def update_ratio_tap_changer_steps(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update ratio tap changer steps with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `rho` - `r` - `x` - `g` - `b` See Also: :meth:`get_ratio_tap_changer_steps` Examples: Some examples using keyword arguments: .. code-block:: python network.update_ratio_tap_changer_steps(id='T-1', position=2, rho=1.1) """ return self._update_elements(ElementType.RATIO_TAP_CHANGER_STEP, df, **kwargs)
[docs] def update_phase_tap_changers(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update phase tap changers with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated : - `tap` - `regulating` - `regulation_mode` - `regulation_value` - `regulated_side` - `target_deadband` - `fictitious` See Also: :meth:`get_phase_tap_changers` Examples: Some examples using keyword arguments: .. code-block:: python network.update_phase_tap_changers(id='T-1', regulation_mode=CURRENT_LIMITER, regulation_value=500) network.update_phase_tap_changers(id=['T-1', 'T-2'], tap=[12, 25]) """ return self._update_elements(ElementType.PHASE_TAP_CHANGER, df, **kwargs)
def update_phase_tap_changer_steps(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update phase tap changer steps with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated : - `rho` - `alpha` - `r` - `x` - `g` - `b` See Also: :meth:`get_phase_tap_changer_steps` Examples: Some examples using keyword arguments: .. code-block:: python network.update_phase_tap_changer_steps(id='T-1', position=2, rho=1.1, alpha=-12.3) """ return self._update_elements(ElementType.PHASE_TAP_CHANGER_STEP, df, **kwargs)
[docs] def update_shunt_compensators(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update shunt compensators with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `section_count` - `p` - `q` - `connected` - `fictitious` See Also: :meth:`get_shunt_compensators` Examples: Some examples using keyword arguments: .. code-block:: python network.update_shunt_compensators(id='IND-1', section_count=1, connected=True) network.update_shunt_compensators(id=['IND-1', 'CAP-1'], section_count=[1, 0]) """ return self._update_elements(ElementType.SHUNT_COMPENSATOR, df, **kwargs)
[docs] def update_linear_shunt_compensator_sections(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update shunt compensators with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `g_per_section` - `b_per_section` - `max_section_count` See Also: :meth:`get_linear_shunt_compensator_sections` Examples: Some examples using keyword arguments: .. code-block:: python network.update_linear_shunt_compensator_sections(id='CAP-1', max_section_count=3) """ return self._update_elements(ElementType.LINEAR_SHUNT_COMPENSATOR_SECTION, df, **kwargs)
[docs] def update_non_linear_shunt_compensator_sections(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update non linear shunt compensators sections with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are : - `g` - `b` See Also: :meth:`get_non_linear_shunt_compensator_sections` Examples: Some examples using keyword arguments: .. code-block:: python network.update_non_linear_shunt_compensator_sections(id='CAP-1', section=1, b=1e-5) """ return self._update_elements(ElementType.NON_LINEAR_SHUNT_COMPENSATOR_SECTION, df, **kwargs)
def update_busbar_sections(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """Update phase tap changers with a ``Pandas`` dataframe. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. """ return self._update_elements(ElementType.BUSBAR_SECTION, df, **kwargs)
[docs] def update_voltage_levels(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update voltage levels with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are : - `high_voltage_limit` - `low_voltage_limit` - `nominal_v` - `fictitious` See Also: :meth:`get_voltage_levels` Examples: Some examples using keyword arguments: .. code-block:: python network.update_voltage_levels(id='VL-1', high_voltage_limit=420) network.update_voltage_levels(id=['VL-1', 'VL-2'], low_voltage_limit=[385, 390]) """ return self._update_elements(ElementType.VOLTAGE_LEVEL, df, **kwargs)
[docs] def update_substations(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update substations with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are : - `TSO` - `country` - `fictitious` See Also: :meth:`get_substations` Examples: Some examples using keyword arguments: .. code-block:: python network.update_substations(id='S-1', TSO='ELIA', country='BE') network.update_substations(id=['S-1', 'S-2'], country=['BE', 'FR']) """ return self._update_elements(ElementType.SUBSTATION, df, **kwargs)
def update_terminals(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update terminals with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are : - `connected`: element_side must be provided if it is a sided network element See Also: :meth:`get_terminals` Examples: Some examples using keyword arguments: .. code-block:: python network.update_terminals(element_id='GENERATOR_ID', connected=False) network.update_terminals(element_id='LINE_ID', element_side='ONE', connected=True) """ return self._update_elements(ElementType.TERMINAL, df, **kwargs) def update_branches(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update branches with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are : - `connected1` - `connected2` - `bus_breaker_bus1_id2` - `bus_breaker_bus2_id2` See Also: :meth:`get_branches` Examples: Some examples using keyword arguments: .. code-block:: python network.update_branches(element_id='BRANCH_ID', connected1=False, connected2=False) """ return self._update_elements(ElementType.BRANCH, df, **kwargs) def update_injections(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update injections with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are : - `connected` - `bus_breaker_bus_id` See Also: :meth:`get_injections` Examples: Some examples using keyword arguments: .. code-block:: python network.update_injections(element_id='INJECTION_ID', connected=True, bus_breaker_bus_id='B2') """ return self._update_elements(ElementType.INJECTION, df, **kwargs) def update_tie_lines(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update tie lines with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are : - `fictitious` See Also: :meth:`get_tie_lines` Examples: Some examples using keyword arguments: .. code-block:: python network.update_tie_lines(element_id='TIE_LINE_ID', fictitious=True) """ return self._update_elements(ElementType.TIE_LINE, df, **kwargs)
[docs] def update_areas(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Update areas with data provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the data to be updated, as a dataframe. kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: Attributes that can be updated are: - `interchange_target` - `fictitious` See Also: :meth:`get_areas` Examples: Some examples using keyword arguments: .. code-block:: python network.update_areas(id='ControlArea_A', interchange_target=-500) network.update_areas(id=['ControlArea_A', 'ControlArea_B'], interchange_target=[-500, 500]) """ return self._update_elements(ElementType.AREA, df, **kwargs)
[docs] def update_extensions(self, extension_name: str, df: DataFrame = None, table_name: str = "", **kwargs: ArrayLike) -> None: """ Update extensions of network elements with data provided as a :class:`~pandas.DataFrame`. Args: extension_name: name of the extension table_name: for multiple dataframes extensions, to precise which dataframe to modify df: the data to be updated kwargs: the data to be updated, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: The id column in the dataframe provides the link to the extensions parent elements """ metadata = _pp.get_network_extensions_dataframe_metadata(extension_name, table_name) df = _adapt_df_or_kwargs(metadata, df, **kwargs) c_df = _create_c_dataframe(df, metadata) _pp.update_extensions(self._handle, extension_name, table_name, c_df)
[docs] def create_extensions(self, extension_name: str, df: Union[DataFrame, List[Optional[DataFrame]]] = None, **kwargs: ArrayLike) -> None: """ create extensions of network elements with data provided as a :class:`~pandas.DataFrame`. Args: extension_name: name of the extension dfs: the data to be created A single dataframe or a list of dataframes can be given as arguments kwargs: the data to be created, as named arguments. Arguments can be single values or any type of sequence. In the case of sequences, all arguments must have the same length. Notes: The id column in the dataframe provides the link to the extensions parent elements """ if not isinstance(df, List): df = [df] self._create_extensions(extension_name, df, **kwargs)
[docs] def get_working_variant_id(self) -> str: """ The current working variant ID. Returns: the id of the currently selected variant. """ return _pp.get_working_variant_id(self._handle)
[docs] def clone_variant(self, src: str, target: str, may_overwrite: bool = True) -> None: """ Creates a copy of the source variant Args: src: variant to copy target: id of the new variant that will be a copy of src may_overwrite: indicates if the target can be overwritten when it already exists """ _pp.clone_variant(self._handle, src, target, may_overwrite)
[docs] def set_working_variant(self, variant: str) -> None: """ Changes the working variant. The provided variant ID must correspond to an existing variant, for example created by a call to `clone_variant`. Args: variant: id of the variant selected (it must exist) """ _pp.set_working_variant(self._handle, variant)
[docs] def remove_variant(self, variant: str) -> None: """ Removes a variant from the network. Args: variant: id of the variant to be deleted """ _pp.remove_variant(self._handle, variant)
[docs] def get_variant_ids(self) -> List[str]: """ Get the list of existing variant IDs. Returns: all the ids of the existing variants """ return _pp.get_variant_ids(self._handle)
[docs] def get_current_limits(self, all_attributes: bool = False, attributes: List[str] = None) -> DataFrame: """ .. deprecated:: Use :meth:`get_operational_limits` instead. Get the list of all current limits on the network paired with their branch id. Args: all_attributes (bool, optional): flag for including all attributes in the dataframe, default is false attributes (List[str], optional): attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. Returns: all current limits on the network """ warnings.warn("get_current_limits is deprecated, use get_operational_limits instead", DeprecationWarning) limits = self.get_operational_limits(all_attributes, attributes) current_limits = limits[ limits['element_type'].isin(['LINE', 'TWO_WINDINGS_TRANSFORMER']) & (limits['type'] == 'CURRENT')] current_limits.index.rename('branch_id', inplace=True) current_limits.set_index('name', append=True, inplace=True) columns = ['side', 'value', 'acceptable_duration'] if 'fictitious' in current_limits.columns: columns.append('fictitious') return current_limits[columns]
[docs] def get_operational_limits(self, all_attributes: bool = False, attributes: List[str] = None, show_inactive_sets: bool = False) -> DataFrame: """ Get the list of operational limits. The resulting dataframe, depending on the parameters, will have some of the following columns: - **element_id**: Identifier of the network element on which this limit applies (could be for example a line or a transformer). This is the index column. - **element_type**: Type of the network element on which this limit applies (LINE, TWO_WINDINGS_TRANSFORMER, THREE_WINDINGS_TRANSFORMER, DANGLING_LINE) - **side**: The side of the element on which this limit applies (ONE, TWO, THREE) - **name**: The name of the limit - **type**: The type of the limit (CURRENT, ACTIVE_POWER, APPARENT_POWER) - **value**: The value of the limit - **acceptable_duration**: The duration, in seconds, for which the element can securely be operated under the limit value. By convention, the value -1 represents an infinite duration. - **fictitious** (optional): `True` if this limit is fictitious - **group_name** (optional): The name of the operational limit group this limit is in - **selected** (optional): `True` if this limit's operational group is the selected one Args: all_attributes: flag for including all attributes in the dataframe, default is false attributes: attributes to include in the dataframe. The 2 parameters are mutually exclusive. If no parameter is specified, the dataframe will include the default attributes. only_selected_sets: flag to choose whether inactive limit sets should also be included in the dataframe Returns: All limits on the network """ if show_inactive_sets: return self.get_elements(ElementType.OPERATIONAL_LIMITS, all_attributes, attributes) else: return self.get_elements(ElementType.SELECTED_OPERATIONAL_LIMITS, all_attributes, attributes)
[docs] def get_node_breaker_topology(self, voltage_level_id: str) -> NodeBreakerTopology: """ Get the node breaker description of the topology of a voltage level. Args: voltage_level_id: id of the voltage level Returns: The node breaker description of the topology of the voltage level """ return NodeBreakerTopology(self._handle, voltage_level_id)
[docs] def get_bus_breaker_topology(self, voltage_level_id: str) -> BusBreakerTopology: """ Get the bus breaker description of the topology of a voltage level. Args: voltage_level_id: id of the voltage level Returns: The bus breaker description of the topology of the voltage level """ return BusBreakerTopology(self._handle, voltage_level_id)
[docs] def merge(self, networks: Union[Network, Sequence[Network]]) -> None: """ Merges networks into this one. Args: networks: List of networks to be merged into this one. Examples: If you have 3 networks, you can merge this way: .. code-block:: python network1.merge([network2, network3]) Note that network1 is modified: it absorbs network2 and network3. """ if isinstance(networks, Network): networks = [networks] self._handle = _pp.merge([self._handle] + [n._handle for n in networks])
def _create_elements(self, element_type: ElementType, dfs: List[Optional[DataFrame]], **kwargs: ArrayLike) -> None: metadata = _pp.get_network_elements_creation_dataframes_metadata(element_type) c_dfs = _get_c_dataframes(dfs, metadata, **kwargs) _pp.create_element(self._handle, c_dfs, element_type) def _create_extensions(self, extension_name: str, dfs: List[Optional[DataFrame]], **kwargs: ArrayLike) -> None: metadata = _pp.get_network_extensions_creation_dataframes_metadata(extension_name) c_dfs = _get_c_dataframes(dfs, metadata, **kwargs) _pp.create_extensions(self._handle, c_dfs, extension_name)
[docs] def create_substations(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates substations. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the substation - **name**: an optional human readable name for the substation - **country**: an optional country code ('DE', 'IT', ...) - **TSO**: an optional TSO name Examples: Using keyword arguments: .. code-block:: python network.create_substations(id='S-1', country='IT', TSO='TERNA') Or using a dataframe: .. code-block:: python stations = pd.DataFrame.from_records(index='id', data=[ {'id': 'S1', 'country': 'BE'}, {'id': 'S2', 'country': 'DE'} ]) network.create_substations(stations) """ self._create_elements(ElementType.SUBSTATION, [df], **kwargs)
[docs] def create_generators(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates generators. Args: df: Attributes as dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new generator - **voltage_level_id**: the voltage level where the new generator will be created. The voltage level must already exist. - **bus_id**: the bus where the new generator will be connected, if the voltage level has a bus-breaker topology kind. - **connectable_bus_id**: the bus where the new generator will be connectable, if the voltage level has a bus-breaker topology kind. - **node**: the node where the new generator will be connected, if the voltage level has a node-breaker topology kind. - **energy_source**: the type of energy source (HYDRO, NUCLEAR, ...) - **max_p**: maximum active power in MW - **min_p**: minimum active power in MW - **target_p**: target active power in MW - **target_q**: target reactive power in MVar, when the generator does not regulate voltage - **rated_s**: nominal power in MVA - **target_v**: target voltage in kV, when the generator regulates voltage - **voltage_regulator_on**: true if the generator regulates voltage Examples: Using keyword arguments: .. code-block:: python network.create_generators(id='GEN', voltage_level_id='VL1', bus_id='B1', target_p=100, min_p=0, max_p=200, target_v=400, voltage_regulator_on=True) """ self._create_elements(ElementType.GENERATOR, [df], **kwargs)
[docs] def create_busbar_sections(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates bus bar sections. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new busbar section - **voltage_level_id**: the voltage level where the new busbar section will be created. The voltage level must already exist. - **node**: the node where the new generator will be connected, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name Examples: Using keyword arguments: .. code-block:: python network.create_busbar_sections(id='BBS', voltage_level_id='VL1', node=0) """ self._create_elements(ElementType.BUSBAR_SECTION, [df], **kwargs)
[docs] def create_buses(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates buses in bus-breaker voltage levels. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. This method can only create "configured buses", in bus-breaker voltage levels, as opposed to electrical buses computed from this underlying topology. Valid attributes are: - **id**: the identifier of the new configured bus - **voltage_level_id**: the voltage level where the new bus will be created. The voltage level must already exist, and must have a bus-breaker topology kind. - **name**: an optional human-readable name Examples: Using keyword arguments: .. code-block:: python network.create_buses(id='B1', voltage_level_id='VL1') """ return self._create_elements(ElementType.BUS, [df], **kwargs)
[docs] def create_loads(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Create loads. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new load - **voltage_level_id**: the voltage level where the new load will be created. The voltage level must already exist. - **bus_id**: the bus where the new load will be connected, if the voltage level has a bus-breaker topology kind. - **connectable_bus_id**: the bus where the new load will be connectable, if the voltage level has a bus-breaker topology kind. - **node**: the node where the new load will be connected, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **type**: optionally, the type of load (UNDEFINED, AUXILIARY, FICTITIOUS) - **p0**: active power load, in MW - **q0**: reactive power load, in MVar Examples: Using keyword arguments: .. code-block:: python network.create_loads(id='LOAD-1', voltage_level_id='VL1', bus_id='B1', p0=10, q0=3) """ return self._create_elements(ElementType.LOAD, [df], **kwargs)
[docs] def create_batteries(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates batteries. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new battery - **voltage_level_id**: the voltage level where the new battery will be created. The voltage level must already exist. - **bus_id**: the bus where the new battery will be connected, if the voltage level has a bus-breaker topology kind. - **connectable_bus_id**: the bus where the new battery will be connectable, if the voltage level has a bus-breaker topology kind. - **node**: the node where the new battery will be connected, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **min_p**: minimum active power, in MW - **max_p**: maximum active power, in MW - **target_p**: active power consumption, in MW - **target_q**: reactive power consumption, in MVar Examples: Using keyword arguments: .. code-block:: python network.create_batteries(id='BAT-1', voltage_level_id='VL1', bus_id='B1', min_p=5, max_p=50, p0=10, q0=3) """ return self._create_elements(ElementType.BATTERY, [df], **kwargs)
[docs] def create_dangling_lines(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates dangling lines. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new line - **voltage_level_id**: the voltage level where the new line will be created. The voltage level must already exist. - **bus_id**: the bus where the new line will be connected, if the voltage level has a bus-breaker topology kind. - **connectable_bus_id**: the bus where the new line will be connectable, if the voltage level has a bus-breaker topology kind. - **node**: the node where the new line will be connected, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **p0**: the active power consumption, in MW - **q0**: the reactive power consumption, in MVar - **r**: the resistance, in Ohms - **x**: the reactance, in Ohms - **g**: the shunt conductance, in S - **b**: the shunt susceptance, in S - **pairing-key**: the optional pairing key associated to the dangling line, to be used for creating tie lines. - **ucte-x-node-code**: deprecated, use pairing-key instead. Examples: Using keyword arguments: .. code-block:: python network.create_dangling_lines(id='BAT-1', voltage_level_id='VL1', bus_id='B1', p0=10, q0=3, r=0, x=5, g=0, b=1e-6) """ ucte_xnode_code_str = 'ucte_xnode_code' if df is not None: if ucte_xnode_code_str in df.columns: warnings.warn(ucte_xnode_code_str + " is deprecated, use pairing_key", DeprecationWarning) df = df.rename(columns={ucte_xnode_code_str: 'pairing_key'}) ucte_x_node_code = kwargs.get(ucte_xnode_code_str) if ucte_x_node_code is not None: warnings.warn(ucte_xnode_code_str + " is deprecated, use pairing_key", DeprecationWarning) kwargs['pairing_key'] = ucte_x_node_code kwargs.pop(ucte_xnode_code_str) return self._create_elements(ElementType.DANGLING_LINE, [df], **kwargs)
[docs] def create_lcc_converter_stations(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates LCC converter stations. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new station - **voltage_level_id**: the voltage level where the new station will be created. The voltage level must already exist. - **bus_id**: the bus where the new station will be connected, if the voltage level has a bus-breaker topology kind. - **connectable_bus_id**: the bus where the new station will be connectable, if the voltage level has a bus-breaker topology kind. - **node**: the node where the new station will be connected, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **power_factor**: the power factor (ratio of the active power to the apparent power) - **loss_factor**: the loss factor of the station Examples: Using keyword arguments: .. code-block:: python network.create_lcc_converter_stations(id='CS-1', voltage_level_id='VL1', bus_id='B1', power_factor=0.3, loss_factor=0.1) """ return self._create_elements(ElementType.LCC_CONVERTER_STATION, [df], **kwargs)
[docs] def create_vsc_converter_stations(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates VSC converter stations. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new station - **voltage_level_id**: the voltage level where the new station will be created. The voltage level must already exist. - **bus_id**: the bus where the new station will be connected, if the voltage level has a bus-breaker topology kind. - **connectable_bus_id**: the bus where the new station will be connectable, if the voltage level has a bus-breaker topology kind. - **node**: the node where the new station will be connected, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **loss_factor**: the loss factor of the new station - **voltage_regulator_on**: true if the station regulated voltage - **target_v**: the target voltage, in kV, when the station regulates voltage - **target_q**: the target reactive power, in MVar, when the station does not regulate voltage Examples: Using keyword arguments: .. code-block:: python network.create_vsc_converter_stations(id='CS-1', voltage_level_id='VL1', bus_id='B1', loss_factor=0.1, voltage_regulator_on=True, target_v=400.0) """ return self._create_elements(ElementType.VSC_CONVERTER_STATION, [df], **kwargs)
[docs] def create_static_var_compensators(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates static var compensators. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new SVC - **voltage_level_id**: the voltage level where the new SVC will be created. The voltage level must already exist. - **bus_id**: the bus where the new SVC will be connected, if the voltage level has a bus-breaker topology kind. - **connectable_bus_id**: the bus where the new SVC will be connectable, if the voltage level has a bus-breaker topology kind. - **node**: the node where the new SVC will be connected, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **b_max**: the maximum susceptance, in S - **b_min**: the minimum susceptance, in S - **regulation_mode**: the regulation mode (VOLTAGE, REACTIVE_POWER, OFF) - **target_v**: the target voltage, in kV, when the regulation mode is VOLTAGE - **target_q**: the target reactive power, in MVar, when the regulation mode is not VOLTAGE Examples: Using keyword arguments: .. code-block:: python network.create_static_var_compensators(id='CS-1', voltage_level_id='VL1', bus_id='B1', b_min=-0.01, b_max=0.01, regulation_mode='VOLTAGE', target_v=400.0) """ return self._create_elements(ElementType.STATIC_VAR_COMPENSATOR, [df], **kwargs)
[docs] def create_lines(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates lines. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new line - **voltage_level1_id**: the voltage level where the new line will be connected on side 1. The voltage level must already exist. - **bus1_id**: the bus where the new line will be connected on side 1, if the voltage level has a bus-breaker topology kind. - **connectable_bus1_id**: the bus where the new line will be connectable on side 1, if the voltage level has a bus-breaker topology kind. - **node1**: the node where the new line will be connected on side 1, if the voltage level has a node-breaker topology kind. - **voltage_level2_id**: the voltage level where the new line will be connected on side 2. The voltage level must already exist. - **bus2_id**: the bus where the new line will be connected on side 2, if the voltage level has a bus-breaker topology kind. - **connectable_bus2_id**: the bus where the new line will be connectable on side 2, if the voltage level has a bus-breaker topology kind. - **node2**: the node where the new line will be connected on side 2, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **b1**: the shunt susceptance, in S, on side 1 - **b2**: the shunt susceptance, in S, on side 2 - **g1**: the shunt conductance, in S, on side 1 - **g2**: the shunt conductance, in S, on side 2 - **r**: the resistance, in Ohm - **x**: the reactance, in Ohm Examples: Using keyword arguments: .. code-block:: python network.create_lines(id='LINE-1', voltage_level1_id='VL1', bus1_id='B1', voltage_level2_id='VL2', bus2_id='B2', b1=1e-6, b2=1e-6, g1=0, , g2=0, r=0.5, x=10) """ return self._create_elements(ElementType.LINE, [df], **kwargs)
[docs] def create_2_windings_transformers(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates 2 windings transformers. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new transformer - **voltage_level1_id**: the voltage level where the new transformer will be connected on side 1. The voltage level must already exist. - **bus1_id**: the bus where the new transformer will be connected on side 1, if the voltage level has a bus-breaker topology kind. - **connectable_bus1_id**: the bus where the new transformer will be connectable on side 1, if the voltage level has a bus-breaker topology kind. - **node1**: the node where the new transformer will be connected on side 1, if the voltage level has a node-breaker topology kind. - **voltage_level2_id**: the voltage level where the new transformer will be connected on side 2. The voltage level must already exist. - **bus2_id**: the bus where the new transformer will be connected on side 2, if the voltage level has a bus-breaker topology kind. - **connectable_bus2_id**: the bus where the new transformer will be connectable on side 2, if the voltage level has a bus-breaker topology kind. - **node2**: the node where the new transformer will be connected on side 2, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **rated_u1**: nominal voltage of the side 1 of the transformer - **rated_u2**: nominal voltage of the side 2 of the transformer - **rated_s**: nominal power of the transformer - **b**: the shunt susceptance, in S - **g**: the shunt conductance, in S - **r**: the resistance, in Ohm - **x**: the reactance, in Ohm Examples: Using keyword arguments: .. code-block:: python network.create_2_windings_transformers(id='T-1', voltage_level1_id='VL1', bus1_id='B1', voltage_level2_id='VL2', bus2_id='B2', b=1e-6, g=1e-6, r=0.5, x=10, rated_u1=400, rated_u2=225) """ return self._create_elements(ElementType.TWO_WINDINGS_TRANSFORMER, [df], **kwargs)
[docs] def create_3_windings_transformers(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates three-winding transformers. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. For each side of the transformer, either a node ID (voltage level in node-breaker topology), bus ID ( voltage level in bus-breaker topology) or connectable bus ID (voltage level in bus-breaker topology, the transformer is created associated but disconnected from this bus) should be specified. Valid attributes are: - **id**: the identifier of the new transformer - **rated_u0**: the rated voltage at the star bus - **voltage_level1_id**: the voltage level where the new transformer will be connected on side 1. The voltage level must already exist. - **bus1_id**: the bus where the new transformer will be connected on side 1, if the voltage level has a bus-breaker topology kind. - **connectable_bus1_id**: the bus to which the transformer can be connected on side 1, if the voltage level has a bus-breaker topology kind. The transformer is created disconnected from this bus. - **node1**: the node where the new transformer will be connected on side 1, if the voltage level has a node-breaker topology kind. - **voltage_level2_id**: the voltage level where the new transformer will be connected on side 2. The voltage level must already exist. - **bus2_id**: the bus where the new transformer will be connected on side 2, if the voltage level has a bus-breaker topology kind. - **connectable_bus2_id**: the bus to which the transformer can be connected on side 2, if the voltage level has a bus-breaker topology kind. The transformer is created disconnected from this bus. - **node2**: the node where the new transformer will be connected on side 2, if the voltage level has a node-breaker topology kind. - **voltage_level3_id**: the voltage level where the new transformer will be connected on side 3. The voltage level must already exist. - **bus3_id**: the bus where the new transformer will be connected on side 3, if the voltage level has a bus-breaker topology kind. - **connectable_bus3_id**: the bus to which the transformer can be connected on side 3, if the voltage level has a bus-breaker topology kind. The transformer is created disconnected from this bus. - **node3**: the node where the new transformer will be connected on side 3, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **rated_u1**: nominal voltage of the side 1 of the transformer - **rated_u2**: nominal voltage of the side 2 of the transformer - **rated_u3**: nominal voltage of the side 3 of the transformer - **rated_s1**: optionally, nominal power of the side 1 of the transformer - **rated_s2**: optionally, nominal power of the side 2 of the transformer - **rated_s3**: optionally, nominal power of the side 3 of the transformer - **r1**: the resistance of the side 1, in Ohm - **r2**: the resistance of the side 2, in Ohm - **r3**: the resistance of the side 3, in Ohm - **x1**: the reactance of the side 1, in Ohm - **x2**: the reactance of the side 2, in Ohm - **x3**: the reactance of the side 3, in Ohm - **b1**: the shunt susceptance of the side 1, in S - **b2**: the shunt susceptance of the side 2, in S - **b3**: the shunt susceptance of the side 3, in S - **g1**: the shunt conductance of the side 1, in S - **g2**: the shunt conductance of the side 2, in S - **g3**: the shunt conductance of the side 3, in S Examples: Using keyword arguments: .. code-block:: python network.create_3_windings_transformers(id='T-1', rated_u0 = 225, voltage_level1_id='VL1', bus1_id='B1', voltage_level2_id='VL2', bus2_id='B2', voltage_level3_id='VL3', bus3_id='B3', b1=1e-6, g1=1e-6, r1=0.5, x1=10, rated_u1=400, rated_s1=100, b2=1e-6, g2=1e-6, r2=0.5, x2=10, rated_u2=225, rated_s2=100, b3=1e-6, g3=1e-6, r3=0.5, x3=10, rated_u3=90, rated_s3=100) """ return self._create_elements(ElementType.THREE_WINDINGS_TRANSFORMER, [df], **kwargs)
[docs] def create_shunt_compensators(self, shunt_df: DataFrame, linear_model_df: Optional[DataFrame] = None, non_linear_model_df: Optional[DataFrame] = None) -> None: """ Create shunt compensators. Shunt compensator sections can be described in 1 of 2 ways: either with a linear model, with a maximum section count and a per-section values, or with a non linear model, where each section is described individually. For this reason, 2 or 3 dataframes need to be provided: one for shunt compensators data, optionally one for linear models, and optionally one for non linear models. Args: shunt_df: dataframe for shunt compensators data linear_model_df: dataframe for linear model sections data non_linear_model_df: dataframe for sections data Notes: Valid attributes for the shunt compensators dataframe are: - **id**: the identifier of the new shunt - **voltage_level_id**: the voltage level where the new shunt will be created. The voltage level must already exist. - **bus_id**: the bus where the new shunt will be connected, if the voltage level has a bus-breaker topology kind. - **connectable_bus_id**: the bus where the new shunt will be connectable, if the voltage level has a bus-breaker topology kind. - **node**: the node where the new shunt will be connected, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **model_type**: either LINEAR or NON_LINEAR - **section_count**: the current count of connected sections - **target_v**: an optional target voltage in kV - **target_v**: an optional deadband for the target voltage, in kV Valid attributes for the linear sections models are: - **id**: the identifier of the new shunt - **g_per_section**: the conductance, in Ohm, for each section - **b_per_section**: the susceptance, in Ohm, for each section - **max_section_count**: the maximum number of connectable sections This dataframe must have only one row for each shunt compensator. Valid attributes for the non linear sections models are: - **id**: the identifier of the new shunt - **g**: the conductance, in Ohm, for this section - **b**: the susceptance, in Ohm, for this section This dataframe will have multiple rows for each shunt compensator: one by section. Examples: For example, to create linear model shunts, we need 1 dataframe for the shunts and 1 dataframe for the linear model of sections: .. code-block:: python shunt_df = pd.DataFrame.from_records( index='id', columns=['id', 'name', 'model_type', 'section_count', 'target_v', 'target_deadband', 'voltage_level_id', 'node'], data=[('SHUNT-1', '', 'LINEAR', 1, 400, 2, 'S1VL2', 2)]) model_df = pd.DataFrame.from_records( index='id', columns=['id', 'g_per_section', 'b_per_section', 'max_section_count'], data=[('SHUNT-1', 0.14, -0.01, 2)]) n.create_shunt_compensators(shunt_df, model_df) For non linear model shunts, we need 1 dataframe for the shunts and 1 dataframe for the sections: .. code-block:: python shunt_df = pd.DataFrame.from_records( index='id', columns=['id', 'name', 'model_type', 'section_count', 'target_v', 'target_deadband', 'voltage_level_id', 'node'], data=[('SHUNT1', '', 'NON_LINEAR', 1, 400, 2, 'S1VL2', 2), ('SHUNT2', '', 'NON_LINEAR', 1, 400, 2, 'S1VL2', 10)]) model_df = pd.DataFrame.from_records( index='id', columns=['id', 'g', 'b'], data=[('SHUNT1', 1, 2), ('SHUNT1', 3, 4), ('SHUNT2', 5, 6), ('SHUNT2', 7, 8)]) n.create_shunt_compensators(shunt_df, non_linear_model_df=model_df) """ if linear_model_df is None: linear_model_df = pd.DataFrame() if non_linear_model_df is None: non_linear_model_df = pd.DataFrame() dfs: List[Optional[DataFrame]] = [shunt_df, linear_model_df, non_linear_model_df] return self._create_elements(ElementType.SHUNT_COMPENSATOR, dfs)
[docs] def create_switches(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates switches. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new switch - **voltage_level_id**: the voltage level where the new switch will be connected. The voltage level must already exist. - **bus1_id**: the bus where the new switch will be connected on side 1, if the voltage level has a bus-breaker topology kind. - **bus2_id**: the bus where the new switch will be connected on side 2, if the voltage level has a bus-breaker topology kind. - **node1**: the node where the new switch will be connected on side 1, if the voltage level has a node-breaker topology kind. - **node2**: the node where the new switch will be connected on side 2, if the voltage level has a node-breaker topology kind. - **name**: an optional human-readable name - **kind**: the kind of switch (BREAKER, DISCONNECTOR, LOAD_BREAK_SWITCH) - **open**: true if the switch is open, default false - **retained**: true if the switch should be retained in bus-breaker topology, default false - **fictitious**: true if the switch is fictitious, default false Examples: Using keyword arguments: .. code-block:: python # In a bus-breaker voltage level, between configured buses B1 and B2 network.create_switches(id='BREAKER-1', voltage_level_id='VL1', bus1_id='B1', bus2_id='B2', kind='BREAKER', open=False) # In a node-breaker voltage level, between nodes 5 and 7 network.create_switches(id='BREAKER-1', voltage_level_id='VL1', node1=5, node2=7, kind='BREAKER', open=False) """ return self._create_elements(ElementType.SWITCH, [df], **kwargs)
[docs] def create_voltage_levels(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates voltage levels. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new voltage level - **substation_id**: the identifier of the substation which the new voltage level belongs to. Optional. If defined, the substation must already exist. - **name**: an optional human-readable name - **topology_kind**: the topology kind, BUS_BREAKER or NODE_BREAKER - **nominal_v**: the nominal voltage, in kV - **low_voltage_limit**: the lower operational voltage limit, in kV - **high_voltage_limit**: the upper operational voltage limit, in kV Examples: Using keyword arguments: .. code-block:: python network.create_voltage_levels(id='VL1', substation_id='S1', topology_kind='BUS_BREAKER', nominal_v=400, low_voltage_limit=380, high_voltage_limit=420) """ return self._create_elements(ElementType.VOLTAGE_LEVEL, [df], **kwargs)
[docs] def create_ratio_tap_changers(self, rtc_df: DataFrame, steps_df: DataFrame) -> None: """ Create ratio tap changers on transformers. Tap changers data must be provided in 2 separate dataframes: one for the tap changers attributes, and another one for tap changers steps attributes. The latter one will generally have multiple lines for one transformer ID. The steps are created in order of the dataframe order meaning (for a transformer) first line of the steps dataframe will create step one of the steps of these transformer. Args: rtc_df: dataframe of tap changers data steps_df: dataframe of steps data Notes: Valid attributes for the tap changers dataframe are: - **id**: the transformer where this tap changer will be created - **tap**: the current tap position - **low_tap**: the number of the lowest tap position (default 0) - **on_load**: true if the transformer has on-load voltage regulation capability - **target_v**: the target voltage, in kV - **target_deadband**: the target voltage regulation deadband, in kV - **regulating**: true if the tap changer should regulate voltage - **regulated_side**: the side where voltage is regulated (ONE or TWO if two-winding transformer, ONE, TWO or THREE if three-winding transformer) - **side**: Side of the tap changer (only for three-winding transformers) Valid attributes for the steps dataframe are: - **id**: the transformer where this step will be added - **g**: the shunt conductance increase compared to the transformer, for this step, in percentage - **b**: the shunt susceptance increase compared to the transformer, for this step, in percentage - **r**: the resistance increase compared to the transformer, for this step, in percentage - **x**: the reactance increased compared to the transformer, for this step, in percentage - **rho**: the transformer ratio for this step (1 means real ratio is rated_u2/rated_u1) Examples: We need to provide 2 dataframes, 1 for tap changer basic data, and one for step-wise data: .. code-block:: python rtc_df = pd.DataFrame.from_records( index='id', columns=['id', 'target_deadband', 'target_v', 'on_load', 'low_tap', 'tap'], data=[('NGEN_NHV1', 2, 200, False, 0, 1)]) steps_df = pd.DataFrame.from_records( index='id', columns=['id', 'b', 'g', 'r', 'x', 'rho'], data=[('NGEN_NHV1', 2, 2, 1, 1, 0.5), ('NGEN_NHV1', 2, 2, 1, 1, 0.5), ('NGEN_NHV1', 2, 2, 1, 1, 0.8)]) network.create_ratio_tap_changers(rtc_df, steps_df) """ return self._create_elements(ElementType.RATIO_TAP_CHANGER, [rtc_df, steps_df])
[docs] def create_phase_tap_changers(self, ptc_df: DataFrame, steps_df: DataFrame) -> None: """ Create phase tap changers on transformers. Tap changers data must be provided in 2 separate dataframes: one for the tap changers attributes, and another one for tap changers steps attributes. The latter one will generally have multiple lines for one transformer ID. The steps are created in order of the dataframe order meaning (for a transformer) first line of the steps dataframe will create step one of the steps of these transformer. Args: ptc_df: dataframe of tap changers data steps_df: dataframe of steps data Notes: Valid attributes for the tap changers dataframe are: - **id**: the transformer where this tap changer will be created - **tap**: the current tap position - **low_tap**: the number of the lowest tap position (default 0) - **regulation_mode**: the regulation mode (CURRENT_LIMITER, ACTIVE_POWER_CONTROL, FIXED_TAP) - **target_deadband**: the regulation deadband - **regulating**: true if the tap changer should regulate - **regulated_side**: the side where the current or active power is regulated (ONE or TWO if two-winding transformer, ONE, TWO or THREE if three-winding transformer) - **side**: Side of the tap changer (only for three-winding transformers) Valid attributes for the steps dataframe are: - **id**: the transformer where this step will be added - **g**: the shunt conductance increase compared to the transformer, for this step, in percentage - **b**: the shunt susceptance increase compared to the transformer, for this step, in percentage - **r**: the resistance increase compared to the transformer, for this step, in percentage - **x**: the reactance increased compared to the transformer, for this step, in percentage - **rho**: the transformer ratio for this step (1 means real ratio is rated_u2/rated_u1) - **alpha**: the phase shift, in degrees, for this step Examples: We need to provide 2 dataframes, 1 for tap changer basic data, and one for step-wise data: .. code-block:: python ptc_df = pd.DataFrame.from_records( index='id', columns=['id', 'target_deadband', 'regulation_mode', 'low_tap', 'tap'], data=[('TWT_TEST', 2, 'CURRENT_LIMITER', 0, 1)]) steps_df = pd.DataFrame.from_records( index='id', columns=['id', 'b', 'g', 'r', 'x', 'rho', 'alpha'], data=[('TWT_TEST', 2, 2, 1, 1, 0.5, 0.1), ('TWT_TEST', 2, 2, 1, 1, 0.4, 0.2), ('TWT_TEST', 2, 2, 1, 1, 0.5, 0.1)]) n.create_phase_tap_changers(ptc_df, steps_df) """ return self._create_elements(ElementType.PHASE_TAP_CHANGER, [ptc_df, steps_df])
[docs] def create_hvdc_lines(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates HVDC lines. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new HVDC line - **name**: an optional human-readable name - **converter_station1_id**: the station where the new HVDC line will be connected on side 1. It must already exist. - **converter_station2_id**: the station where the new HVDC line will be connected on side 2. It must already exist. - **r**: the resistance of the HVDC line, in Ohm - **nominal_v**: the nominal voltage of the HVDC line, in kV - **max_p**: the maximum transmissible power, in MW - **target_p**: the active power target, in MW - **converters_mode**: SIDE_1_RECTIFIER_SIDE_2_INVERTER or SIDE_1_INVERTER_SIDE_2_RECTIFIER Examples: Using keyword arguments: .. code-block:: python network.create_hvdc_lines(id='HVDC-1', converter_station1_id='CS-1', converter_station2_id='CS-2', r=1.0, nominal_v=400, converters_mode='SIDE_1_RECTIFIER_SIDE_2_INVERTER', max_p=1000, target_p=800) """ return self._create_elements(ElementType.HVDC_LINE, [df], **kwargs)
[docs] def create_operational_limits(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates operational limits. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **element_id**: the ID of the network element on which we want to create new limits THREE_WINDINGS_TRANSFORMER, DANGLING_LINE) - **side**: the side of the network element where we want to create new limits (ONE, TWO, THREE) - **name**: the name of the limit - **type**: the type of limit to be created (CURRENT, APPARENT_POWER, ACTIVE_POWER) - **value**: the value of the limit in A, MVA or MW - **acceptable_duration**: the maximum number of seconds during which we can operate under that limit - **fictitious**: fictitious limit ? For each location of the network defined by a couple (element_id, side): - if operational limits already exist, they will be replaced - multiple limits may be defined, typically with different acceptable_duration - you can only define ONE permanent limit, identified by an acceptable_duration of -1 Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. """ if df is not None: df['acceptable_duration'] = df['acceptable_duration'].map(lambda x: -1 if x == inf else int(x)) if 'is_fictitious' in df.columns: warnings.warn("operation limits is_fictitious attribute has been renamed fictitious", DeprecationWarning) df = df.rename(columns={'is_fictitious': 'fictitious'}) if 'element_type' in df.columns: warnings.warn("useless operation limits element_type attribute has been removed", DeprecationWarning) df = df.drop(columns=['element_type']) if kwargs.get('is_fictitious') is not None: warnings.warn("operation limits is_fictitious attribute has been renamed fictitious", DeprecationWarning) kwargs['fictitious'] = kwargs.pop('is_fictitious') if kwargs.get('element_type') is not None: warnings.warn("useless operation limits element_type attribute has been removed", DeprecationWarning) kwargs.pop('element_type') return self._create_elements(ElementType.OPERATIONAL_LIMITS, [df], **kwargs)
[docs] def create_minmax_reactive_limits(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates reactive limits of type min/max. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the generator - **min_q**: minimum reactive limit, in MVAr - **max_q**: maximum reactive limit, in MVAr Previously defined limits for a given generator, if present, will be replaced by the new ones. Examples: Using keyword arguments: .. code-block:: python network.create_minmax_reactive_limits(id='GEN-1', min_q=-100, max_q=100) See Also: :meth:`create_curve_reactive_limits` """ return self._create_elements(ElementType.MINMAX_REACTIVE_LIMITS, [df], **kwargs)
[docs] def create_curve_reactive_limits(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates reactive limits as "curves". Curves are actually composed of line segments, defined by a list of points. Each row of the input data actually defines 2 points: one for the minimum limit, one for the maximum limit, for the given active power value. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the generator - **p**: active power, in MW, for which this row defines limits - **min_q**: minimum reactive limit at this active power value, in MVAr - **max_q**: maximum reactive limit at this active power value, in MVAr At least 2 rows must be defined for each generator, for 2 different active power values. Previously defined limits for a given generator, if present, will be replaced by the new ones. Examples: Generator GEN-1 will be able to provide 150MVAr when P=0MW, and only 100MVAr when it generates 100MW: .. code-block:: python network.create_curve_reactive_limits(id=['GEN-1', 'GEN-1'], p=[0, 100], min_q=[-150, -100], max_q=[150, 100]) See Also: :meth:`create_minmax_reactive_limits` """ return self._create_elements(ElementType.REACTIVE_CAPABILITY_CURVE_POINT, [df], **kwargs)
[docs] def create_tie_lines(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Creates tie lines from two dangling lines. Both dangling lines must have the same UCTE Xnode code. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new tie line - **name**: an optional human-readable name - **dangling_line1_id**: the ID of the first dangling line It must already exist. - **dangling_line2_id**: the ID of the second dangling line It must already exist. Examples: Using keyword arguments: .. code-block:: python network.create_tie_lines(id='tie_line_1', dangling_line1_id='DL-1', dangling_line2_id='DL-2') """ return self._create_elements(ElementType.TIE_LINE, [df], **kwargs)
[docs] def create_areas(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Create areas. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. See Also: :meth:`get_areas` Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the new area - **name**: an optional human-readable name - **area_type**: the type of Area (e.g. ControlArea, BiddingZone …) - **interchange_target**: Target active power interchange (MW) Examples: Using keyword arguments: .. code-block:: python network.create_areas(id='Area1', area_type='ControlArea', interchange_target=120.5) """ return self._create_elements(ElementType.AREA, [df], **kwargs)
[docs] def create_areas_voltage_levels(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Associate voltage levels to (existing) areas. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Important: The provided voltage levels for an area replace all existing voltage levels of that area, i.e. the entire list of voltage levels must be provided for the areas being edited. Valid attributes are: - **id**: the identifier of the area - **voltage_level_id**: the identifier of the voltage level to be associated with the area See Also: :meth:`get_areas_voltage_levels` Examples: To associate voltage levels VL1 and VL2 to Area1. .. code-block:: python network.create_areas_voltage_levels(id=['Area1', 'Area1'], voltage_level_id=['VL1', 'VL2']) To dissociate all VoltageLevels of a given area, provide an empty string in voltage_level_id. .. code-block:: python network.create_areas_voltage_levels(id=['Area1'], voltage_level_id=['']) """ return self._create_elements(ElementType.AREA_VOLTAGE_LEVELS, [df], **kwargs)
[docs] def create_areas_boundaries(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Define boundaries of (existing) areas. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Important: The provided boundaries for an area replace all existing boundaries of that area, i.e. the entire list of boundaries must be provided for the areas being edited. Valid attributes are: - **id**: the identifier of the area - **boundary_type**: either `DANGLING_LINE` or `TERMINAL`, defaults to `DANGLING_LINE`. - **element**: dangling line identifier, or any connectable - **side**: if element is not a dangling line (e.g. a branch or transformer), the terminal side - **ac**: True is boundary is to be considered as AC See Also: :meth:`get_areas_boundaries` Examples: .. code-block:: python # define dangling lines NHV1_XNODE1 and NVH1_XNODE2 as boundaries of AreaA, and # define dangling lines XNODE1_NHV2 and XNODE2_NHV2 as boundaries of AreaB network.create_areas_boundaries(id=['AreaA', 'AreaA', 'AreaB', 'AreaB'], boundary_type=['DANGLING_LINE', 'DANGLING_LINE', 'DANGLING_LINE', 'DANGLING_LINE'], element=['NHV1_XNODE1', 'NVH1_XNODE2', 'XNODE1_NHV2', 'XNODE2_NHV2'], ac=[True, True, True, True]) To dissociate all Boundaries of a given area, provide an empty string in element. .. code-block:: python network.create_areas_boundaries(id=['Area1'], element=['']) """ return self._create_elements(ElementType.AREA_BOUNDARIES, [df], **kwargs)
[docs] def add_aliases(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Adds aliases to network elements. An alias is a reference to a network element. For example, to get or to update an element, his alias may be used instead of his id. An alias may be associated with a type, to distinguish it from other aliases. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the network element associated to the alias - **alias**: name of the alias - **alias_type**: type of the alias (optional) Examples: .. code-block:: python network.add_aliases(id='element_id', alias='alias_id') network.add_aliases(id='element_id', alias='alias_id', alias_type='alias_type') """ return self._create_elements(ElementType.ALIAS, [df], **kwargs)
[docs] def get_validation_level(self) -> ValidationLevel: """ The network's validation level. This it the network validation level as computed by validation checks. Returns: the ValidationLevel. """ return _pp.get_validation_level(self._handle)
[docs] def validate(self) -> ValidationLevel: """ Validate the network. The validation will raise an exception if any check is not consistent with the configured minimum validation level. Returns: the computed ValidationLevel, which may be higher than the configured minimum level. Raises: pypowsybl.PyPowsyblError: if any validation check is not consistent with the configured minimum validation level. """ return _pp.validate(self._handle)
[docs] def set_min_validation_level(self, validation_level: ValidationLevel) -> None: """ Set the minimum validation level for the network. Args: validation_level (ValidationLevel): the validation level Raises: pypowsybl.PyPowsyblError: if any validation check is not consistent with the new minimum validation level. """ _pp.set_min_validation_level(self._handle, validation_level)
[docs] def remove_aliases(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Removes aliases of network elements. Args: df: Attributes as a dataframe. kwargs: Attributes as keyword arguments. Notes: Data may be provided as a dataframe or as keyword arguments. In the latter case, all arguments must have the same length. Valid attributes are: - **id**: the identifier of the network element associated to the alias - **alias**: name of the alias Examples: .. code-block:: python network.remove_aliases(id='element_id', alias='alias_id') """ metadata = _pp.get_network_elements_creation_dataframes_metadata(ElementType.ALIAS)[0] df = _adapt_df_or_kwargs(metadata, df, **kwargs) c_df = _create_c_dataframe(df, metadata) _pp.remove_aliases(self._handle, c_df)
[docs] def remove_elements(self, elements_ids: Union[str, List[str]]) -> None: """ Removes elements from the network. Args: elements_ids: IDs of the elements to be removed. Notes: Elements can be provided as a list of IDs or as a single ID. Elements can be any identifiable object of the network (line, generator, switch, substation ...). Examples: .. code-block:: python network.remove_elements('GENERATOR-1') # Removes only 1 element network.remove_elements(['GENERATOR-1', 'BUS']) """ if isinstance(elements_ids, str): elements_ids = [elements_ids] _pp.remove_elements(self._handle, elements_ids)
[docs] def get_extensions(self, extension_name: str, table_name: str = "") -> DataFrame: """ Get an extension as a :class:`~pandas.DataFrame` for a specified extension name. Args: extension_name: name of the extension table_name: optional argument to choose the name of the dataframe to retrieve for extensions using multiple dataframes Returns: A dataframe with the extensions data. Notes: The extra id column in the resulting dataframe provides the link to the extensions parent elements """ return create_data_frame_from_series_array( _pp.create_network_elements_extension_series_array(self._handle, extension_name, table_name))
def get_extension(self, extension_name: str) -> DataFrame: """ .. deprecated:: Use :meth:`get_extensions` instead. """ warnings.warn("get_extension is deprecated, use get_extensions instead", DeprecationWarning) return self.get_extensions(extension_name)
[docs] def add_elements_properties(self, df: DataFrame = None, **kwargs: ArrayLike) -> None: """ Add properties to network elements, provided as a :class:`~pandas.DataFrame` or as named arguments. Args: df: the properties to be created or updated. The index has to be the `id` identifying the network elements. kwargs: the properties to be added as named arguments. Arguments can be a single string or any type of sequence of strings. In the case of sequences, all arguments must have the same length. Examples: For example, to add the properties prop1 = value1 and prop2 = value2 to a network element: .. code-block:: python >>> network.add_elements_properties(id='GENERATOR-1', prop1='value1', prop2='value2') >>> network.get_generators(attributes=['prop1', 'prop2'], id='GENERATOR-1') toto id VLEJUP7 tutu You can also update multiple elements at once, for example with a dataframe: .. code-block:: python >>> properties_df = pd.Dataframe(index=pd.Series('id', ['G1', 'G2']), data={ 'prop1': [ 'val11', 'val12'], 'prop2': [ 'val12', 'val22'], }) >>> network.add_elements_properties(properties_df) >>> network.get_generators(attributes=['prop1', 'prop2'], id=['G1', 'G2']) prop1 prop2 id G1 val11 val12 G2 val21 val22 """ if df is None: df = _adapt_properties_kwargs(**kwargs) if df.isnull().values.any(): raise _pp.PyPowsyblError("dataframe can not contain NaN values") for series_name in df.columns.values: df[series_name] = df[series_name].astype(str) c_df = _create_properties_c_dataframe(df) _pp.add_network_element_properties(self._handle, c_df)
[docs] def remove_elements_properties(self, ids: Union[str, List[str]], properties: Union[str, List[str]]) -> None: """ Remove properties from a list of network elements Args: ids: list of the network elements that will have their properties removed properties: list of the properties that will be removed Examples: To remove properties prop1 and prop2 from network elements GEN1 and GEN2: .. code-block:: python network.remove_elements_properties(ids=['GEN1', 'GEN2'], properties=['prop1', 'prop2']) """ if isinstance(ids, str): ids = [ids] if isinstance(properties, str): properties = [properties] _pp.remove_network_element_properties(self._handle, ids, properties)
[docs] def remove_extensions(self, extension_name: str, ids: Union[str, List[str]]) -> None: """ Removes network elements extensions, given the extension's name. Args: extension_name: name of the extension ids: IDs of the elements to be removed. Notes: ids can be provided as a list of IDs or as a single ID. """ if isinstance(ids, str): ids = [ids] _pp.remove_extensions(self._handle, extension_name, ids)