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Backend.py
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Backend.py
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# Copyright (c) 2019-2020, RTE (https://www.rte-france.com)
# See AUTHORS.txt
# This Source Code Form is subject to the terms of the Mozilla Public License, version 2.0.
# If a copy of the Mozilla Public License, version 2.0 was not distributed with this file,
# you can obtain one at http://mozilla.org/MPL/2.0/.
# SPDX-License-Identifier: MPL-2.0
# This file is part of Grid2Op, Grid2Op a testbed platform to model sequential decision making in power systems.
import copy
import os
import sys
import warnings
import json
from abc import ABC, abstractmethod
import numpy as np
import pandas as pd
from grid2op.dtypes import dt_int, dt_float, dt_bool
from grid2op.Exceptions import (
EnvError,
DivergingPowerFlow,
IncorrectNumberOfElements,
IncorrectNumberOfLoads,
)
from grid2op.Exceptions import (
IncorrectNumberOfGenerators,
BackendError,
IncorrectNumberOfLines,
)
from grid2op.Space import GridObjects
from grid2op.Exceptions import Grid2OpException
# TODO method to get V and theta at each bus, could be in the same shape as check_kirchoff
class Backend(GridObjects, ABC):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Unless if you want to code yourself a backend this is not recommend to alter it
or use it directly in any way.
If you want to code a backend, an example is given in :class:`PandaPowerBackend` (
or in the repository lightsim2grid on github)
This documentation is present mainly for exhaustivity. It is not recommended to manipulate a Backend
directly. Prefer using an :class:`grid2op.Environment.Environment`
This is a base class for each :class:`Backend` object.
It allows to run power flow smoothly, and abstract the method of computing cascading failures.
This class allow the user or the agent to interact with an power flow calculator, while relying on dedicated
methods to change the power grid behaviour.
It is NOT recommended to use this class outside the Environment.
An example of a valid backend is provided in the :class:`PandapowerBackend`.
All the abstract methods (that need to be implemented for a backend to work properly) are (more information given
in the :ref:`create-backend-module` page):
- :func:`Backend.load_grid`
- :func:`Backend.apply_action`
- :func:`Backend.runpf`
- :func:`Backend.get_topo_vect`
- :func:`Backend.generators_info`
- :func:`Backend.loads_info`
- :func:`Backend.lines_or_info`
- :func:`Backend.lines_ex_info`
And optionally:
- :func:`Backend.close` (this is mandatory if your backend implementation (`self._grid`) is relying on some
c / c++ code that do not free memory automatically.
- :func:`Backend.copy` (not that this is mandatory if your backend implementation (in `self._grid`) cannot be
deep copied using the python copy.deepcopy function) [as of grid2op >= 1.7.1 it is no more
required. If not implemented, you won't be able to use some of grid2op feature however]
- :func:`Backend.get_line_status`: the default implementation uses the "get_topo_vect()" and then check
if buses at both ends of powerline are positive. This is rather slow and can most likely be optimized.
- :func:`Backend.get_line_flow`: the default implementation will retrieve all powerline information
at the "origin" side and just return the "a_or" vector. You want to do something smarter here.
- :func:`Backend._disconnect_line`: has a default slow implementation using "apply_action" that might
can most likely be optimized in your backend.
- :func:`Backend.reset` will reload the powergrid from the hard drive by default. This is rather slow and we
recommend to overload it.
And, if the flag :attr:Backend.shunts_data_available` is set to ``True`` the method :func:`Backend.shunt_info`
should also be implemented.
.. note:: Backend also support "shunts" information if the `self.shunts_data_available` flag is set to
``True`` in that case, you also need to implement all the relevant shunt information (attributes `n_shunt`,
`shunt_to_subid`, `name_shunt` and function `shunt_info` and handle the modification of shunts
bus, active value and reactive value in the "apply_action" function).
In order to be valid and carry out some computations, you should call :func:`Backend.load_grid` and later
:func:`grid2op.Spaces.GridObjects.assert_grid_correct`. It is also more than recommended to call
:func:`Backend.assert_grid_correct_after_powerflow` after the first powerflow. This is all carried ou in the
environment properly.
Attributes
----------
detailed_infos_for_cascading_failures: :class:`bool`
Whether to be verbose when computing a cascading failure.
thermal_limit_a: :class:`numpy.array`, dtype:float
Thermal limit of the powerline in amps for each powerline. Thie thermal limit is relevant on only one
side of the powerline: the same side returned by :func:`Backend.get_line_overflow`
comp_time: ``float``
Time to compute the powerflow (might be unset, ie stay at 0.0)
"""
IS_BK_CONVERTER = False
env_name = "unknown"
# action to set me
my_bk_act_class = None
_complete_action_class = None
ERR_INIT_POWERFLOW = "Power cannot be computed on the first time step, please check your data."
def __init__(self,
detailed_infos_for_cascading_failures: bool=False,
can_be_copied: bool=True,
**kwargs):
"""
Initialize an instance of Backend. This does nothing per se. Only the call to :func:`Backend.load_grid`
should guarantee the backend is properly configured.
:param detailed_infos_for_cascading_failures: Whether to be detailed (but slow) when computing cascading failures
:type detailed_infos_for_cascading_failures: :class:`bool`
"""
GridObjects.__init__(self)
# the following parameter is used to control the amount of verbosity when computing a cascading failure
# if it's set to true, it returns all intermediate _grid states. This can slow down the computation!
self.detailed_infos_for_cascading_failures = (
detailed_infos_for_cascading_failures
)
# the power _grid manipulated. One powergrid per backend.
self._grid = None
# thermal limit setting, in ampere, at the same "side" of the powerline than self.get_line_overflow
self.thermal_limit_a = None
# for the shunt (only if supported)
self._sh_vnkv = None # for each shunt gives the nominal value at the bus at which it is connected
# if this information is not present, then "get_action_to_set" might not behave correctly
self.comp_time = 0.0
self.can_output_theta = False
# to prevent the use of the same backend instance in different environment.
self._is_loaded = False
self._can_be_copied = can_be_copied
self._my_kwargs = {"detailed_infos_for_cascading_failures": detailed_infos_for_cascading_failures,
"can_be_copied": self._can_be_copied}
for k, v in kwargs.items():
self._my_kwargs[k] = v
@property
def is_loaded(self):
return self._is_loaded
@is_loaded.setter
def is_loaded(self, value):
if value is True:
self._is_loaded = True
else:
raise BackendError('Impossible to unset the "is_loaded" status.')
@abstractmethod
def load_grid(self, path, filename=None):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
This is called once at the loading of the powergrid.
Load the powergrid.
It should first define self._grid.
And then fill all the helpers used by the backend eg. all the attributes of :class:`Space.GridObjects`.
After a the call to :func:`Backend.load_grid` has been performed, the backend should be in such a state where
the :class:`grid2op.Space.GridObjects` is properly set up. See the description of
:class:`grid2op.Space.GridObjects` to know which attributes should be set here and which should not.
:param path: the path to find the powergrid
:type path: :class:`string`
:param filename: the filename of the powergrid
:type filename: :class:`string`, optional
:return: ``None``
"""
pass
@abstractmethod
def apply_action(self, action):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Don't attempt to apply an action directly to a backend. This function will modify
the powergrid state given the action in input.
This is one of the core function if you want to code a backend.
Modify the powergrid with the action given by an agent or by the envir.
For the L2RPN project, this action is mainly for topology if it has been sent by the agent.
Or it can also affect production and loads, if the action is made by the environment.
The help of :func:`grid2op.BaseAction.BaseAction.__call__` or the code in BaseActiontion.py file give more information about
the implementation of this method.
:param action: the action to be implemented on the powergrid.
:type action: :class:`grid2op.Action._BackendAction._BackendAction`
:return: ``None``
"""
pass
@abstractmethod
def runpf(self, is_dc=False):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
This is called by :func:`Backend.next_grid_state` (that computes some kind of
cascading failures).
This is one of the core function if you want to code a backend. It will carry out
a powerflow.
Run a power flow on the underlying _grid.
Powerflow can be AC (is_dc = False) or DC (is_dc = True)
:param is_dc: is the powerflow run in DC or in AC
:type is_dc: :class:`bool`
:return: ``True`` if it has converged, or false otherwise. In case of non convergence, no flows can be inspected on
the _grid.
:rtype: :class:`bool`
:return: an exception in case of divergence (or none if no particular info are available)
:rtype: `Exception`
"""
pass
@abstractmethod
def get_topo_vect(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.topo_vect`
Get the topology vector from the :attr:`Backend._grid`.
The topology vector defines, for each object, on which bus it is connected.
It returns -1 if the object is not connected.
It is a vector with as much elements (productions, loads and lines extremity) as there are in the powergrid.
For each elements, it gives on which bus it is connected in its substation.
For example, if the first element of this vector is the load of id 1, then if `res[0] = 2` it means that the
load of id 1 is connected to the second bus of its substation.
You can check which object of the powerlines is represented by each component of this vector by looking at the
`*_pos_topo_vect` (*eg.* :attr:`grid2op.Space.GridObjects.load_pos_topo_vect`) vectors.
For each elements it gives its position in this vector.
As any function of the backend, it is not advised to use it directly. You can get this information in the
:attr:`grid2op.Observation.Observation.topo_vect` instead.
Returns
--------
res: ``numpy.ndarray`` dtype: ``int``
An array saying to which bus the object is connected.
"""
pass
@abstractmethod
def generators_info(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.gen_p`,
:attr:`grid2op.Observation.BaseObservation.gen_q` and
:attr:`grid2op.Observation.BaseObservation.gen_v` instead.
This method is used to retrieve information about the generators (active, reactive production
and voltage magnitude of the bus to which it is connected).
.. note::
The values returned here are the values AFTER the powerflow has been computed and not
the target values.
Returns
-------
prod_p ``numpy.ndarray``
The active power production for each generator (in MW)
prod_q ``numpy.ndarray``
The reactive power production for each generator (in MVAr)
prod_v ``numpy.ndarray``
The voltage magnitude of the bus to which each generators is connected (in kV)
"""
pass
@abstractmethod
def loads_info(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.load_p`,
:attr:`grid2op.Observation.BaseObservation.load_q` and
:attr:`grid2op.Observation.BaseObservation.load_v` instead.
This method is used to retrieve information about the loads (active, reactive consumption
and voltage magnitude of the bus to which it is connected).
.. note::
The values returned here are the values AFTER the powerflow has been computed and not
the target values.
Returns
-------
load_p ``numpy.ndarray``
The active power consumption for each load (in MW)
load_q ``numpy.ndarray``
The reactive power consumption for each load (in MVAr)
load_v ``numpy.ndarray``
The voltage magnitude of the bus to which each load is connected (in kV)
"""
pass
@abstractmethod
def lines_or_info(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.p_or`,
:attr:`grid2op.Observation.BaseObservation.q_or`,
:attr:`grid2op.Observation.BaseObservation.a_or` and,
:attr:`grid2op.Observation.BaseObservation.v_or` instead
It returns the information extracted from the _grid at the origin end of each powerline.
For assumption about the order of the powerline flows return in this vector, see the help of the
:func:`Backend.get_line_status` method.
Returns
-------
p_or ``numpy.ndarray``
the origin active power flowing on the lines (in MW)
q_or ``numpy.ndarray``
the origin reactive power flowing on the lines (in MVAr)
v_or ``numpy.ndarray``
the voltage magnitude at the origin of each powerlines (in kV)
a_or ``numpy.ndarray``
the current flow at the origin of each powerlines (in A)
"""
pass
@abstractmethod
def lines_ex_info(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.p_ex`,
:attr:`grid2op.Observation.BaseObservation.q_ex`,
:attr:`grid2op.Observation.BaseObservation.a_ex` and,
:attr:`grid2op.Observation.BaseObservation.v_ex` instead
It returns the information extracted from the _grid at the extremity end of each powerline.
For assumption about the order of the powerline flows return in this vector, see the help of the
:func:`Backend.get_line_status` method.
Returns
-------
p_ex ``numpy.ndarray``
the extremity active power flowing on the lines (in MW)
q_ex ``numpy.ndarray``
the extremity reactive power flowing on the lines (in MVAr)
v_ex ``numpy.ndarray``
the voltage magnitude at the extremity of each powerlines (in kV)
a_ex ``numpy.ndarray``
the current flow at the extremity of each powerlines (in A)
"""
pass
def close(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
This is called by `env.close()` do not attempt to use it otherwise.
This function is called when the environment is over.
After calling this function, the backend might not behave properly, and in any case should not be used before
another call to :func:`Backend.load_grid` is performed
"""
pass
def reset(self, grid_path, grid_filename=None):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
This is done in the `env.reset()` method and should be performed otherwise.
Reload the power grid.
For backwards compatibility this method calls `Backend.load_grid`.
But it is encouraged to overload it in the subclasses.
"""
self.comp_time = 0.0
self.load_grid(grid_path, filename=grid_filename)
def copy(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
.. note::
As of grid2op 1.7.1 you it is not mandatory to implement this function
when creating a backend.
If it is not available, then grid2op will automatically
deactivate the forecast capability and will not use the "backend.copy()"
function.
When this function is not implement, you will not be able to use (for
example) :func:`grid2op.Observation.BaseObservation.simulate` nor
the :class:`grid2op.simulator.Simulator` for example.
Performs a deep copy of the backend.
In the default implementation we explicitly called the deepcopy operator on `self._grid` to make the
error message more explicit in case there is a problem with this part.
The implementation is **equivalent** to:
.. code-block:: python
def copy(self):
return copy.deepcopy(self)
:return: An instance of Backend equal to :attr:`self`, but deep copied.
:rtype: :class:`Backend`
"""
if not self._can_be_copied:
raise BackendError("This backend cannot be copied.")
start_grid = self._grid
self._grid = None
res = copy.deepcopy(self)
res.__class__ = type(self) # somehow deepcopy forget the init class... weird
res._grid = copy.deepcopy(start_grid)
self._grid = start_grid
res._is_loaded = False # i can reload a copy of an environment
return res
def save_file(self, full_path):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Save the current power _grid in a human readable format supported by the backend.
The format is not modified by this wrapper.
This function is not mandatory, and if implemented, it is used only as a debugging purpose.
:param full_path: the full path (path + file name + extension) where *self._grid* is stored.
:type full_path: :class:`string`
:return: ``None``
"""
raise RuntimeError("Class {} does not allow for saving file.".format(self))
def get_line_status(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.line_status` instead
Return the status of each lines (connected : True / disconnected: False )
It is assume that the order of the powerline is fixed: if the status of powerline "l1" is put at the 42nd element
of the return vector, then it should always be set at the 42nd element.
It is also assumed that all the other methods of the backend that allows to retrieve informations on the powerlines
also respect the same convention, and consistent with one another.
For example, if powerline "l1" is the 42nd second of the vector returned by :func:`Backend.get_line_status` then information
about it's flow will be at position *42* of the vector returned by :func:`Backend.get_line_flow` for example.
:return: an array with the line status of each powerline
:rtype: np.array, dtype:bool
"""
topo_vect = self.get_topo_vect()
return (topo_vect[self.line_or_pos_topo_vect] >= 0) & (
topo_vect[self.line_ex_pos_topo_vect] >= 0
)
def get_line_flow(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.a_or` or
:attr:`grid2op.Observation.BaseObservation.a_ex` for example
Return the current flow in each lines of the powergrid. Only one value per powerline is returned.
If the AC mod is used, this shall return the current flow on the end of the powerline where there is a protection.
For example, if there is a protection on "origin end" of powerline "l2" then this method shall return the current
flow of at the "origin end" of powerline l2.
Note that in general, there is no loss of generality in supposing all protections are set on the "origin end" of
the powerline. So this method will return all origin line flows.
It is also possible, for a specific application, to return the maximum current flow between both ends of a power
_grid for more complex scenario.
For assumption about the order of the powerline flows return in this vector, see the help of the
:func:`Backend.get_line_status` method.
:return: an array with the line flows of each powerline
:rtype: np.array, dtype:float
"""
p_or, q_or, v_or, a_or = self.lines_or_info()
return a_or
def set_thermal_limit(self, limits):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
You can set the thermal limit directly in the environment.
This function is used as a convenience function to set the thermal limits :attr:`Backend.thermal_limit_a`
in amperes.
It can be used at the beginning of an episode if the thermal limit are not present in the original data files
or alternatively if the thermal limits depends on the period of the year (one in winter and one in summer
for example).
Parameters
----------
limits: ``object``
It can be understood differently according to its type:
- If it's a ``numpy.ndarray``, then it is assumed the thermal limits are given in amperes in the same order
as the powerlines computed in the backend. In that case it modifies all the thermal limits of all
the powerlines at once.
- If it's a ``dict`` it must have:
- as key the powerline names (not all names are mandatory, in that case only the powerlines with the name
in this dictionnary will be modified)
- as value the new thermal limit (should be a strictly positive float).
"""
if isinstance(limits, np.ndarray):
if limits.shape[0] == self.n_line:
self.thermal_limit_a = 1.0 * limits.astype(dt_float)
elif isinstance(limits, dict):
for el in limits.keys():
if not el in self.name_line:
raise BackendError(
'You asked to modify the thermal limit of powerline named "{}" that is not '
"on the grid. Names of powerlines are {}".format(
el, self.name_line
)
)
for i, el in self.name_line:
if el in limits:
try:
tmp = dt_float(limits[el])
except:
raise BackendError(
'Impossible to convert data ({}) for powerline named "{}" into float '
"values".format(limits[el], el)
)
if tmp <= 0:
raise BackendError(
'New thermal limit for powerlines "{}" is not positive ({})'
"".format(el, tmp)
)
self.thermal_limit_a[i] = tmp
def update_thermal_limit_from_vect(self, thermal_limit_a):
"""You can use it if your backend stores the thermal limits
of the grid in a vector (see PandaPowerBackend for example)
.. warning::
This is not called by the environment and cannot be used to
model Dynamic Line Rating. For such purpose please use `update_thermal_limit`
This function is used to create a "Simulator" from a backend for example.
Parameters
----------
vect : np.ndarray
The thermal limits (in A)
"""
thermal_limit_a = np.array(thermal_limit_a).astype(dt_float)
self.thermal_limit_a[:] = thermal_limit_a
def update_thermal_limit(self, env):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
This is done in a call to `env.step` in case of DLR for example.
If you don't want this feature, do not implement it.
Update the new thermal limit in case of DLR for example.
By default it does nothing.
Depending on the operational strategy, it is also possible to implement some
`Dynamic Line Rating <https://en.wikipedia.org/wiki/Dynamic_line_rating_for_electric_utilities>`_ (DLR)
strategies.
In this case, this function will give the thermal limit for a given time step provided the flows and the
weather condition are accessible by the backend. Our methodology doesn't make any assumption on the method
used to get these thermal limits.
Parameters
----------
env: :class:`grid2op.Environment.Environment`
The environment used to compute the thermal limit
"""
pass
def get_thermal_limit(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Retrieve the thermal limit directly from the environment instead (with a call
to :func:`grid2op.Environment.BaseEnc.get_thermal_limit` for example)
Gives the thermal limit (in amps) for each powerline of the _grid. Only one value per powerline is returned.
It is assumed that both :func:`Backend.get_line_flow` and *_get_thermal_limit* gives the value of the same
end of the powerline.
See the help of *_get_line_flow* for a more detailed description of this problem.
For assumption about the order of the powerline flows return in this vector, see the help of the
:func:`Backend.get_line_status` method.
:return: An array giving the thermal limit of the powerlines.
:rtype: np.array, dtype:float
"""
return self.thermal_limit_a
def get_relative_flow(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.rho`
This method return the relative flows, *eg.* the current flow divided by the thermal limits. It has a pretty
straightforward default implementation, but it can be overriden for example for transformer if the limits are
on the lower voltage side or on the upper voltage level.
Returns
-------
res: ``numpy.ndarray``, dtype: float
The relative flow in each powerlines of the grid.
"""
num_ = self.get_line_flow()
denom_ = self.get_thermal_limit()
res = np.divide(num_, denom_)
return res
def get_line_overflow(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.rho` and
check whether or not the flow is higher tha 1. or have a look at
:attr:`grid2op.Observation.BaseObservation.timestep_overflow` and check the
non zero index.
Prefer using the attribute of the :class:`grid2op.Observation.BaseObservation`
faster accessor to the line that are on overflow.
For assumption about the order of the powerline flows return in this vector, see the help of the
:func:`Backend.get_line_status` method.
:return: An array saying if a powerline is overflow or not
:rtype: np.array, dtype:bool
"""
th_lim = self.get_thermal_limit()
flow = self.get_line_flow()
return flow > th_lim
def shunt_info(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
This method is optional. If implemented, it should return the proper information about the shunt in the
powergrid.
If not implemented it returns empty list.
Note that if there are shunt on the powergrid, it is recommended that this method should be implemented before
calling :func:`Backend.check_kirchoff`.
If this method is implemented AND :func:`Backend.check_kirchoff` is called, the method
:func:`Backend.sub_from_bus_id` should also be implemented preferably.
Returns
-------
shunt_p: ``numpy.ndarray``
For each shunt, the active power it withdraw at the bus to which it is connected.
shunt_q: ``numpy.ndarray``
For each shunt, the reactive power it withdraw at the bus to which it is connected.
shunt_v: ``numpy.ndarray``
For each shunt, the voltage magnitude of the bus to which it is connected.
shunt_bus: ``numpy.ndarray``
For each shunt, the bus id to which it is connected.
"""
return [], [], [], []
def get_theta(self):
"""
Notes
-----
Don't forget to set the flag :attr:`Backend.can_output_theta` to ``True`` in the
:func:`Bakcend.load_grid` if you support this feature.
Returns
-------
line_or_theta: ``numpy.ndarray``
For each origin side of powerline, gives the voltage angle
line_ex_theta: ``numpy.ndarray``
For each extremity side of powerline, gives the voltage angle
load_theta: ``numpy.ndarray``
Gives the voltage angle to the bus at which each load is connected
gen_theta: ``numpy.ndarray``
Gives the voltage angle to the bus at which each generator is connected
storage_theta: ``numpy.ndarray``
Gives the voltage angle to the bus at which each storage unit is connected
"""
raise NotImplementedError(
"Your backend does not support the retrieval of the voltage angle theta."
)
def sub_from_bus_id(self, bus_id):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Optional method that allows to get the substation if the bus id is provided.
Parameters
----------
bus_id: ``int``
The id of the bus where you want to know to which substation it belongs
Returns
-------
The substation to which an object connected to bus with id `bus_id` is connected to.
"""
raise BackendError(
"This backend doesn't allow to get the substation from the bus id."
)
def _disconnect_line(self, id_):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using the action space to disconnect a powerline.
Disconnect the line of id "id\\_ " in the backend.
In this scenario, the *id\\_* of a powerline is its position (counted starting from O) in the vector returned by
:func:`Backend.get_line_status` or :func:`Backend.get_line_flow` for example.
For example, if the current flow on powerline "l1" is the 42nd element of the vector returned by
:func:`Backend.get_line_flow`
then :func:`Backend._disconnect_line(42)` will disconnect this same powerline "l1".
For assumption about the order of the powerline flows return in this vector, see the help of the
:func:`Backend.get_line_status` method.
:param id_: id of the powerline to be disconnected
:type id_: int
"""
my_cls = type(self)
action = my_cls._complete_action_class()
action.update({"set_line_status": [(id_, -1)]})
bk_act = my_cls.my_bk_act_class()
bk_act += action
self.apply_action(bk_act)
def _runpf_with_diverging_exception(self, is_dc):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Computes a power flow on the _grid and raises an exception in case of diverging power flow, or any other
exception that can be thrown by the backend.
:param is_dc: mode of the power flow. If *is_dc* is True, then the powerlow is run using the DC
approximation otherwise it uses the AC powerflow.
:type is_dc: bool
Raises
------
exc_: :class:`grid2op.Exceptions.DivergingPowerFlow`
In case of divergence of the powerflow
"""
conv = False
exc_me = None
try:
conv, exc_me = self.runpf(is_dc=is_dc) # run powerflow
except Grid2OpException as exc_:
exc_me = exc_
except Exception as exc_:
exc_me = DivergingPowerFlow(
f" An unexpected error occurred during the computation of the powerflow."
f"The error is: \n {exc_} \n. This is game over"
)
if not conv and exc_me is None:
exc_me = DivergingPowerFlow(
"GAME OVER: Powerflow has diverged during computation "
"or a load has been disconnected or a generator has been disconnected."
)
return exc_me
def next_grid_state(self, env, is_dc=False):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
This is called by `env.step`
This method is called by the environment to compute the next\\_grid\\_states.
It allows to compute the powerline and approximate the "cascading failures" if there are some overflows.
Attributes
----------
env: :class:`grid2op.Environment.Environment`
the environment in which the powerflow is ran.
is_dc: ``bool``
mode of power flow (AC : False, DC: is_dc is True)
Returns
--------
disconnected_during_cf: ``numpy.ndarray``, dtype=bool
For each powerlines, it returns ``True`` if the powerline has been disconnected due to a cascading failure
or ``False`` otherwise.
infos: ``list``
If :attr:`Backend.detailed_infos_for_cascading_failures` is ``True`` then it returns the different
state computed by the powerflow (can drastically slow down this function, as it requires
deep copy of backend object). Otherwise the list is always empty.
"""
infos = []
disconnected_during_cf = np.full(self.n_line, fill_value=-1, dtype=dt_int)
conv_ = self._runpf_with_diverging_exception(is_dc)
if env._no_overflow_disconnection or conv_ is not None:
return disconnected_during_cf, infos, conv_
# the environment disconnect some powerlines
init_time_step_overflow = copy.deepcopy(env._timestep_overflow)
ts = 0
while True:
# simulate the cascading failure
lines_flows = 1.0 * self.get_line_flow()
thermal_limits = self.get_thermal_limit()
lines_status = self.get_line_status()
# a) disconnect lines on hard overflow (that are still connected)
to_disc = (
lines_flows > env._hard_overflow_threshold * thermal_limits
) & lines_status
# b) deals with soft overflow (disconnect them if lines still connected)
init_time_step_overflow[(lines_flows >= thermal_limits) & lines_status] += 1
to_disc[
(init_time_step_overflow > env._nb_timestep_overflow_allowed)
& lines_status
] = True
# disconnect the current power lines
if np.sum(to_disc[lines_status]) == 0:
# no powerlines have been disconnected at this time step, i stop the computation there
break
disconnected_during_cf[to_disc] = ts
# perform the disconnection action
for i, el in enumerate(to_disc):
if el:
self._disconnect_line(i)
# start a powerflow on this new state
conv_ = self._runpf_with_diverging_exception(is_dc)
if self.detailed_infos_for_cascading_failures:
infos.append(self.copy())
if conv_ is not None:
break
ts += 1
return disconnected_during_cf, infos, conv_
def storages_info(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
Prefer using :attr:`grid2op.Observation.BaseObservation.storage_power` instead.
This method is used to retrieve information about the storage units (active, reactive consumption
and voltage magnitude of the bus to which it is connected).
Returns
-------
storage_p ``numpy.ndarray``
The active power consumption for each load (in MW)
storage_q ``numpy.ndarray``
The reactive power consumption for each load (in MVAr)
storage_v ``numpy.ndarray``
The voltage magnitude of the bus to which each load is connected (in kV)
"""
if self.n_storage > 0:
raise BackendError(
"storages_info method is not implemented yet there is batteries on the grid."
)
def storage_deact_for_backward_comaptibility(self):
"""
INTERNAL
.. warning:: /!\\\\ Internal, do not use unless you know what you are doing /!\\\\
This function is called under a very specific condition: an old environment has been loaded that
do not take into account the storage units, even though they were possibly some modeled by the backend.