Source code for smartgrid.observation.global_observation

"""
Global observations of the World, shared by all Agents in the smart grid.
"""

from collections import namedtuple

import numpy as np

from smartgrid.util import hoover

global_fields = [
    'hour',
    'available_energy',
    'equity',
    'energy_loss',
    'autonomy',
    'exclusion',
    'well_being',
    'over_consumption',
]


[docs] class GlobalObservation(namedtuple('GlobalObservation', global_fields)): """ Global observations of the World, shared by all Agents in the smart grid. These observations are not directly linked to a particular agent, but rather to the whole society of agents in the :py:class:`.World`, i.e., in this smart grid. Thus, the measures are the same for all agents. To optimize computations, we thus create global observations only once each step. A global observation is a vector containing the following measures: hour The current hour in the simulated world. It is computed as a ratio between 0 and 1, and days are ignored by using a modulo. Specifically, assuming that the current time step is ``t``, the *hour* measure is computed as ``(t % 24) / 24``. available_energy The quantity of energy available in the grid, which is accessible to all agents. This is a large pool of energy, however they should avoid over-consuming it, and take an appropriate quantity so as to let other agents profit as well. This measure is normalized as a value between 0 and 1, from the *real* available quantity, w.r.t. the bounds of energy that could have been generated at this step. See the :py:mod:`.energy_generator` module for more details on energy generators, and their bounds. equity The equity of comforts between all agents in the grid, i.e., to which degree do they have a similar comfort. It is computed as a statistical indicator of dispersion named the `Hoover index <https://en.wikipedia.org/wiki/Hoover_index>`_, which is a well-known tool in economy, originally made to describe income inequality. ``equity`` is computed as ``1 - hoover(comforts)``, such that 0 represents a perfect inequality (one person has everything, the others nothing), and 1 a perfect equality (everybody has the same comfort). energy_loss The quantity of energy that was available to agents, but not used (i.e., neither consumed nor stored) at this time step. autonomy This measure represents the autonomy, or self-sustainability, of the smart grid. It is measured based on the transactions (i.e., selling or buying energy from and to the national grid), w.r.t. the total amount of energy exchanged within the grid (given, stored, consumed). exclusion The proportion of agents that have a comfort lower than half the median of agents' comforts. Such agents are said to be *excluded*. well_being The median of all agents' comfort. Using a median rather than an average reduces the impact of outliers. over_consumption The quantity of energy that agents have consumed, but was not originally available in the grid. We assume that the grid automatically bought this missing energy from the national grid. It is computed as the sum of energy consumed from the grid and stored from the grid, by all agents, minus the sum of energy given by all agents, and the energy initially available, divided by the sum of energy taken by all agents, to obtain a ratio between 0 and 1. If the measure is less than 0, we set it to 0. """ last_step_compute = -1 """ Last time step at which global observations were computed. This is used to optimize the computations and avoid re-computing already known observations, since these are the same for all agents at a given time step. """ computed = None """ Memoized global observations, computed at the time step indicated by :py:attr:`.last_step_compute`. """
[docs] @classmethod def _is_compute(cls, world: 'World') -> bool: """ Private method to know whether the current step has already been computed. """ return world.current_step == cls.last_step_compute
[docs] @classmethod def compute(cls, world: 'World'): """ Return the global observations computed from the World state. This method uses memoization through :py:attr:`.computed`, :py:meth:`._is_compute` and :py:attr:`.last_step_compute` to avoid re-computing already known observations. In such cases, the cached instance is returned. Otherwise, measures are computed, and a new instance is created, memoized, and returned. :type world: smartgrid.world.World :param world: The World for which we want to compute the global observations. :rtype: GlobalObservation """ # return directly if the step have been computed if cls._is_compute(world): return cls.computed # Pre-compute some intermediate data comforts = [] sum_taken, sum_given, sum_transactions, sum_consumed, sum_stored = 0, 0, 0, 0, 0 for a in world.agents: comforts.append(a.state.comfort) sum_taken += a.enacted_action.grid_consumption + a.enacted_action.store_energy sum_given += a.enacted_action.give_energy sum_transactions += a.enacted_action.buy_energy + a.enacted_action.sell_energy sum_consumed += a.enacted_action.grid_consumption + a.enacted_action.storage_consumption sum_stored += a.enacted_action.store_energy # Compute some common measures about env hour = (world.current_step % 24) / 24 available_energy = np.interp( world.available_energy, world.energy_generator.available_energy_bounds( world.current_need, world.current_step, world.min_needed_energy, world.max_needed_energy ), (0, 1) ) equity = 1.0 - hoover(comforts) over_consumption = max(0.0, sum_taken - sum_given - world.available_energy) over_consumption /= (sum_taken + 10E-300) energy_loss = max(0.0, -over_consumption) autonomy = 1.0 - sum_transactions / (sum_consumed + sum_stored + sum_given + sum_transactions + 10E-300) well_being = np.median(comforts) if np.isnan(well_being): well_being = 0.0 threshold = well_being / 2 exclusion = len([c for c in comforts if c < threshold]) / len(comforts) cls.last_step_compute = world.current_step cls.computed = cls(hour=hour, available_energy=available_energy, equity=equity, energy_loss=energy_loss, autonomy=autonomy, exclusion=exclusion, well_being=well_being, over_consumption=over_consumption, ) return cls.computed
[docs] @classmethod def reset(cls): """ Reset the counter of steps computed, i.e., the memoization. """ cls.last_step_compute = -1