Files
EOS/src/akkudoktoreos/optimization/genetic/geneticparams.py
Andreas 7f2ac9098c feat: Direktvermarktung mit Batterie-Netzeinspeisung
Fügt einen Direktvermarktungs-Modus (feedintariff.direct_marketing_enabled)
hinzu, der den Börsenpreis als Einspeisevergütung nutzt und aktive
Batterie-Entladung ins Netz (battery_grid_export_allowed) sowie
DC-Charge-Bypass optimiert.

- FeedInTariffEnergyCharts-Provider (Börsen-Einspeisetarif inkl. Prognose)
- Inverter: DC/AC-Wirkungsgrade und Batterie-Grid-Export in process_energy
- Genetik: Export-/DC-Charge-Zustände, Restwert-Bewertung des Akkus
- Solution-Result: neues Feld Feed_in_tariff (verwendeter Tarif je Stunde)
- Tests für neue Provider, Solution und Simulation

Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
2026-07-12 09:01:33 +02:00

657 lines
30 KiB
Python

"""GENETIC algorithm paramters.
This module defines the Pydantic-based configuration and input parameter models
used in the energy optimization routines, including photovoltaic forecasts,
electricity pricing, and system component parameters.
It also provides a method to assemble these parameters from predictions,
forecasts, and fallback defaults, preparing them for optimization runs.
"""
from typing import Optional, Union
from loguru import logger
from pydantic import Field, field_validator, model_validator
from typing_extensions import Self
from akkudoktoreos.core.coreabc import (
ConfigMixin,
MeasurementMixin,
PredictionMixin,
get_ems,
)
from akkudoktoreos.optimization.genetic.geneticabc import GeneticParametersBaseModel
from akkudoktoreos.optimization.genetic.geneticdevices import (
ElectricVehicleParameters,
HomeApplianceParameters,
InverterParameters,
SolarPanelBatteryParameters,
)
from akkudoktoreos.utils.datetimeutil import to_duration
# Do not import directly from akkudoktoreos.core.coreabc
# EnergyManagementSystemMixin - Creates circular dependency with ems.py
# StartMixin - Creates circular dependency with ems.py
class GeneticEnergyManagementParameters(GeneticParametersBaseModel):
"""Encapsulates energy-related forecasts and costs used in GENETIC optimization."""
pv_prognose_wh: list[float] = Field(
json_schema_extra={
"description": "An array of floats representing the forecasted photovoltaic output in watts for different time intervals."
}
)
strompreis_euro_pro_wh: list[float] = Field(
json_schema_extra={
"description": "An array of floats representing the electricity price in euros per watt-hour for different time intervals."
}
)
einspeiseverguetung_euro_pro_wh: Union[list[float], float] = Field(
json_schema_extra={
"description": "A float or array of floats representing the feed-in compensation in euros per watt-hour."
}
)
preis_euro_pro_wh_akku: float = Field(
json_schema_extra={
"description": "A float representing the cost of battery energy per watt-hour."
}
)
gesamtlast: list[float] = Field(
json_schema_extra={
"description": "An array of floats representing the total load (consumption) in watts for different time intervals."
}
)
@model_validator(mode="after")
def validate_list_length(self) -> Self:
"""Validate that all input lists are of the same length.
Raises:
ValueError: If input list lengths differ.
"""
pv_prognose_length = len(self.pv_prognose_wh)
if (
pv_prognose_length != len(self.strompreis_euro_pro_wh)
or pv_prognose_length != len(self.gesamtlast)
or (
isinstance(self.einspeiseverguetung_euro_pro_wh, list)
and pv_prognose_length != len(self.einspeiseverguetung_euro_pro_wh)
)
):
raise ValueError("Input lists have different lengths")
return self
class GeneticOptimizationParameters(
ConfigMixin,
MeasurementMixin,
PredictionMixin,
# EnergyManagementSystemMixin, # Creates circular dependency with ems.py
# StartMixin, # Creates circular dependency with ems.py
GeneticParametersBaseModel,
):
"""Main parameter class for running the genetic energy optimization.
Collects all model and configuration parameters necessary to run the
optimization process, such as forecasts, pricing, battery and appliance models.
"""
ems: GeneticEnergyManagementParameters
pv_akku: Optional[SolarPanelBatteryParameters]
inverter: Optional[InverterParameters]
eauto: Optional[ElectricVehicleParameters]
dishwasher: Optional[HomeApplianceParameters] = None
temperature_forecast: Optional[list[Optional[float]]] = Field(
default=None,
json_schema_extra={
"description": "An array of floats representing the temperature forecast in degrees Celsius for different time intervals."
},
)
start_solution: Optional[list[float]] = Field(
default=None,
json_schema_extra={
"description": "Can be `null` or contain a previous solution (if available)."
},
)
@model_validator(mode="after")
def validate_list_length(self) -> Self:
"""Ensure that temperature forecast list matches the PV forecast length.
Raises:
ValueError: If list lengths mismatch.
"""
arr_length = len(self.ems.pv_prognose_wh)
if self.temperature_forecast is not None and arr_length != len(self.temperature_forecast):
raise ValueError("Input lists have different lengths")
return self
@field_validator("start_solution")
def validate_start_solution(
cls, start_solution: Optional[list[float]]
) -> Optional[list[float]]:
"""Validate that the starting solution has at least two elements.
Args:
start_solution (list[float]): Optional list of solution values.
Returns:
list[float]: Validated list.
Raises:
ValueError: If the solution is too short.
"""
if start_solution is not None and len(start_solution) < 2:
raise ValueError("Requires at least two values.")
return start_solution
@classmethod
def prepare(cls) -> "Optional[GeneticOptimizationParameters]":
"""Prepare optimization parameters from config, forecast and measurement data.
Fills in values needed for optimization from available configuration, predictions and
measurements. If some data is missing, default or demo values are used.
Parameters start by definition of the genetic algorithm at hour 0 of the actual date
(not at start datetime of energy management run)
Returns:
GeneticOptimizationParameters: The fully prepared optimization parameters.
Raises:
ValueError: If required configuration values like start time are missing.
"""
ems = get_ems()
# The optimization paramters
oparams: "Optional[GeneticOptimizationParameters]" = None
# Check for run definitions
if ems.start_datetime is None:
error_msg = "Start datetime unknown."
logger.error(error_msg)
raise ValueError(error_msg)
# Check for general predictions conditions
if cls.config.general.latitude is None:
default_latitude = 52.52
logger.info(f"Latitude unknown - defaulting to {default_latitude}.")
cls.config.general.latitude = default_latitude
if cls.config.general.longitude is None:
default_longitude = 13.405
logger.info(f"Longitude unknown - defaulting to {default_longitude}.")
cls.config.general.longitude = default_longitude
if cls.config.prediction.hours is None:
logger.info("Prediction hours unknown - defaulting to 48 hours.")
cls.config.prediction.hours = 48
if cls.config.prediction.historic_hours is None:
logger.info("Prediction historic hours unknown - defaulting to 24 hours.")
cls.config.prediction.historic_hours = 24
# Check optimization definitions
if cls.config.optimization.horizon_hours is None:
logger.info("Optimization horizon unknown - defaulting to 24 hours.")
cls.config.optimization.horizon_hours = 24
if cls.config.optimization.interval is None:
logger.info("Optimization interval unknown - defaulting to 3600 seconds.")
cls.config.optimization.interval = 3600
if cls.config.optimization.interval != 3600:
logger.info(
"Optimization interval '{}' seconds not supported - forced to 3600 seconds."
)
cls.config.optimization.interval = 3600
# Check genetic algorithm definitions
if cls.config.optimization.genetic.individuals is None:
logger.info("Genetic individuals unknown - defaulting to 300.")
cls.config.optimization.genetic.individuals = 300
if cls.config.optimization.genetic.generations is None:
logger.info("Genetic generations unknown - defaulting to 400.")
cls.config.optimization.genetic.generations = 400
if "ev_soc_miss" not in cls.config.optimization.genetic.penalties:
logger.info("Genetic penalties unknown - defaulting to ev_soc_miss = 10.")
cls.config.optimization.genetic.penalties["ev_soc_miss"] = 10
# Get start solution from last run
start_solution = None
last_solution = ems.genetic_solution()
if last_solution and last_solution.start_solution:
start_solution = last_solution.start_solution
# Add forecast and device data
interval = to_duration(cls.config.optimization.interval)
power_to_energy_per_interval_factor = cls.config.optimization.interval / 3600
parameter_start_datetime = ems.start_datetime.set(hour=0, second=0, microsecond=0)
parameter_end_datetime = parameter_start_datetime.add(hours=cls.config.prediction.hours)
max_retries = 10
for attempt in range(1, max_retries + 1):
# Collect all the data for optimisation, but do not exceed max retries
if attempt > max_retries:
error_msg = f"Maximum retries {max_retries} for parameter collection exceeded. Parameter preparation attempt {attempt}."
logger.error(error_msg)
raise ValueError(error_msg)
# Assure predictions are uptodate
cls.prediction.update_data()
try:
pvforecast_ac_power = (
cls.prediction.key_to_array(
key="pvforecast_ac_power",
start_datetime=parameter_start_datetime,
end_datetime=parameter_end_datetime,
interval=interval,
fill_method="linear",
)
* power_to_energy_per_interval_factor
).tolist()
except:
logger.info(
"No PV forecast data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.merge_settings_from_dict(
{
"pvforecast": {
"provider": "PVForecastAkkudoktor",
"max_planes": 4,
"planes": [
{
"peakpower": 5.0,
"surface_azimuth": 170,
"surface_tilt": 7,
"userhorizon": [20, 27, 22, 20],
"inverter_paco": 10000,
},
{
"peakpower": 4.8,
"surface_azimuth": 90,
"surface_tilt": 7,
"userhorizon": [30, 30, 30, 50],
"inverter_paco": 10000,
},
{
"peakpower": 1.4,
"surface_azimuth": 140,
"surface_tilt": 60,
"userhorizon": [60, 30, 0, 30],
"inverter_paco": 2000,
},
{
"peakpower": 1.6,
"surface_azimuth": 185,
"surface_tilt": 45,
"userhorizon": [45, 25, 30, 60],
"inverter_paco": 1400,
},
],
},
}
)
# Retry
continue
try:
elecprice_marketprice_wh = cls.prediction.key_to_array(
key="elecprice_marketprice_wh",
start_datetime=parameter_start_datetime,
end_datetime=parameter_end_datetime,
interval=interval,
fill_method="ffill",
).tolist()
except:
logger.info(
"No Electricity Marketprice forecast data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.elecprice.provider = "ElecPriceAkkudoktor"
# Retry
continue
try:
loadforecast_power_w = cls.prediction.key_to_array(
key="loadforecast_power_w",
start_datetime=parameter_start_datetime,
end_datetime=parameter_end_datetime,
interval=interval,
fill_method="ffill",
).tolist()
except:
logger.info(
"No Load forecast data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.merge_settings_from_dict(
{
"load": {
"provider": "LoadAkkudoktor",
"loadakkudoktor": {
"loadakkudoktor_year_energy_kwh": "3000",
},
},
}
)
# Retry
continue
if cls.config.feedintariff.direct_marketing_enabled:
if cls.config.feedintariff.provider == "FeedInTariffEnergyCharts":
try:
feed_in_tariff_wh = cls.prediction.key_to_array(
key="feed_in_tariff_wh",
start_datetime=parameter_start_datetime,
end_datetime=parameter_end_datetime,
interval=interval,
fill_method="ffill",
).tolist()
except:
feed_in_tariff_wh = list(elecprice_marketprice_wh)
else:
feed_in_tariff_wh = list(elecprice_marketprice_wh)
else:
try:
feed_in_tariff_wh = cls.prediction.key_to_array(
key="feed_in_tariff_wh",
start_datetime=parameter_start_datetime,
end_datetime=parameter_end_datetime,
interval=interval,
fill_method="ffill",
).tolist()
except:
logger.info(
"No feed in tariff forecast data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.merge_settings_from_dict(
{
"feedintariff": {
"provider": "FeedInTariffFixed",
"provider_settings": {
"FeedInTariffFixed": {
"feed_in_tariff_kwh": 0.078,
},
},
},
}
)
# Retry
continue
try:
weather_temp_air = cls.prediction.key_to_array(
key="weather_temp_air",
start_datetime=parameter_start_datetime,
end_datetime=parameter_end_datetime,
interval=interval,
fill_method="ffill",
).tolist()
except:
logger.info(
"No weather forecast data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.weather.provider = "BrightSky"
# Retry
continue
# Add device data
# Batteries
# ---------
if cls.config.devices.max_batteries is None:
logger.info("Number of battery devices not configured - defaulting to 1.")
cls.config.devices.max_batteries = 1
if cls.config.devices.max_batteries == 0:
battery_params = None
battery_lcos_kwh = 0
else:
if cls.config.devices.batteries is None:
logger.info("No battery device data available - defaulting to demo data.")
cls.config.devices.batteries = [{"device_id": "battery1", "capacity_wh": 8000}]
try:
battery_config = cls.config.devices.batteries[0]
battery_params = SolarPanelBatteryParameters(
device_id=battery_config.device_id,
capacity_wh=battery_config.capacity_wh,
charging_efficiency=battery_config.charging_efficiency,
discharging_efficiency=battery_config.discharging_efficiency,
max_charge_power_w=battery_config.max_charge_power_w,
min_soc_percentage=battery_config.min_soc_percentage,
max_soc_percentage=battery_config.max_soc_percentage,
charge_rates=battery_config.charge_rates,
)
except:
logger.info(
"No battery device data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.devices.batteries = [{"device_id": "battery1", "capacity_wh": 8000}]
# Retry
continue
# Levelized cost of ownership
if battery_config.levelized_cost_of_storage_kwh is None:
logger.info(
"No battery device LCOS data available - defaulting to 0 €/kWh. Parameter preparation attempt {}.",
attempt,
)
battery_config.levelized_cost_of_storage_kwh = 0
battery_lcos_kwh = battery_config.levelized_cost_of_storage_kwh
# Initial SOC
try:
initial_soc_factor = cls.measurement.key_to_value(
key=battery_config.measurement_key_soc_factor,
target_datetime=ems.start_datetime,
time_window=to_duration(to_duration("48 hours")),
)
if initial_soc_factor > 1.0 or initial_soc_factor < 0.0:
logger.error(
f"Invalid battery initial SoC factor {initial_soc_factor} - defaulting to 0.0."
)
initial_soc_factor = 0.0
# genetic parameter is 0..100 as int
initial_soc_percentage = int(initial_soc_factor * 100)
except:
initial_soc_percentage = None
if initial_soc_percentage is None:
logger.info(
f"No battery device SoC data (measurement key = '{battery_config.measurement_key_soc_factor}') available - defaulting to 0."
)
initial_soc_percentage = 0
battery_params.initial_soc_percentage = initial_soc_percentage
# Electric Vehicles
# -----------------
if cls.config.devices.max_electric_vehicles is None:
logger.info("Number of electric_vehicle devices not configured - defaulting to 1.")
cls.config.devices.max_electric_vehicles = 1
if cls.config.devices.max_electric_vehicles == 0:
electric_vehicle_params = None
else:
if cls.config.devices.electric_vehicles is None:
logger.info(
"No electric vehicle device data available - defaulting to demo data."
)
cls.config.devices.max_electric_vehicles = 1
cls.config.devices.electric_vehicles = [
{
"device_id": "ev11",
"capacity_wh": 50000,
"charge_rates": [0.0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0],
"min_soc_percentage": 70,
}
]
try:
electric_vehicle_config = cls.config.devices.electric_vehicles[0]
electric_vehicle_params = ElectricVehicleParameters(
device_id=electric_vehicle_config.device_id,
capacity_wh=electric_vehicle_config.capacity_wh,
charging_efficiency=electric_vehicle_config.charging_efficiency,
discharging_efficiency=electric_vehicle_config.discharging_efficiency,
charge_rates=electric_vehicle_config.charge_rates,
max_charge_power_w=electric_vehicle_config.max_charge_power_w,
min_soc_percentage=electric_vehicle_config.min_soc_percentage,
max_soc_percentage=electric_vehicle_config.max_soc_percentage,
)
except:
logger.info(
"No electric_vehicle device data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.devices.max_electric_vehicles = 1
cls.config.devices.electric_vehicles = [
{
"device_id": "ev12",
"capacity_wh": 50000,
"charge_rates": [0.0, 0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0],
"min_soc_percentage": 70,
}
]
# Retry
continue
# Initial SOC
try:
initial_soc_factor = cls.measurement.key_to_value(
key=electric_vehicle_config.measurement_key_soc_factor,
target_datetime=ems.start_datetime,
time_window=to_duration(to_duration("48 hours")),
)
if initial_soc_factor > 1.0 or initial_soc_factor < 0.0:
logger.error(
f"Invalid electric vehicle initial SoC factor {initial_soc_factor} - defaulting to 0.0."
)
initial_soc_factor = 0.0
# genetic parameter is 0..100 as int
initial_soc_percentage = int(initial_soc_factor * 100)
except:
initial_soc_percentage = None
if initial_soc_percentage is None:
logger.info(
f"No electric vehicle device SoC data (measurement key = '{electric_vehicle_config.measurement_key_soc_factor}') available - defaulting to 0."
)
initial_soc_percentage = 0
electric_vehicle_params.initial_soc_percentage = initial_soc_percentage
# Inverters
# ---------
if cls.config.devices.max_inverters is None:
logger.info("Number of inverter devices not configured - defaulting to 1.")
cls.config.devices.max_inverters = 1
if cls.config.devices.max_inverters == 0:
inverter_params = None
else:
if cls.config.devices.inverters is None:
logger.info("No inverter device data available - defaulting to demo data.")
cls.config.devices.inverters = [
{
"device_id": "inverter1",
"max_power_w": 10000,
"battery_id": battery_config.device_id,
}
]
try:
inverter_config = cls.config.devices.inverters[0]
inverter_params = InverterParameters(
device_id=inverter_config.device_id,
max_power_wh=inverter_config.max_power_w,
battery_id=inverter_config.battery_id,
ac_to_dc_efficiency=inverter_config.ac_to_dc_efficiency,
dc_to_ac_efficiency=inverter_config.dc_to_ac_efficiency,
max_ac_charge_power_w=inverter_config.max_ac_charge_power_w,
)
except:
logger.info(
"No inverter device data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.devices.inverters = [
{
"device_id": "inverter1",
"max_power_w": 10000,
"battery_id": battery_config.device_id,
}
]
# Retry
continue
# Home Appliances
# ---------------
if cls.config.devices.max_home_appliances is None:
logger.info("Number of home appliance devices not configured - defaulting to 1.")
cls.config.devices.max_home_appliances = 1
if cls.config.devices.max_home_appliances == 0:
home_appliance_params = None
else:
home_appliance_params = None
if cls.config.devices.home_appliances is None:
logger.info(
"No home appliance device data available - defaulting to demo data."
)
cls.config.devices.home_appliances = [
{
"device_id": "dishwasher1",
"consumption_wh": 2000,
"duration_h": 3.0,
"time_windows": {
"windows": [
{
"start_time": "08:00",
"duration": "5 hours",
},
{
"start_time": "15:00",
"duration": "3 hours",
},
],
},
}
]
try:
home_appliance_config = cls.config.devices.home_appliances[0]
home_appliance_params = HomeApplianceParameters(
device_id=home_appliance_config.device_id,
consumption_wh=home_appliance_config.consumption_wh,
duration_h=home_appliance_config.duration_h,
time_windows=home_appliance_config.time_windows,
)
except:
logger.info(
"No home appliance device data available - defaulting to demo data. Parameter preparation attempt {}.",
attempt,
)
cls.config.devices.home_appliances = [
{
"device_id": "dishwasher1",
"consumption_wh": 2000,
"duration_h": 3.0,
"time_windows": None,
}
]
# Retry
continue
# We got all parameter data
try:
oparams = GeneticOptimizationParameters(
ems=GeneticEnergyManagementParameters(
pv_prognose_wh=pvforecast_ac_power,
strompreis_euro_pro_wh=elecprice_marketprice_wh,
einspeiseverguetung_euro_pro_wh=feed_in_tariff_wh,
gesamtlast=loadforecast_power_w,
preis_euro_pro_wh_akku=battery_lcos_kwh / 1000,
),
temperature_forecast=weather_temp_air,
pv_akku=battery_params,
eauto=electric_vehicle_params,
inverter=inverter_params,
dishwasher=home_appliance_params,
start_solution=start_solution,
)
except:
logger.info(
"Can not prepare optimization parameters - will retry. Parameter preparation attempt {}.",
attempt,
)
oparams = None
# Retry
continue
# Parameters prepared
break
return oparams