EOS/single_test_optimization.py

#!/usr/bin/env python3

from pprint import pprint

# Import necessary modules from the project
from modules.class_optimize import optimization_problem

start_hour = 10

# PV Forecast (in W)
pv_forecast = [
    0,
    0,
    0,
    0,
    0,
    0,
    0,
    8.05,
    352.91,
    728.51,
    930.28,
    1043.25,
    1106.74,
    1161.69,
    6018.82,
    5519.07,
    3969.88,
    3017.96,
    1943.07,
    1007.17,
    319.67,
    7.88,
    0,
    0,
    0,
    0,
    0,
    0,
    0,
    0,
    0,
    5.04,
    335.59,
    705.32,
    1121.12,
    1604.79,
    2157.38,
    1433.25,
    5718.49,
    4553.96,
    3027.55,
    2574.46,
    1720.4,
    963.4,
    383.3,
    0,
    0,
    0,
]

# Temperature Forecast (in degree C)
temperature_forecast = [
    18.3,
    17.8,
    16.9,
    16.2,
    15.6,
    15.1,
    14.6,
    14.2,
    14.3,
    14.8,
    15.7,
    16.7,
    17.4,
    18.0,
    18.6,
    19.2,
    19.1,
    18.7,
    18.5,
    17.7,
    16.2,
    14.6,
    13.6,
    13.0,
    12.6,
    12.2,
    11.7,
    11.6,
    11.3,
    11.0,
    10.7,
    10.2,
    11.4,
    14.4,
    16.4,
    18.3,
    19.5,
    20.7,
    21.9,
    22.7,
    23.1,
    23.1,
    22.8,
    21.8,
    20.2,
    19.1,
    18.0,
    17.4,
]

# Electricity Price (in Euro per Wh)
strompreis_euro_pro_wh = [
    0.0003384,
    0.0003318,
    0.0003284,
    0.0003283,
    0.0003289,
    0.0003334,
    0.0003290,
    0.0003302,
    0.0003042,
    0.0002430,
    0.0002280,
    0.0002212,
    0.0002093,
    0.0001879,
    0.0001838,
    0.0002004,
    0.0002198,
    0.0002270,
    0.0002997,
    0.0003195,
    0.0003081,
    0.0002969,
    0.0002921,
    0.0002780,
    0.0003384,
    0.0003318,
    0.0003284,
    0.0003283,
    0.0003289,
    0.0003334,
    0.0003290,
    0.0003302,
    0.0003042,
    0.0002430,
    0.0002280,
    0.0002212,
    0.0002093,
    0.0001879,
    0.0001838,
    0.0002004,
    0.0002198,
    0.0002270,
    0.0002997,
    0.0003195,
    0.0003081,
    0.0002969,
    0.0002921,
    0.0002780,
]

# Overall System Load (in W)
gesamtlast = [
    676.71,
    876.19,
    527.13,
    468.88,
    531.38,
    517.95,
    483.15,
    472.28,
    1011.68,
    995.00,
    1053.07,
    1063.91,
    1320.56,
    1132.03,
    1163.67,
    1176.82,
    1216.22,
    1103.78,
    1129.12,
    1178.71,
    1050.98,
    988.56,
    912.38,
    704.61,
    516.37,
    868.05,
    694.34,
    608.79,
    556.31,
    488.89,
    506.91,
    804.89,
    1141.98,
    1056.97,
    992.46,
    1155.99,
    827.01,
    1257.98,
    1232.67,
    871.26,
    860.88,
    1158.03,
    1222.72,
    1221.04,
    949.99,
    987.01,
    733.99,
    592.97,
]

# Start Solution (binary)
start_solution = [
    1,
    1,
    1,
    1,
    0,
    1,
    0,
    0,
    1,
    1,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    0,
    0,
    0,
    0,
    0,
    0,
    1,
    0,
    0,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    0,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
    1,
]

# Define parameters for the optimization problem
parameter = {
    # Cost of storing energy in battery (per Wh)
    "preis_euro_pro_wh_akku": 10e-05,
    # Initial state of charge (SOC) of PV battery (%)
    "pv_soc": 80,
    # Battery capacity (in Wh)
    "pv_akku_cap": 26400,
    # Yearly energy consumption (in Wh)
    "year_energy": 4100000,
    # Feed-in tariff for exporting electricity (per Wh)
    "einspeiseverguetung_euro_pro_wh": 7e-05,
    # Maximum heating power (in W)
    "max_heizleistung": 1000,
    # Overall load on the system
    "gesamtlast": gesamtlast,
    # PV generation forecast (48 hours)
    "pv_forecast": pv_forecast,
    # Temperature forecast (48 hours)
    "temperature_forecast": temperature_forecast,
    # Electricity price forecast (48 hours)
    "strompreis_euro_pro_wh": strompreis_euro_pro_wh,
    # Minimum SOC for electric car
    "eauto_min_soc": 70,
    # Electric car battery capacity (Wh)
    "eauto_cap": 60000,
    # Charging efficiency of the electric car
    "eauto_charge_efficiency": 0.95,
    # Charging power of the electric car (W)
    "eauto_charge_power": 11040,
    # Current SOC of the electric car (%)
    "eauto_soc": 54,
    # Current PV power generation (W)
    "pvpowernow": 211.137503624,
    # Initial solution for the optimization
    "start_solution": start_solution,
    # Household appliance consumption (Wh)
    "haushaltsgeraet_wh": 937,
    # Duration of appliance usage (hours)
    "haushaltsgeraet_dauer": 0,
}

# Initialize the optimization problem
opt_class = optimization_problem(prediction_hours=48, strafe=10, optimization_hours=24)

# Perform the optimisation based on the provided parameters and start hour
ergebnis = opt_class.optimierung_ems(parameter=parameter, start_hour=start_hour)

# Print or visualize the result
pprint(ergebnis)