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168 lines
9.2 KiB
168 lines
9.2 KiB
import matplotlib
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matplotlib.use('Qt5Agg') # or 'Qt5Agg', depending on your setup
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import matplotlib.pyplot as plt
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import numpy as np
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import json
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import sys
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import argparse
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__author__ = 'm3x1m0m'
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class c_settings_extractor:
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def __init__(self, fname):
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with open(fname, "r") as rf:
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settings = json.load(rf)
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kilometer_price_ccar = settings["ccar"]["litres_per_kilometer"] * settings["juice_litre_price"]
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self.labels = [settings["ecar"]["label"], settings["ccar"]["label"]]
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self.purchase = np.array([settings["ecar"]["price"], settings["ccar"]["price"]])
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self.taxes = np.array([settings["ecar"]["taxes"], settings["ccar"]["taxes"]])
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self.insurance = np.array([settings["ecar"]["insurance"], settings["ccar"]["insurance"]])
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kilometer_price_ecar = ( settings["ecar"]["charging_behaviour"]["percent_home_charges"] * settings["kwh_price_home"]
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+ settings["ecar"]["charging_behaviour"]["percent_commercial_charges"] * settings["kwh_price_commercial"]) / 100.0
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self.driving = np.array([kilometer_price_ecar * settings["kilometers_per_year"], kilometer_price_ccar * settings["kilometers_per_year"]])
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self.maintenance = np.array([settings["ecar"]["maintenance"], settings["ccar"]["maintenance"]])
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self.kilometers = settings["kilometers_per_year"]
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self.currency = settings["currency"]
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def get_labels(self):
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return self.labels
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def get_purchase(self):
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return self.purchase
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def get_taxes(self):
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return self.taxes
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def get_insurance(self):
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return self.insurance
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def get_driving(self):
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return self.driving
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def get_maintenance(self):
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return self.maintenance
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def get_kilometers(self):
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return self.kilometers
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def get_currency(self):
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return self.currency
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class c_ecar_comparator:
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def __init__(self, fname):
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self.settings_extractor = c_settings_extractor(fname)
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def calculate_costs_a_year(self):
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taxes = self.settings_extractor.get_taxes()
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insurance = self.settings_extractor.get_insurance()
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driving = self.settings_extractor.get_driving()
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maintenance = self.settings_extractor.get_maintenance()
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return taxes + insurance + driving + maintenance
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def calculate_costs(self, years, months):
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months_a_year = 12.0
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costs_a_year = self.calculate_costs_a_year()
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return costs_a_year * (years + months/months_a_year)
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def calculate_break_even(self):
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total_costs = self.settings_extractor.get_purchase()
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months_a_year = 12.0
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increment = self.calculate_costs_a_year() / months_a_year
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months = 0
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while total_costs[0] > total_costs[1]:
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total_costs = total_costs + increment
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months += 1
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kilometers = self.settings_extractor.get_kilometers() * months / months_a_year
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return [months//months_a_year, months%months_a_year, kilometers] # years, months
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def calculate_amortization_point(self):
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y = 0
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m = 1
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months_a_year = 12.0
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# Insurance and taxes need to be payed anyway
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relevant_costs_a_year = self.settings_extractor.get_driving() + self.settings_extractor.get_maintenance()
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savings_a_month = (relevant_costs_a_year[1]-relevant_costs_a_year[0]) / months_a_year
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months_till_amortized = self.settings_extractor.get_purchase()[0] / savings_a_month
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kilometers = months_till_amortized * self.settings_extractor.get_kilometers() / months_a_year
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months_till_amortized = np.ceil(months_till_amortized)
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return months_till_amortized//months_a_year, months_till_amortized%months_a_year, round(kilometers, ndigits=2)
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def main():
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parser = argparse.ArgumentParser(description='This script allows to calculate if an electric car makes sense financially for you.')
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parser.add_argument('-a','--settings', help='Settings file.', required=True, metavar=('FILENAME'))
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parser.add_argument('-b','--break_even', help='Calculate the break even point (when the EV becomes cheaper).', action='store_true')
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parser.add_argument('-c','--amortization', help='Calculate the point in time when the electric vehicle is amortized completely by savings.', action='store_true')
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parser.add_argument('-d','--savings_per_month', help='Calculate savings per month.', action='store_true')
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parser.add_argument('-e','--savings_per_year', help='Calculate savings per year.', action='store_true')
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parser.add_argument('-f','--savings_per_kilometer', help='Calculate savings per 100 kilometers (only driving, no maintenance, taxes or insurance).', action='store_true')
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parser.add_argument('-g','--plot', help='Visualize costs over one or multiple years.', type=int, metavar=('YEARS'))
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args = parser.parse_args()
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if not args.break_even and not args.savings_per_year and not args.savings_per_month and not args.plot:
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sys.exit("Please choose one or multiple options")
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comparator = c_ecar_comparator(args.settings)
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extractor = c_settings_extractor(args.settings)
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be_years = None
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be_months = None
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be_kilometers = None
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if args.break_even:
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be_years, be_months, be_kilometers = comparator.calculate_break_even()
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print("Break even after {} years and {} months.".format(be_years, be_months))
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if args.savings_per_month:
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years = 0
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months = 1
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savings = comparator.calculate_costs(years, months)
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print("Savings per month based on yearly spending: {}.".format(round(savings[1]-savings[0], ndigits=2)))
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if args.savings_per_year:
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years = 1
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months = 0
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savings = comparator.calculate_costs(years, months)
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print("Savings per year: {}.".format(round(savings[1]-savings[0], ndigits=2)))
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if args.savings_per_kilometer:
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hundred_km = 100.0
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driving = hundred_km * extractor.get_driving() / extractor.get_kilometers()
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labels = extractor.get_labels()
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print("Costs driving 100 km in the {}: {}. Costs driving 100 km in the {}: {}.".format(labels[0], round(driving[0], ndigits=2), labels[1], round(driving[1]), ndigits=2))
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am_years = None
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am_months = None
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am_kilometers = None
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if args.amortization:
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am_years, am_months, am_kilometers = comparator.calculate_amortization_point()
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print("The electric vehicle will be amortized by savings after {} years, {} months or exactely at {} kilometres.".format(am_years, am_months, am_kilometers))
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if args.plot != None:
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width = 0.3
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plt_colors = ["#8ecae6", "#219ebc", "#023047", "#ffb703", "#fb8500"];
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color_ind = 0
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labels = extractor.get_labels()
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purchase = extractor.get_purchase()
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taxes = extractor.get_taxes()
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insurance = extractor.get_insurance()
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driving = extractor.get_driving()
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maintenance = extractor.get_maintenance()
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fig, ax = plt.subplots()
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ax.bar(labels, purchase, width, label = "Price", color = plt_colors[0])
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current_y = extractor.get_purchase()
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y = 0
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for i in range(args.plot):
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ax.bar(labels, taxes, width, bottom = current_y, label = "Taxes".format(y), color = plt_colors[1])
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current_y = current_y + taxes
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ax.bar(labels, insurance, width, bottom = current_y, label = "Insurance".format(y), color = plt_colors[2])
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current_y = current_y + insurance
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ax.bar(labels, driving, width, bottom = current_y, label = "Driving".format(y), color = plt_colors[3])
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current_y = current_y + driving
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ax.bar(labels, maintenance, width, bottom = current_y, label = "Maintenance".format(y), color = plt_colors[4])
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current_y = current_y + maintenance
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y += 1
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labels = ["Purchase", "Taxes", "Insurance", "Driving", "Maintenance"]
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lnspace_start = -0.2
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lnspace_stop = 1.2
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lnspace_n = 10
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x_text = 0.2
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if args.break_even:
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months_a_year = 12.0
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be_money = (be_years + be_months/months_a_year) * comparator.calculate_costs_a_year()
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be_money = be_money[1] + extractor.get_purchase()
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ax.plot(np.linspace(lnspace_start, lnspace_stop, lnspace_n), [be_money[1]]*lnspace_n, "--", color = plt_colors[2], label = "Break even")
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ax.text(x_text, be_money[1] + 100, "Break even: {} years, {} months, {} kilometers".format(be_years, be_months, be_kilometers))
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labels = ["Break even"] + labels
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if args.amortization:
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months_a_year = 12.0
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am_money = (am_years + am_months/months_a_year) * comparator.calculate_costs_a_year()
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am_money = am_money[1] + extractor.get_purchase()
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ax.plot(np.linspace(lnspace_start, lnspace_stop, lnspace_n), [am_money[1]]*lnspace_n, "--", color = plt_colors[2], label = "Amortization")
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ax.text(x_text, am_money[1] + 100, "Amortization: {} years, {} months, {} kilometers".format(am_years, am_months, am_kilometers))
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labels = ["Amortization"] + labels
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ax.set_ylabel(extractor.get_currency())
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ax.set_title("Comparision of economics: Electric vs. combustion car")
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ax.legend(labels)
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ax.grid(axis = "y")
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plt.show()
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if __name__ == "__main__":
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main()
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