Tom Brown
GitHub
commit
21c4fd4761
@ -17,3 +17,10 @@ IRENA existing VRE capacities,existing_infrastructure/{solar|onwind|offwind}_cap
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USGS ammonia production,myb1-2017-nitro.xls,unknown,https://www.usgs.gov/centers/nmic/nitrogen-statistics-and-information
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hydrogen salt cavern potentials,hydrogen_salt_cavern_potentials.csv,CC BY 4.0,https://doi.org/10.1016/j.ijhydene.2019.12.161
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hotmaps industrial site database,Industrial_Database.csv,CC BY 4.0,https://gitlab.com/hotmaps/industrial_sites/industrial_sites_Industrial_Database
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Hotmaps building stock data,data_building_stock.csv,CC BY 4.0,https://gitlab.com/hotmaps/building-stock
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U-values Poland,u_values_poland.csv,unknown,https://data.europa.eu/euodp/de/data/dataset/building-stock-observatory
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Floor area missing in hotmaps building stock data,floor_area_missing.csv,unknown,https://data.europa.eu/euodp/de/data/dataset/building-stock-observatory
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Comparative level investment,comparative_level_investment.csv,Eurostat,https://ec.europa.eu/eurostat/statistics-explained/index.php?title=Comparative_price_levels_for_investment
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Electricity taxes,electricity_taxes_eu.csv,Eurostat,https://appsso.eurostat.ec.europa.eu/nui/show.do?dataset=nrg_pc_204&lang=en
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Average surface components,average_surface_components.csv,unknown,http://webtool.building-typology.eu/#bm
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Retrofitting thermal envelope costs for Germany,retro_cost_germany.csv,unkown,https://www.iwu.de/forschung/handlungslogiken/kosten-energierelevanter-bau-und-anlagenteile-bei-modernisierung/
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@ -23,7 +23,6 @@ Structure:
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import pandas as pd
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import matplotlib.pyplot as plt
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pd.options.mode.chained_assignment = None
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#%% ************ FUCNTIONS ***************************************************
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@ -175,9 +174,9 @@ def prepare_building_stock_data():
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area = building_data[(building_data.type == 'Heated area [Mm²]') &
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(building_data.subsector != "Total")]
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area_tot = area.groupby(["country", "sector"]).sum()
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area["weight"] = area.apply(lambda x: x.value /
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area = pd.concat([area, area.apply(lambda x: x.value /
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area_tot.value.loc[(x.country, x.sector)],
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axis=1)
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axis=1).rename("weight")],axis=1)
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area = area.groupby(['country', 'sector', 'subsector', 'bage']).sum()
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area_tot.rename(index=country_iso_dic, inplace=True)
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@ -192,9 +191,9 @@ def prepare_building_stock_data():
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pop_layout["ct"] = pop_layout.index.str[:2]
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ct_total = pop_layout.total.groupby(pop_layout["ct"]).sum()
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area_per_pop = area_tot.unstack().apply(lambda x: x / ct_total[x.index])
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area_per_pop = area_tot.unstack().reindex(index=ct_total.index).apply(lambda x: x / ct_total[x.index])
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missing_area_ct = ct_total.index.difference(area_tot.index.levels[0])
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for ct in missing_area_ct:
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for ct in (missing_area_ct & ct_total.index):
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averaged_data = pd.DataFrame(
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area_per_pop.value.reindex(map_for_missings[ct]).mean()
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* ct_total[ct],
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@ -233,7 +232,7 @@ def prepare_building_stock_data():
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# smallest possible today u values for windows 0.8 (passive house standard)
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# maybe the u values for the glass and not the whole window including frame
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# for those types assumed in the dataset
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u_values[(u_values.type=="Windows") & (u_values.value<0.8)]["value"] = 0.8
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u_values.loc[(u_values.type=="Windows") & (u_values.value<0.8), "value"] = 0.8
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# drop unnecessary columns
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u_values.drop(['topic', 'feature','detail', 'estimated','unit'],
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axis=1, inplace=True, errors="ignore")
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@ -314,8 +313,12 @@ def calculate_cost_energy_curve(u_values, l_strength, l_weight, average_surface_
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for l in l_strength:
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u_values[l] = calculate_new_u(u_values, l, l_weight)
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energy_saved[l] = calculate_dE(u_values, l, average_surface_w)
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costs[l] = calculate_costs(u_values, l, cost_retro, average_surface)
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energy_saved = pd.concat([energy_saved,
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calculate_dE(u_values, l, average_surface_w).rename(l)],
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axis=1)
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costs = pd.concat([costs,
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calculate_costs(u_values, l, cost_retro, average_surface).rename(l)],
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axis=1)
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# energy and costs per country, sector, subsector and year
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e_tot = energy_saved.groupby(['country', 'sector', 'subsector', 'bage']).sum()
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@ -334,11 +337,13 @@ def calculate_cost_energy_curve(u_values, l_strength, l_weight, average_surface_
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axis=1, keys=["dE", "cost"])
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res.rename(index=country_iso_dic, inplace=True)
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res = res.loc[countries]
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res = res.reindex(index=countries, level=0)
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# reset index because otherwise not considered countries still in index.levels[0]
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res = res.reset_index().set_index(["country", "sector"])
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# map missing countries
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for ct in map_for_missings.keys():
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averaged_data = pd.DataFrame(res.loc[map_for_missings[ct], :].mean(level=1))
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for ct in pd.Index(map_for_missings.keys()) & countries:
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averaged_data = res.reindex(index=map_for_missings[ct], level=0).mean(level=1)
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index = pd.MultiIndex.from_product([[ct], averaged_data.index.to_list()])
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averaged_data.index = index
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if ct not in res.index.levels[0]:
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@ -436,12 +441,14 @@ if __name__ == "__main__":
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# for missing weighting of surfaces of building types assume MultiFamily houses
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u_values["assumed_subsector"] = u_values.subsector
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u_values.assumed_subsector[
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~u_values.subsector.isin(average_surface.index)] = 'Multifamily houses'
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u_values.loc[~u_values.subsector.isin(average_surface.index),
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"assumed_subsector"] = 'Multifamily houses'
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dE_and_cost = calculate_cost_energy_curve(u_values, l_strength, l_weight,
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average_surface_w, average_surface, area,
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country_iso_dic, countries)
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# reset index because otherwise not considered countries still in index.levels[0]
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dE_and_cost = dE_and_cost.reset_index().set_index(["country", "sector"])
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# weights costs after construction index
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if construction_index:
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@ -1820,52 +1820,52 @@ def get_parameter(item):
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return item
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#%%
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if __name__ == "__main__":
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# Detect running outside of snakemake and mock snakemake for testing
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if 'snakemake' not in globals():
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from vresutils.snakemake import MockSnakemake
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snakemake = MockSnakemake(
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wildcards=dict(network='elec', simpl='', clusters='37', lv='1.0',
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opts='', planning_horizons='2020',
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sector_opts='Co2L0-168H-T-H-B-I-solar3-dist1'),
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input=dict(network='../pypsa-eur/networks/{network}_s{simpl}_{clusters}_ec_lv{lv}_{opts}.nc',
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energy_totals_name='resources/energy_totals.csv',
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co2_totals_name='resources/co2_totals.csv',
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transport_name='resources/transport_data.csv',
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biomass_potentials='resources/biomass_potentials.csv',
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biomass_transport='data/biomass/biomass_transport_costs.csv',
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timezone_mappings='data/timezone_mappings.csv',
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heat_profile="data/heat_load_profile_BDEW.csv",
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costs="../technology-data/outputs/costs_{planning_horizons}.csv",
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h2_cavern = "data/hydrogen_salt_cavern_potentials.csv",
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profile_offwind_ac="../pypsa-eur/resources/profile_offwind-ac.nc",
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profile_offwind_dc="../pypsa-eur/resources/profile_offwind-dc.nc",
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clustermaps='../pypsa-eur/resources/clustermaps_{network}_s{simpl}_{clusters}.h5',
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clustered_pop_layout="resources/pop_layout_{network}_s{simpl}_{clusters}.csv",
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simplified_pop_layout="resources/pop_layout_{network}_s{simpl}.csv",
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industrial_demand="resources/industrial_energy_demand_{network}_s{simpl}_{clusters}.csv",
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heat_demand_urban="resources/heat_demand_urban_{network}_s{simpl}_{clusters}.nc",
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heat_demand_rural="resources/heat_demand_rural_{network}_s{simpl}_{clusters}.nc",
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heat_demand_total="resources/heat_demand_total_{network}_s{simpl}_{clusters}.nc",
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temp_soil_total="resources/temp_soil_total_{network}_s{simpl}_{clusters}.nc",
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temp_soil_rural="resources/temp_soil_rural_{network}_s{simpl}_{clusters}.nc",
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temp_soil_urban="resources/temp_soil_urban_{network}_s{simpl}_{clusters}.nc",
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temp_air_total="resources/temp_air_total_{network}_s{simpl}_{clusters}.nc",
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temp_air_rural="resources/temp_air_rural_{network}_s{simpl}_{clusters}.nc",
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temp_air_urban="resources/temp_air_urban_{network}_s{simpl}_{clusters}.nc",
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cop_soil_total="resources/cop_soil_total_{network}_s{simpl}_{clusters}.nc",
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cop_soil_rural="resources/cop_soil_rural_{network}_s{simpl}_{clusters}.nc",
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cop_soil_urban="resources/cop_soil_urban_{network}_s{simpl}_{clusters}.nc",
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cop_air_total="resources/cop_air_total_{network}_s{simpl}_{clusters}.nc",
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cop_air_rural="resources/cop_air_rural_{network}_s{simpl}_{clusters}.nc",
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cop_air_urban="resources/cop_air_urban_{network}_s{simpl}_{clusters}.nc",
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solar_thermal_total="resources/solar_thermal_total_{network}_s{simpl}_{clusters}.nc",
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solar_thermal_urban="resources/solar_thermal_urban_{network}_s{simpl}_{clusters}.nc",
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traffic_data = "data/emobility/",
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solar_thermal_rural="resources/solar_thermal_rural_{network}_s{simpl}_{clusters}.nc",
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retro_cost_energy = "resources/retro_cost_{network}_s{simpl}_{clusters}.csv",
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floor_area = "resources/floor_area_{network}_s{simpl}_{clusters}.csv"
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opts='', planning_horizons='2030', co2_budget_name="go",
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sector_opts='Co2L0-120H-T-H-B-I-solar3-dist1'),
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input=dict( network='../pypsa-eur/networks/{network}_s{simpl}_{clusters}_ec_lv{lv}_{opts}.nc',
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energy_totals_name='resources/energy_totals.csv',
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co2_totals_name='resources/co2_totals.csv',
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transport_name='resources/transport_data.csv',
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traffic_data = "data/emobility/",
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biomass_potentials='resources/biomass_potentials.csv',
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timezone_mappings='data/timezone_mappings.csv',
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heat_profile="data/heat_load_profile_BDEW.csv",
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costs="../technology-data/outputs/costs_{planning_horizons}.csv",
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h2_cavern = "data/hydrogen_salt_cavern_potentials.csv",
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profile_offwind_ac="../pypsa-eur/resources/profile_offwind-ac.nc",
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profile_offwind_dc="../pypsa-eur/resources/profile_offwind-dc.nc",
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busmap_s="../pypsa-eur/resources/busmap_{network}_s{simpl}.csv",
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busmap="../pypsa-eur/resources/busmap_{network}_s{simpl}_{clusters}.csv",
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clustered_pop_layout="resources/pop_layout_{network}_s{simpl}_{clusters}.csv",
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simplified_pop_layout="resources/pop_layout_{network}_s{simpl}.csv",
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industrial_demand="resources/industrial_energy_demand_{network}_s{simpl}_{clusters}.csv",
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heat_demand_urban="resources/heat_demand_urban_{network}_s{simpl}_{clusters}.nc",
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heat_demand_rural="resources/heat_demand_rural_{network}_s{simpl}_{clusters}.nc",
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heat_demand_total="resources/heat_demand_total_{network}_s{simpl}_{clusters}.nc",
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temp_soil_total="resources/temp_soil_total_{network}_s{simpl}_{clusters}.nc",
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temp_soil_rural="resources/temp_soil_rural_{network}_s{simpl}_{clusters}.nc",
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temp_soil_urban="resources/temp_soil_urban_{network}_s{simpl}_{clusters}.nc",
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temp_air_total="resources/temp_air_total_{network}_s{simpl}_{clusters}.nc",
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temp_air_rural="resources/temp_air_rural_{network}_s{simpl}_{clusters}.nc",
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temp_air_urban="resources/temp_air_urban_{network}_s{simpl}_{clusters}.nc",
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cop_soil_total="resources/cop_soil_total_{network}_s{simpl}_{clusters}.nc",
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cop_soil_rural="resources/cop_soil_rural_{network}_s{simpl}_{clusters}.nc",
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cop_soil_urban="resources/cop_soil_urban_{network}_s{simpl}_{clusters}.nc",
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cop_air_total="resources/cop_air_total_{network}_s{simpl}_{clusters}.nc",
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cop_air_rural="resources/cop_air_rural_{network}_s{simpl}_{clusters}.nc",
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cop_air_urban="resources/cop_air_urban_{network}_s{simpl}_{clusters}.nc",
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solar_thermal_total="resources/solar_thermal_total_{network}_s{simpl}_{clusters}.nc",
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solar_thermal_urban="resources/solar_thermal_urban_{network}_s{simpl}_{clusters}.nc",
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solar_thermal_rural="resources/solar_thermal_rural_{network}_s{simpl}_{clusters}.nc",
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retro_cost_energy = "resources/retro_cost_{network}_s{simpl}_{clusters}.csv",
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floor_area = "resources/floor_area_{network}_s{simpl}_{clusters}.csv"
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),
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output=['pypsa-eur-sec/results/test/prenetworks/{network}_s{simpl}_{clusters}_lv{lv}__{sector_opts}_{co2_budget_name}_{planning_horizons}.nc']
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)
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