# SPDX-FileCopyrightText: : 2017-2024 The PyPSA-Eur Authors # # SPDX-License-Identifier: CC0-1.0 # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#top-level-configuration version: 0.11.0 tutorial: false logging: level: INFO format: '%(levelname)s:%(name)s:%(message)s' private: keys: entsoe_api: remote: ssh: "" path: "" # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#run run: prefix: "" name: - dh_temperature_55-30 - dh_temperature_90-50 scenarios: enable: true file: config/scenarios.yaml disable_progressbar: false shared_resources: policy: base exclude: [] shared_cutouts: true # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#foresight foresight: overnight # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#scenario # Wildcard docs in https://pypsa-eur.readthedocs.io/en/latest/wildcards.html scenario: simpl: - '' ll: - vopt clusters: - 2 opts: - '' sector_opts: - '' planning_horizons: - 2050 # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#countries countries: ['DE'] # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#snapshots snapshots: start: "2013-01-01" end: "2014-01-01" inclusive: 'left' # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#enable enable: retrieve: auto prepare_links_p_nom: false retrieve_databundle: true retrieve_cost_data: true build_cutout: false retrieve_cutout: true custom_busmap: false drop_leap_day: true # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#co2-budget co2_budget: 2020: 0.701 2025: 0.524 2030: 0.297 2035: 0.150 2040: 0.071 2045: 0.032 2050: 0.000 # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#electricity electricity: voltages: [220., 300., 380., 500., 750.] gaslimit_enable: false gaslimit: false co2limit_enable: false co2limit: 7.75e+7 co2base: 1.487e+9 operational_reserve: activate: false epsilon_load: 0.02 epsilon_vres: 0.02 contingency: 4000 max_hours: battery: 6 H2: 168 extendable_carriers: Generator: [solar, solar-hsat, onwind, offwind-ac, offwind-dc, offwind-float, OCGT, CCGT] StorageUnit: [] # battery, H2 Store: [battery, H2] Link: [] # H2 pipeline powerplants_filter: (DateOut >= 2023 or DateOut != DateOut) and not (Country == 'Germany' and Fueltype == 'Nuclear') custom_powerplants: false everywhere_powerplants: [] conventional_carriers: [nuclear, oil, OCGT, CCGT, coal, lignite, geothermal, biomass] renewable_carriers: [solar, solar-hsat, onwind, offwind-ac, offwind-dc, offwind-float, hydro] estimate_renewable_capacities: enable: true from_opsd: true year: 2020 expansion_limit: false technology_mapping: Offshore: [offwind-ac, offwind-dc, offwind-float] Onshore: [onwind] PV: [solar] autarky: enable: false by_country: false # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#atlite atlite: default_cutout: europe-2013-era5 nprocesses: 4 show_progress: false cutouts: # use 'base' to determine geographical bounds and time span from config # base: # module: era5 europe-2013-era5: module: era5 # in priority order x: [-12., 42.] y: [33., 72] dx: 0.3 dy: 0.3 time: ['2013', '2013'] europe-2013-sarah: module: [sarah, era5] # in priority order x: [-12., 42.] y: [33., 65] dx: 0.2 dy: 0.2 time: ['2013', '2013'] sarah_interpolate: false sarah_dir: features: [influx, temperature] # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#renewable renewable: onwind: cutout: europe-2013-era5 resource: method: wind turbine: Vestas_V112_3MW add_cutout_windspeed: true capacity_per_sqkm: 3 # correction_factor: 0.93 corine: grid_codes: [12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 31, 32] distance: 1000 distance_grid_codes: [1, 2, 3, 4, 5, 6] luisa: false # grid_codes: [1111, 1121, 1122, 1123, 1130, 1210, 1221, 1222, 1230, 1241, 1242] # distance: 1000 # distance_grid_codes: [1111, 1121, 1122, 1123, 1130, 1210, 1221, 1222, 1230, 1241, 1242] natura: true excluder_resolution: 100 clip_p_max_pu: 1.e-2 offwind-ac: cutout: europe-2013-era5 resource: method: wind turbine: NREL_ReferenceTurbine_2020ATB_5.5MW add_cutout_windspeed: true capacity_per_sqkm: 2 correction_factor: 0.8855 corine: [44, 255] luisa: false # [0, 5230] natura: true ship_threshold: 400 max_depth: 60 max_shore_distance: 30000 excluder_resolution: 200 clip_p_max_pu: 1.e-2 offwind-dc: cutout: europe-2013-era5 resource: method: wind turbine: NREL_ReferenceTurbine_2020ATB_5.5MW add_cutout_windspeed: true capacity_per_sqkm: 2 correction_factor: 0.8855 corine: [44, 255] luisa: false # [0, 5230] natura: true ship_threshold: 400 max_depth: 60 min_shore_distance: 30000 excluder_resolution: 200 clip_p_max_pu: 1.e-2 offwind-float: cutout: europe-2013-era5 resource: method: wind turbine: NREL_ReferenceTurbine_5MW_offshore # ScholzPhd Tab 4.3.1: 10MW/km^2 capacity_per_sqkm: 2 correction_factor: 0.8855 # proxy for wake losses # from 10.1016/j.energy.2018.08.153 # until done more rigorously in #153 corine: [44, 255] natura: true ship_threshold: 400 excluder_resolution: 200 min_depth: 60 max_depth: 1000 clip_p_max_pu: 1.e-2 solar: cutout: europe-2013-sarah resource: method: pv panel: CSi orientation: slope: 35. azimuth: 180. capacity_per_sqkm: 5.1 # correction_factor: 0.854337 corine: [1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 26, 31, 32] luisa: false # [1111, 1121, 1122, 1123, 1130, 1210, 1221, 1222, 1230, 1241, 1242, 1310, 1320, 1330, 1410, 1421, 1422, 2110, 2120, 2130, 2210, 2220, 2230, 2310, 2410, 2420, 3210, 3320, 3330] natura: true excluder_resolution: 100 clip_p_max_pu: 1.e-2 solar-hsat: cutout: europe-2013-sarah resource: method: pv panel: CSi orientation: slope: 35. azimuth: 180. tracking: horizontal capacity_per_sqkm: 4.43 # 15% higher land usage acc. to NREL corine: [1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 26, 31, 32] luisa: false # [1111, 1121, 1122, 1123, 1130, 1210, 1221, 1222, 1230, 1241, 1242, 1310, 1320, 1330, 1410, 1421, 1422, 2110, 2120, 2130, 2210, 2220, 2230, 2310, 2410, 2420, 3210, 3320, 3330] natura: true excluder_resolution: 100 clip_p_max_pu: 1.e-2 hydro: cutout: europe-2013-era5 carriers: [ror, PHS, hydro] PHS_max_hours: 6 hydro_max_hours: "energy_capacity_totals_by_country" # one of energy_capacity_totals_by_country, estimate_by_large_installations or a float flatten_dispatch: false flatten_dispatch_buffer: 0.2 clip_min_inflow: 1.0 eia_norm_year: false eia_correct_by_capacity: false eia_approximate_missing: false # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#conventional conventional: unit_commitment: false dynamic_fuel_price: false nuclear: p_max_pu: "data/nuclear_p_max_pu.csv" # float of file name # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#lines lines: types: 220.: "Al/St 240/40 2-bundle 220.0" 300.: "Al/St 240/40 3-bundle 300.0" 380.: "Al/St 240/40 4-bundle 380.0" 500.: "Al/St 240/40 4-bundle 380.0" 750.: "Al/St 560/50 4-bundle 750.0" s_max_pu: 0.7 s_nom_max: .inf max_extension: 20000 #MW length_factor: 1.25 reconnect_crimea: true under_construction: 'keep' # 'zero': set capacity to zero, 'remove': remove, 'keep': with full capacity dynamic_line_rating: activate: false cutout: europe-2013-era5 correction_factor: 0.95 max_voltage_difference: false max_line_rating: false # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#links links: p_max_pu: 1.0 p_nom_max: .inf max_extension: 30000 #MW include_tyndp: true under_construction: 'zero' # 'zero': set capacity to zero, 'remove': remove, 'keep': with full capacity # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#transformers transformers: x: 0.1 s_nom: 2000. type: '' # docs-load in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#load load: interpolate_limit: 3 time_shift_for_large_gaps: 1w manual_adjustments: true # false scaling_factor: 1.0 fixed_year: false # false or year (e.g. 2013) supplement_synthetic: true # docs # TODO: PyPSA-Eur merge issue in prepare_sector_network.py # regulate what components with which carriers are kept from PyPSA-Eur; # some technologies are removed because they are implemented differently # (e.g. battery or H2 storage) or have different year-dependent costs # in PyPSA-Eur-Sec pypsa_eur: Bus: - AC Link: - DC Generator: - onwind - offwind-ac - offwind-dc - offwind-float - solar-hsat - solar - ror - nuclear StorageUnit: - PHS - hydro Store: [] # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#energy energy: energy_totals_year: 2019 base_emissions_year: 1990 emissions: CO2 # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#biomass biomass: year: 2030 scenario: ENS_Med classes: solid biomass: - Agricultural waste - Fuelwood residues - Secondary Forestry residues - woodchips - Sawdust - Residues from landscape care - Municipal waste not included: - Sugar from sugar beet - Rape seed - "Sunflower, soya seed " - Bioethanol barley, wheat, grain maize, oats, other cereals and rye - Miscanthus, switchgrass, RCG - Willow - Poplar - FuelwoodRW - C&P_RW biogas: - Manure solid, liquid - Sludge # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#solar-thermal solar_thermal: clearsky_model: simple # should be "simple" or "enhanced"? orientation: slope: 45. azimuth: 180. cutout: default # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#existing-capacities existing_capacities: grouping_years_power: [1920, 1950, 1955, 1960, 1965, 1970, 1975, 1980, 1985, 1990, 1995, 2000, 2005, 2010, 2015, 2020, 2025] grouping_years_heat: [1980, 1985, 1990, 1995, 2000, 2005, 2010, 2015, 2019] # heat grouping years >= baseyear will be ignored threshold_capacity: 10 default_heating_lifetime: 20 conventional_carriers: - lignite - coal - oil - uranium # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#sector sector: transport: true heating: true biomass: true industry: true agriculture: true district_heating: potential: 0.6 progress: 2020: 0.0 2025: 0.15 2030: 0.3 2035: 0.45 2040: 0.6 2045: 0.8 2050: 1.0 district_heating_loss: 0.15 # check these numbers! forward_temperature: 90 #C return_temperature: 50 #C heat_source_cooling: 6 #K heat_pump_cop_approximation: refrigerant: ammonia heat_exchanger_pinch_point_temperature_difference: 5 #K isentropic_compressor_efficiency: 0.8 heat_loss: 0.0 cluster_heat_buses: true heat_demand_cutout: default bev_dsm_restriction_value: 0.75 bev_dsm_restriction_time: 7 transport_heating_deadband_upper: 20. transport_heating_deadband_lower: 15. ICE_lower_degree_factor: 0.375 ICE_upper_degree_factor: 1.6 EV_lower_degree_factor: 0.98 EV_upper_degree_factor: 0.63 bev_dsm: true bev_availability: 0.5 bev_energy: 0.05 bev_charge_efficiency: 0.9 bev_charge_rate: 0.011 bev_avail_max: 0.95 bev_avail_mean: 0.8 v2g: true land_transport_fuel_cell_share: 2020: 0 2025: 0 2030: 0 2035: 0 2040: 0 2045: 0 2050: 0 land_transport_electric_share: 2020: 0 2025: 0.15 2030: 0.3 2035: 0.45 2040: 0.7 2045: 0.85 2050: 1 land_transport_ice_share: 2020: 1 2025: 0.85 2030: 0.7 2035: 0.55 2040: 0.3 2045: 0.15 2050: 0 transport_electric_efficiency: 53.19 # 1 MWh_el = 53.19*100 km transport_fuel_cell_efficiency: 30.003 # 1 MWh_H2 = 30.003*100 km transport_ice_efficiency: 16.0712 # 1 MWh_oil = 16.0712 * 100 km agriculture_machinery_electric_share: 0 agriculture_machinery_oil_share: 1 agriculture_machinery_fuel_efficiency: 0.7 agriculture_machinery_electric_efficiency: 0.3 MWh_MeOH_per_MWh_H2: 0.8787 MWh_MeOH_per_tCO2: 4.0321 MWh_MeOH_per_MWh_e: 3.6907 shipping_hydrogen_liquefaction: false shipping_hydrogen_share: 2020: 0 2025: 0 2030: 0 2035: 0 2040: 0 2045: 0 2050: 0 shipping_methanol_share: 2020: 0 2025: 0.15 2030: 0.3 2035: 0.5 2040: 0.7 2045: 0.85 2050: 1 shipping_oil_share: 2020: 1 2025: 0.85 2030: 0.7 2035: 0.5 2040: 0.3 2045: 0.15 2050: 0 shipping_methanol_efficiency: 0.46 shipping_oil_efficiency: 0.40 aviation_demand_factor: 1. HVC_demand_factor: 1. time_dep_hp_cop: true heat_pump_sink_T_individual_heating: 55. reduce_space_heat_exogenously: true reduce_space_heat_exogenously_factor: 2020: 0.10 # this results in a space heat demand reduction of 10% 2025: 0.09 # first heat demand increases compared to 2020 because of larger floor area per capita 2030: 0.09 2035: 0.11 2040: 0.16 2045: 0.21 2050: 0.29 retrofitting: retro_endogen: false cost_factor: 1.0 interest_rate: 0.04 annualise_cost: true tax_weighting: false construction_index: true tes: true tes_tau: decentral: 3 central: 180 boilers: true resistive_heaters: true oil_boilers: false biomass_boiler: true overdimension_individual_heating: 1.1 #to cover demand peaks bigger than data chp: true micro_chp: false solar_thermal: true solar_cf_correction: 0.788457 # = >>> 1/1.2683 marginal_cost_storage: 0. #1e-4 methanation: true coal_cc: false dac: true co2_vent: false central_heat_vent: false allam_cycle: false hydrogen_fuel_cell: true hydrogen_turbine: false SMR: true SMR_cc: true regional_methanol_demand: false regional_oil_demand: false regional_coal_demand: false regional_co2_sequestration_potential: enable: false attribute: - conservative estimate Mt - conservative estimate GAS Mt - conservative estimate OIL Mt - conservative estimate aquifer Mt include_onshore: false min_size: 3 max_size: 25 years_of_storage: 25 co2_sequestration_potential: 200 co2_sequestration_cost: 10 co2_sequestration_lifetime: 50 co2_spatial: false co2network: false co2_network_cost_factor: 1 cc_fraction: 0.9 hydrogen_underground_storage: true hydrogen_underground_storage_locations: # - onshore # more than 50 km from sea - nearshore # within 50 km of sea # - offshore ammonia: false min_part_load_fischer_tropsch: 0.5 min_part_load_methanolisation: 0.3 min_part_load_methanation: 0.3 use_fischer_tropsch_waste_heat: 0.25 use_haber_bosch_waste_heat: 0.25 use_methanolisation_waste_heat: 0.25 use_methanation_waste_heat: 0.25 use_fuel_cell_waste_heat: 0.25 use_electrolysis_waste_heat: 0.25 electricity_transmission_grid: true electricity_distribution_grid: true electricity_distribution_grid_cost_factor: 1.0 electricity_grid_connection: true transmission_efficiency: DC: efficiency_static: 0.98 efficiency_per_1000km: 0.977 H2 pipeline: efficiency_per_1000km: 1 # 0.982 compression_per_1000km: 0.018 gas pipeline: efficiency_per_1000km: 1 #0.977 compression_per_1000km: 0.01 electricity distribution grid: efficiency_static: 0.97 H2_network: true gas_network: false H2_retrofit: false H2_retrofit_capacity_per_CH4: 0.6 gas_network_connectivity_upgrade: 1 gas_distribution_grid: true gas_distribution_grid_cost_factor: 1.0 biomass_spatial: false biomass_transport: false biogas_upgrading_cc: false conventional_generation: OCGT: gas biomass_to_liquid: false biosng: false limit_max_growth: enable: false # allowing 30% larger than max historic growth factor: 1.3 max_growth: # unit GW onwind: 16 # onshore max grow so far 16 GW in Europe https://www.iea.org/reports/renewables-2020/wind solar: 28 # solar max grow so far 28 GW in Europe https://www.iea.org/reports/renewables-2020/solar-pv offwind-ac: 35 # offshore max grow so far 3.5 GW in Europe https://windeurope.org/about-wind/statistics/offshore/european-offshore-wind-industry-key-trends-statistics-2019/ offwind-dc: 35 max_relative_growth: onwind: 3 solar: 3 offwind-ac: 3 offwind-dc: 3 enhanced_geothermal: enable: false flexible: true max_hours: 240 max_boost: 0.25 var_cf: true sustainability_factor: 0.0025 # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#industry industry: St_primary_fraction: 2020: 0.6 2025: 0.55 2030: 0.5 2035: 0.45 2040: 0.4 2045: 0.35 2050: 0.3 DRI_fraction: 2020: 0 2025: 0 2030: 0.05 2035: 0.2 2040: 0.4 2045: 0.7 2050: 1 H2_DRI: 1.7 elec_DRI: 0.322 Al_primary_fraction: 2020: 0.4 2025: 0.375 2030: 0.35 2035: 0.325 2040: 0.3 2045: 0.25 2050: 0.2 MWh_NH3_per_tNH3: 5.166 MWh_CH4_per_tNH3_SMR: 10.8 MWh_elec_per_tNH3_SMR: 0.7 MWh_H2_per_tNH3_electrolysis: 5.93 MWh_elec_per_tNH3_electrolysis: 0.2473 MWh_NH3_per_MWh_H2_cracker: 1.46 # https://github.com/euronion/trace/blob/44a5ff8401762edbef80eff9cfe5a47c8d3c8be4/data/efficiencies.csv NH3_process_emissions: 24.5 petrochemical_process_emissions: 25.5 #HVC primary/recycling based on values used in Neumann et al https://doi.org/10.1016/j.joule.2023.06.016, linearly interpolated between 2020 and 2050 #2020 recycling rates based on Agora https://static.agora-energiewende.de/fileadmin/Projekte/2021/2021_02_EU_CEAP/A-EW_254_Mobilising-circular-economy_study_WEB.pdf #fractions refer to the total primary HVC production in 2020 #assumes 6.7 Mtplastics produced from recycling in 2020 HVC_primary_fraction: 2020: 1.0 2025: 0.9 2030: 0.8 2035: 0.7 2040: 0.6 2045: 0.5 2050: 0.4 HVC_mechanical_recycling_fraction: 2020: 0.12 2025: 0.15 2030: 0.18 2035: 0.21 2040: 0.24 2045: 0.27 2050: 0.30 HVC_chemical_recycling_fraction: 2020: 0.0 2025: 0.0 2030: 0.04 2035: 0.08 2040: 0.12 2045: 0.16 2050: 0.20 HVC_environment_sequestration_fraction: 0. waste_to_energy: false waste_to_energy_cc: false sector_ratios_fraction_future: 2020: 0.0 2025: 0.1 2030: 0.3 2035: 0.5 2040: 0.7 2045: 0.9 2050: 1.0 basic_chemicals_without_NH3_production_today: 69. #Mt/a, = 86 Mtethylene-equiv - 17 MtNH3 HVC_production_today: 52. MWh_elec_per_tHVC_mechanical_recycling: 0.547 MWh_elec_per_tHVC_chemical_recycling: 6.9 chlorine_production_today: 9.58 MWh_elec_per_tCl: 3.6 MWh_H2_per_tCl: -0.9372 methanol_production_today: 1.5 MWh_elec_per_tMeOH: 0.167 MWh_CH4_per_tMeOH: 10.25 MWh_MeOH_per_tMeOH: 5.528 hotmaps_locate_missing: false reference_year: 2015 # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#costs costs: year: 2030 version: v0.9.0 social_discountrate: 0.02 fill_values: FOM: 0 VOM: 0 efficiency: 1 fuel: 0 investment: 0 lifetime: 25 "CO2 intensity": 0 "discount rate": 0.07 # Marginal and capital costs can be overwritten # capital_cost: # onwind: 500 marginal_cost: solar: 0.01 onwind: 0.015 offwind: 0.015 hydro: 0. H2: 0. electrolysis: 0. fuel cell: 0. battery: 0. battery inverter: 0. emission_prices: enable: false co2: 0. co2_monthly_prices: false # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#clustering clustering: focus_weights: false simplify_network: to_substations: false algorithm: kmeans # choose from: [hac, kmeans] feature: solar+onwind-time exclude_carriers: [] remove_stubs: true remove_stubs_across_borders: true cluster_network: algorithm: kmeans feature: solar+onwind-time exclude_carriers: [] consider_efficiency_classes: false aggregation_strategies: generators: committable: any ramp_limit_up: max ramp_limit_down: max temporal: resolution_elec: false resolution_sector: false # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#adjustments adjustments: electricity: false sector: false # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#solving solving: #tmpdir: "path/to/tmp" options: clip_p_max_pu: 1.e-2 load_shedding: false noisy_costs: true skip_iterations: true rolling_horizon: false seed: 123 custom_extra_functionality: "../data/custom_extra_functionality.py" # io_api: "direct" # Increases performance but only supported for the highs and gurobi solvers # options that go into the optimize function track_iterations: false min_iterations: 2 max_iterations: 3 transmission_losses: 2 linearized_unit_commitment: true horizon: 365 post_discretization: enable: false line_unit_size: 1700 line_threshold: 0.3 link_unit_size: DC: 2000 H2 pipeline: 1200 gas pipeline: 1500 link_threshold: DC: 0.3 H2 pipeline: 0.3 gas pipeline: 0.3 agg_p_nom_limits: agg_offwind: false include_existing: false file: data/agg_p_nom_minmax.csv constraints: CCL: false EQ: false BAU: false SAFE: false solver: name: gurobi options: gurobi-default solver_options: highs-default: # refer to https://ergo-code.github.io/HiGHS/dev/options/definitions/ threads: 4 solver: "ipm" run_crossover: "off" small_matrix_value: 1e-6 large_matrix_value: 1e9 primal_feasibility_tolerance: 1e-5 dual_feasibility_tolerance: 1e-5 ipm_optimality_tolerance: 1e-4 parallel: "on" random_seed: 123 gurobi-default: threads: 4 method: 2 # barrier crossover: 0 BarConvTol: 1.e-6 Seed: 123 AggFill: 0 PreDual: 0 GURO_PAR_BARDENSETHRESH: 200 gurobi-numeric-focus: NumericFocus: 3 # Favour numeric stability over speed method: 2 # barrier crossover: 0 # do not use crossover BarHomogeneous: 1 # Use homogeneous barrier if standard does not converge BarConvTol: 1.e-5 FeasibilityTol: 1.e-4 OptimalityTol: 1.e-4 ObjScale: -0.5 threads: 8 Seed: 123 gurobi-fallback: # Use gurobi defaults crossover: 0 method: 2 # barrier BarHomogeneous: 1 # Use homogeneous barrier if standard does not converge BarConvTol: 1.e-5 FeasibilityTol: 1.e-5 OptimalityTol: 1.e-5 Seed: 123 threads: 8 cplex-default: threads: 4 lpmethod: 4 # barrier solutiontype: 2 # non basic solution, ie no crossover barrier.convergetol: 1.e-5 feasopt.tolerance: 1.e-6 copt-default: Threads: 8 LpMethod: 2 Crossover: 0 RelGap: 1.e-6 Dualize: 0 copt-gpu: LpMethod: 6 GPUMode: 1 PDLPTol: 1.e-5 Crossover: 0 cbc-default: {} # Used in CI glpk-default: {} # Used in CI mem_mb: 30000 #memory in MB; 20 GB enough for 50+B+I+H2; 100 GB for 181+B+I+H2 runtime: 6h #runtime in humanfriendly style https://humanfriendly.readthedocs.io/en/latest/ # docs in https://pypsa-eur.readthedocs.io/en/latest/configuration.html#plotting plotting: map: boundaries: [-11, 30, 34, 71] color_geomap: ocean: white land: white projection: name: "EqualEarth" # See https://scitools.org.uk/cartopy/docs/latest/reference/projections.html for alternatives, for example: # name: "LambertConformal" # central_longitude: 10. # central_latitude: 50. # standard_parallels: [35, 65] eu_node_location: x: -5.5 y: 46. costs_max: 1000 costs_threshold: 1 energy_max: 20000 energy_min: -20000 energy_threshold: 50. nice_names: OCGT: "Open-Cycle Gas" CCGT: "Combined-Cycle Gas" offwind-ac: "Offshore Wind (AC)" offwind-dc: "Offshore Wind (DC)" offwind-float: "Offshore Wind (Floating)" onwind: "Onshore Wind" solar: "Solar" PHS: "Pumped Hydro Storage" hydro: "Reservoir & Dam" battery: "Battery Storage" H2: "Hydrogen Storage" lines: "Transmission Lines" ror: "Run of River" load: "Load Shedding" ac: "AC" dc: "DC" tech_colors: # wind onwind: "#235ebc" onshore wind: "#235ebc" offwind: "#6895dd" offshore wind: "#6895dd" offwind-ac: "#6895dd" offshore wind (AC): "#6895dd" offshore wind ac: "#6895dd" offwind-dc: "#74c6f2" offshore wind (DC): "#74c6f2" offshore wind dc: "#74c6f2" offwind-float: "#b5e2fa" offshore wind (Float): "#b5e2fa" offshore wind float: "#b5e2fa" # water hydro: '#298c81' hydro reservoir: '#298c81' ror: '#3dbfb0' run of river: '#3dbfb0' hydroelectricity: '#298c81' PHS: '#51dbcc' hydro+PHS: "#08ad97" # solar solar: "#f9d002" solar PV: "#f9d002" solar-hsat: "#fdb915" solar thermal: '#ffbf2b' residential rural solar thermal: '#f1c069' services rural solar thermal: '#eabf61' residential urban decentral solar thermal: '#e5bc5a' services urban decentral solar thermal: '#dfb953' urban central solar thermal: '#d7b24c' solar rooftop: '#ffea80' # gas OCGT: '#e0986c' OCGT marginal: '#e0986c' OCGT-heat: '#e0986c' gas boiler: '#db6a25' gas boilers: '#db6a25' gas boiler marginal: '#db6a25' residential rural gas boiler: '#d4722e' residential urban decentral gas boiler: '#cb7a36' services rural gas boiler: '#c4813f' services urban decentral gas boiler: '#ba8947' urban central gas boiler: '#b0904f' gas: '#e05b09' fossil gas: '#e05b09' natural gas: '#e05b09' biogas to gas: '#e36311' biogas to gas CC: '#e51245' CCGT: '#a85522' CCGT marginal: '#a85522' allam: '#B98F76' gas for industry co2 to atmosphere: '#692e0a' gas for industry co2 to stored: '#8a3400' gas for industry: '#853403' gas for industry CC: '#692e0a' gas pipeline: '#ebbca0' gas pipeline new: '#a87c62' # oil oil: '#c9c9c9' imported oil: '#a3a3a3' oil boiler: '#adadad' residential rural oil boiler: '#a9a9a9' services rural oil boiler: '#a5a5a5' residential urban decentral oil boiler: '#a1a1a1' urban central oil boiler: '#9d9d9d' services urban decentral oil boiler: '#999999' agriculture machinery oil: '#949494' shipping oil: "#808080" land transport oil: '#afafaf' # nuclear Nuclear: '#ff8c00' Nuclear marginal: '#ff8c00' nuclear: '#ff8c00' uranium: '#ff8c00' # coal Coal: '#545454' coal: '#545454' Coal marginal: '#545454' coal for industry: '#343434' solid: '#545454' Lignite: '#826837' lignite: '#826837' Lignite marginal: '#826837' # biomass biogas: '#e3d37d' biomass: '#baa741' solid biomass: '#baa741' solid biomass transport: '#baa741' solid biomass for industry: '#7a6d26' solid biomass for industry CC: '#47411c' solid biomass for industry co2 from atmosphere: '#736412' solid biomass for industry co2 to stored: '#47411c' urban central solid biomass CHP: '#9d9042' urban central solid biomass CHP CC: '#6c5d28' biomass boiler: '#8A9A5B' residential rural biomass boiler: '#a1a066' residential urban decentral biomass boiler: '#b0b87b' services rural biomass boiler: '#c6cf98' services urban decentral biomass boiler: '#dde5b5' biomass to liquid: '#32CD32' BioSNG: '#123456' # power transmission lines: '#6c9459' transmission lines: '#6c9459' electricity distribution grid: '#97ad8c' low voltage: '#97ad8c' # electricity demand Electric load: '#110d63' electric demand: '#110d63' electricity: '#110d63' industry electricity: '#2d2a66' industry new electricity: '#2d2a66' agriculture electricity: '#494778' # battery + EVs battery: '#ace37f' battery storage: '#ace37f' battery charger: '#88a75b' battery discharger: '#5d4e29' home battery: '#80c944' home battery storage: '#80c944' home battery charger: '#5e8032' home battery discharger: '#3c5221' BEV charger: '#baf238' V2G: '#e5ffa8' land transport EV: '#baf238' land transport demand: '#38baf2' Li ion: '#baf238' # hot water storage water tanks: '#e69487' residential rural water tanks: '#f7b7a3' services rural water tanks: '#f3afa3' residential urban decentral water tanks: '#f2b2a3' services urban decentral water tanks: '#f1b4a4' urban central water tanks: '#e9977d' hot water storage: '#e69487' hot water charging: '#e8998b' urban central water tanks charger: '#b57a67' residential rural water tanks charger: '#b4887c' residential urban decentral water tanks charger: '#b39995' services rural water tanks charger: '#b3abb0' services urban decentral water tanks charger: '#b3becc' hot water discharging: '#e99c8e' urban central water tanks discharger: '#b9816e' residential rural water tanks discharger: '#ba9685' residential urban decentral water tanks discharger: '#baac9e' services rural water tanks discharger: '#bbc2b8' services urban decentral water tanks discharger: '#bdd8d3' # heat demand Heat load: '#cc1f1f' heat: '#cc1f1f' heat vent: '#aa3344' heat demand: '#cc1f1f' rural heat: '#ff5c5c' residential rural heat: '#ff7c7c' services rural heat: '#ff9c9c' central heat: '#cc1f1f' urban central heat: '#d15959' urban central heat vent: '#a74747' decentral heat: '#750606' residential urban decentral heat: '#a33c3c' services urban decentral heat: '#cc1f1f' low-temperature heat for industry: '#8f2727' process heat: '#ff0000' agriculture heat: '#d9a5a5' # heat supply heat pumps: '#2fb537' heat pump: '#2fb537' air heat pump: '#36eb41' residential urban decentral air heat pump: '#48f74f' services urban decentral air heat pump: '#5af95d' services rural air heat pump: '#5af95d' urban central air heat pump: '#6cfb6b' ground heat pump: '#2fb537' residential rural ground heat pump: '#48f74f' residential rural air heat pump: '#48f74f' services rural ground heat pump: '#5af95d' Ambient: '#98eb9d' CHP: '#8a5751' urban central gas CHP: '#8d5e56' CHP CC: '#634643' urban central gas CHP CC: '#6e4e4c' CHP heat: '#8a5751' CHP electric: '#8a5751' district heating: '#e8beac' resistive heater: '#d8f9b8' residential rural resistive heater: '#bef5b5' residential urban decentral resistive heater: '#b2f1a9' services rural resistive heater: '#a5ed9d' services urban decentral resistive heater: '#98e991' urban central resistive heater: '#8cdf85' retrofitting: '#8487e8' building retrofitting: '#8487e8' # hydrogen H2 for industry: "#f073da" H2 for shipping: "#ebaee0" H2: '#bf13a0' hydrogen: '#bf13a0' retrofitted H2 boiler: '#e5a0d9' SMR: '#870c71' SMR CC: '#4f1745' H2 liquefaction: '#d647bd' hydrogen storage: '#bf13a0' H2 Store: '#bf13a0' H2 storage: '#bf13a0' land transport fuel cell: '#6b3161' H2 pipeline: '#f081dc' H2 pipeline retrofitted: '#ba99b5' H2 Fuel Cell: '#c251ae' H2 fuel cell: '#c251ae' H2 turbine: '#991f83' H2 Electrolysis: '#ff29d9' H2 electrolysis: '#ff29d9' # ammonia NH3: '#46caf0' ammonia: '#46caf0' ammonia store: '#00ace0' ammonia cracker: '#87d0e6' Haber-Bosch: '#076987' # syngas Sabatier: '#9850ad' methanation: '#c44ce6' methane: '#c44ce6' # synfuels Fischer-Tropsch: '#25c49a' liquid: '#25c49a' kerosene for aviation: '#a1ffe6' naphtha for industry: '#57ebc4' methanolisation: '#83d6d5' methanol: '#468c8b' shipping methanol: '#468c8b' industry methanol: '#468c8b' # co2 CC: '#f29dae' CCS: '#f29dae' CO2 sequestration: '#f29dae' DAC: '#ff5270' co2 stored: '#f2385a' co2 sequestered: '#f2682f' co2: '#f29dae' co2 vent: '#ffd4dc' CO2 pipeline: '#f5627f' # emissions process emissions CC: '#000000' process emissions: '#222222' process emissions to stored: '#444444' process emissions to atmosphere: '#888888' oil emissions: '#aaaaaa' shipping oil emissions: "#555555" shipping methanol emissions: '#666666' land transport oil emissions: '#777777' agriculture machinery oil emissions: '#333333' # other shipping: '#03a2ff' power-to-heat: '#2fb537' power-to-gas: '#c44ce6' power-to-H2: '#ff29d9' power-to-liquid: '#25c49a' gas-to-power/heat: '#ee8340' waste: '#e3d37d' other: '#000000' geothermal: '#ba91b1' geothermal heat: '#ba91b1' geothermal district heat: '#d19D00' geothermal organic rankine cycle: '#ffbf00' AC: "#70af1d" AC-AC: "#70af1d" AC line: "#70af1d" links: "#8a1caf" HVDC links: "#8a1caf" DC: "#8a1caf" DC-DC: "#8a1caf" DC link: "#8a1caf" load: "#dd2e23" waste CHP: '#e3d37d' waste CHP CC: '#e3d3ff' HVC to air: 'k'