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config.tutorial.yaml
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config.tutorial.yaml
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# SPDX-FileCopyrightText: PyPSA-Earth and PyPSA-Eur Authors
#
# SPDX-License-Identifier: CC0-1.0
version: 1.0.0
tutorial: true
logging:
level: INFO
format: "%(levelname)s:%(name)s:%(message)s"
run:
name: ""
scenario:
simpl: ['']
ll: ['copt']
clusters: [6]
opts: [Co2L-4H]
countries: ["NG", "BJ"]
# ['DZ', 'AO', 'BJ', 'BW', 'BF', 'BI', 'CM', 'CF', 'TD', 'CG', 'CD',
# 'DJ', 'EG', 'GQ', 'ER', 'ET', 'GA', 'GH', 'GN', 'CI', 'KE', 'LS', 'LR', 'LY',
# 'MG', 'MW', 'ML', 'MR', 'MU', 'MA', 'MZ', 'NA', 'NE', 'NG', 'RW',
# 'SL', 'ZA', 'SS', 'SD', 'SZ', 'TZ', 'TG', 'TN', 'UG', 'ZM', 'ZW'] # list(AFRICA_CC)
#["NG"] # Nigeria
#["NE"] # Niger
#["SL"] # Sierra Leone
#["MA"] # Morroco
#["ZA"] # South Africa
summary_dir: results
snapshots:
start: "2013-03-1"
end: "2013-03-7"
inclusive: "left" # end is not inclusive
enable:
# prepare_links_p_nom: false
retrieve_databundle: true
retrieve_cost_data: true
download_osm_data: true
# If "build_cutout" : true # requires cds API key https://cds.climate.copernicus.eu/api-how-to
# More information https://atlite.readthedocs.io/en/latest/introduction.html#datasets
build_cutout: false
build_natura_raster: true # If True, then build_natura_raster can be run
# definition of the Coordinate Reference Systems
crs:
geo_crs: EPSG:4326 # general geographic projection, not used for metric measures. "EPSG:4326" is the standard used by OSM and google maps
distance_crs: EPSG:3857 # projection for distance measurements only. Possible recommended values are "EPSG:3857" (used by OSM and Google Maps)
area_crs: ESRI:54009 # projection for area measurements only. Possible recommended values are Global Mollweide "ESRI:54009"
# CI relevant
retrieve_databundle: # required to be "false" for nice CI test output
show_progress: true # show (true) or do not show (false) the progress bar in retrieve_databundle while downloading data
augmented_line_connection:
add_to_snakefile: false # If True, includes this rule to the workflow
connectivity_upgrade: 2 # Min. lines connection per node, https://networkx.org/documentation/stable/reference/algorithms/generated/networkx.algorithms.connectivity.edge_augmentation.k_edge_augmentation.html#networkx.algorithms.connectivity.edge_augmentation.k_edge_augmentation
new_line_type: ["HVAC"] # Expanded lines can be either ["HVAC"] or ["HVDC"] or both ["HVAC", "HVDC"]
min_expansion: 1 # [MW] New created line expands by float/int input
min_DC_length: 600 # [km] Minimum line length of DC line
# if True clusters to GADM shapes, if False Voronoi cells will be clustered
cluster_options:
simplify_network:
to_substations: false # network is simplified to nodes with positive or negative power injection (i.e. substations or offwind connections)
algorithm: kmeans # choose from: [hac, kmeans]
feature: solar+onwind-time # only for hac. choose from: [solar+onwind-time, solar+onwind-cap, solar-time, solar-cap, solar+offwind-cap] etc.
exclude_carriers: []
remove_stubs: true
remove_stubs_across_borders: true
p_threshold_drop_isolated: 20 # [MW] isolated buses are being discarded if bus mean power is below the specified threshold
p_threshold_merge_isolated: 300 # [MW] isolated buses are being merged into a single isolated bus if bus mean power is above the specified threshold
cluster_network:
algorithm: kmeans
feature: solar+onwind-time
exclude_carriers: []
alternative_clustering: false # "False" use Voronoi shapes, "True" use GADM shapes
distribute_cluster: ['load'] # ['load'],['pop'] or ['gdp']
out_logging: true # When true, logging is printed to console
aggregation_strategies:
generators: # use "min" for more conservative assumptions
p_nom: sum
p_nom_max: sum
p_nom_min: sum
p_min_pu: mean
marginal_cost: mean
committable: any
ramp_limit_up: max
ramp_limit_down: max
efficiency: mean
# options for build_shapes
build_shape_options:
gadm_layer_id: 1 # GADM level area used for the gadm_shapes. Codes are country-dependent but roughly: 0: country, 1: region/county-like, 2: municipality-like
update_file: false # When true, all the input files are downloaded again and replace the existing files
out_logging: true # When true, logging is printed to console
year: 2020 # reference year used to derive shapes, info on population and info on GDP
nprocesses: 2 # number of processes to be used in build_shapes
nchunks: 2 # number of data chuncks for build_shapes. If not specified or smaller than nprocesses, specified as nprocesses
worldpop_method: "standard" # "standard" pulls from web 1kmx1km raster, "api" pulls from API 100mx100m raster, false (not "false") no pop addition to shape which is useful when generating only cutout
gdp_method: "standard" # "standard" pulls from web 1x1km raster, false (not "false") no gdp addition to shape which useful when generating only cutout
contended_flag: "set_by_country" # "set_by_country" assigns the contended areas to the countries according to the GADM database, "drop" drops these contended areas from the model
clean_osm_data_options:
names_by_shapes: true # Set the country name based on the extended country shapes
threshold_voltage: 35000 # [V] minimum voltage threshold to keep the asset (cable, line, generator, etc.) [V]
tag_substation: "transmission" # needed feature tag to be considered for the analysis. If empty, no filtering on the tag_substation is performed
add_line_endings: true # When true, the line endings are added to the dataset of the substations
generator_name_method: OSM # Methodology to specify the name to the generator. Options: OSM (name as by OSM dataset), closest_city (name by the closest city)
build_osm_network: # Options of the build_osm_network script; osm = OpenStreetMap
group_close_buses: true # When "True", close buses are merged and guarantee the voltage matching among line endings
group_tolerance_buses: 5000 # [m] (default 5000) Tolerance in meters of the close buses to merge
split_overpassing_lines: true # When True, lines overpassing buses are splitted and connected to the bueses
overpassing_lines_tolerance: 1 # [m] (default 1) Tolerance to identify lines overpassing buses
force_ac: false # When true, it forces all components (lines and substation) to be AC-only. To be used if DC assets create problem.
base_network:
min_voltage_substation_offshore: 35000 # [V] minimum voltage of the offshore substations
min_voltage_rebase_voltage: 35000
load_options:
ssp: "ssp2-2.6" # shared socio-economic pathway (GDP and population growth) scenario to consider
weather_year: 2013 # Load scenarios available with different weather year (different renewable potentials)
prediction_year: 2030 # Load scenarios available with different prediction year (GDP, population)
scale: 1 # scales all load time-series, i.e. 2 = doubles load
electricity:
voltages: [220., 300., 380.]
co2limit: 1.487e+9
co2base: 1.487e+9
agg_p_nom_limits: data/agg_p_nom_minmax.csv
hvdc_as_lines: false # should HVDC lines be modeled as `Line` or as `Link` component?
operational_reserve: # like https://genxproject.github.io/GenX/dev/core/#Reserves
activate: false
epsilon_load: 0.02 # share of total load
epsilon_vres: 0.02 # share of total renewable supply
contingency: 0 # fixed capacity in MW
max_hours:
battery: 6
H2: 168
extendable_carriers:
Generator: [solar, onwind, offwind-ac, offwind-dc, OCGT]
StorageUnit: [] # battery, H2
Store: [battery, H2]
Link: [] # H2 pipeline
powerplants_filter: (DateOut >= 2022 or DateOut != DateOut)
custom_powerplants: false
conventional_carriers: [nuclear, oil, OCGT, CCGT, coal, lignite, geothermal, biomass]
renewable_carriers: [solar, onwind, offwind-ac, offwind-dc, hydro]
estimate_renewable_capacities:
stats: "irena" # False, = greenfield expansion, 'irena' uses IRENA stats to add expansion limits
year: 2020 # Reference year, available years for IRENA stats are 2000 to 2020
p_nom_min: 1 # any float, scales the minimum expansion acquired from stats, i.e. 110% of <years>'s capacities => p_nom_min: 1.1
p_nom_max: false # sets the expansion constraint, False to deactivate this option and use estimated renewable potentials determine by the workflow, float scales the p_nom_min factor accordingly
technology_mapping:
# Wind is the Fueltype in ppm.data.Capacity_stats, onwind, offwind-{ac,dc} the carrier in PyPSA-Earth
Offshore: [offwind-ac, offwind-dc]
Onshore: [onwind]
PV: [solar]
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"
dc_type: "HVDC XLPE 1000"
s_max_pu: 0.7
s_nom_max: .inf
length_factor: 1.25
under_construction: "zero" # 'zero': set capacity to zero, 'remove': remove, 'keep': with full capacity
links:
p_max_pu: 1.0
p_nom_max: .inf
under_construction: "zero" # 'zero': set capacity to zero, 'remove': remove, 'keep': with full capacity
transformers:
x: 0.1
s_nom: 2000.
type: ""
atlite:
nprocesses: 4
cutouts:
# use 'base' to determine geographical bounds and time span from config
# base:
# module: era5
africa-2013-era5-tutorial:
module: era5
dx: 0.3 # cutout resolution
dy: 0.3 # cutout resolution
# The cutout time is automatically set by the snapshot range. See `snapshot:` option above and 'build_cutout.py'.
# time: ["2013-01-01", "2014-01-01"] # to manually specify a different weather year (~70 years available)
# The cutout spatial extent [x,y] is automatically set by country selection. See `countires:` option above and 'build_cutout.py'.
# x: [-12., 35.] # set cutout range manual, instead of automatic by boundaries of country
# y: [33., 72] # manual set cutout range
renewable:
onwind:
cutout: africa-2013-era5-tutorial
resource:
method: wind
turbine: Vestas_V112_3MW
capacity_per_sqkm: 3 # ScholzPhd Tab 4.3.1: 10MW/km^2
# correction_factor: 0.93
copernicus:
# Scholz, Y. (2012). Renewable energy based electricity supply at low costs:
# development of the REMix model and application for Europe. ( p.42 / p.28)
grid_codes: [20, 30, 40, 60, 100, 111, 112, 113, 114, 115, 116, 121, 122, 123, 124, 125, 126]
distance: 1000
distance_grid_codes: [50]
natura: true
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
offwind-ac:
cutout: africa-2013-era5-tutorial
resource:
method: wind
turbine: NREL_ReferenceTurbine_5MW_offshore
capacity_per_sqkm: 3
# correction_factor: 0.93
copernicus:
grid_codes: [80, 200]
natura: true
max_depth: 50
max_shore_distance: 30000
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
offwind-dc:
cutout: africa-2013-era5-tutorial
resource:
method: wind
turbine: NREL_ReferenceTurbine_5MW_offshore
# ScholzPhd Tab 4.3.1: 10MW/km^2
capacity_per_sqkm: 3
# correction_factor: 0.93
copernicus:
grid_codes: [80, 200]
natura: true
max_depth: 50
min_shore_distance: 30000
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
solar:
cutout: africa-2013-era5-tutorial
resource:
method: pv
panel: CSi
orientation: latitude_optimal # will lead into optimal design
# slope: 0. # slope: 0 represent a flat panel
# azimuth: 180. # azimuth: 180 south orientation
capacity_per_sqkm: 4.6 # From 1.7 to 4.6 addresses issue #361
# Determined by comparing uncorrected area-weighted full-load hours to those
# published in Supplementary Data to
# Pietzcker, Robert Carl, et al. "Using the sun to decarbonize the power
# sector: The economic potential of photovoltaics and concentrating solar
# power." Applied Energy 135 (2014): 704-720.
correction_factor: 0.854337
copernicus:
grid_codes: [20, 30, 40, 50, 60, 90, 100]
natura: true
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
hydro:
cutout: africa-2013-era5-tutorial
resource:
method: hydro
hydrobasins: data/hydrobasins/hybas_world_lev04_v1c.shp
flowspeed: 1.0 # m/s
# weight_with_height: false
# show_progress: true
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
clip_min_inflow: 1.0
normalization:
method: hydro_capacities # 'hydro_capacities' to rescale country hydro production by using hydro_capacities, 'eia' to rescale by eia data, false for no rescaling
year: 2013 # (optional) year of statistics used to rescale the runoff time series. When not provided, the cutout weather year is used
multiplier: 1.1 # multiplier applied after the normalization of the hydro production; default 1.0
# TODO: Needs to be adjusted for Africa
costs:
year: 2030
version: v0.5.0
rooftop_share: 0.14 # based on the potentials, assuming (0.1 kW/m2 and 10 m2/person)
USD2013_to_EUR2013: 0.7532 # [EUR/USD] ECB: https://www.ecb.europa.eu/stats/exchange/eurofxref/html/eurofxref-graph-usd.en.html
fill_values:
FOM: 0
VOM: 0
efficiency: 1
fuel: 0
investment: 0
lifetime: 25
CO2 intensity: 0
discount rate: 0.07
marginal_cost: # EUR/MWh
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: # in currency per tonne emission, only used with the option Ep
co2: 0.
monte_carlo:
options:
add_to_snakefile: false
samples: 7 # number of optimizations
sampling_strategy: "chaospy" # "pydoe2", "chaospy", "scipy", packages that are supported
pypsa_standard:
# User can add here flexibly more features for the Monte-Carlo sampling.
# Given as "key: value" format
# Key: add below the pypsa object for the monte_carlo sampling, "network" is only allowed for filtering!
# Value: currently supported format [l_bound, u_bound] or empty [], represent multiplication factors for the object
loads_t.p_set: [0.9, 1.1]
generators_t.p_max_pu.loc[:, n.generators.carrier == "wind"]: [0.9, 1.1]
generators_t.p_max_pu.loc[:, n.generators.carrier == "solar"]: [0.9, 1.1]
solving:
options:
formulation: kirchhoff
load_shedding: true
noisy_costs: true
min_iterations: 4
max_iterations: 6
clip_p_max_pu: 0.01
skip_iterations: true
track_iterations: false
#nhours: 10
solver:
name: glpk
plotting:
map:
figsize: [7, 7]
boundaries: [-10.2, 29, 35, 72]
p_nom:
bus_size_factor: 5.e+4
linewidth_factor: 3.e+3
costs_max: 800
costs_threshold: 1
energy_max: 15000.
energy_min: -10000.
energy_threshold: 50.
vre_techs: ["onwind", "offwind-ac", "offwind-dc", "solar", "ror"]
conv_techs: ["OCGT", "CCGT", "nuclear", "coal", "oil"]
storage_techs: ["hydro+PHS", "battery", "H2"]
load_carriers: ["AC load"]
AC_carriers: ["AC line", "AC transformer"]
link_carriers: ["DC line", "Converter AC-DC"]
tech_colors:
"onwind": "#235ebc"
"onshore wind": "#235ebc"
"offwind": "#6895dd"
"offwind-ac": "#6895dd"
"offshore wind": "#6895dd"
"offshore wind ac": "#6895dd"
"offwind-dc": "#74c6f2"
"offshore wind dc": "#74c6f2"
"hydro": "#08ad97"
"hydro+PHS": "#08ad97"
"PHS": "#08ad97"
"hydro reservoir": "#08ad97"
"hydroelectricity": "#08ad97"
"ror": "#4adbc8"
"run of river": "#4adbc8"
"solar": "#f9d002"
"solar PV": "#f9d002"
"solar thermal": "#ffef60"
"biomass": "#0c6013"
"solid biomass": "#06540d"
"biogas": "#23932d"
"waste": "#68896b"
"geothermal": "#ba91b1"
"OCGT": "#d35050"
"gas": "#d35050"
"natural gas": "#d35050"
"CCGT": "#b20101"
"nuclear": "#ff9000"
"coal": "#707070"
"lignite": "#9e5a01"
"oil": "#262626"
"H2": "#ea048a"
"hydrogen storage": "#ea048a"
"battery": "#b8ea04"
"Electric load": "#f9d002"
"electricity": "#f9d002"
"lines": "#70af1d"
"transmission lines": "#70af1d"
"AC-AC": "#70af1d"
"AC line": "#70af1d"
"links": "#8a1caf"
"HVDC links": "#8a1caf"
"DC-DC": "#8a1caf"
"DC link": "#8a1caf"
"load": "#FF0000"
nice_names:
OCGT: "Open-Cycle Gas"
CCGT: "Combined-Cycle Gas"
offwind-ac: "Offshore Wind (AC)"
offwind-dc: "Offshore Wind (DC)"
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"