Input Data¶
Electric System Input Data¶
All the input files must be located in a folder with the name of the case study.
Acronyms¶
Acronym |
Description |
|---|---|
aFRR |
Automatic Frequency Restoration Reserve |
AWE |
Alkaline Water Electrolyzer |
BESS |
Battery Energy Storage System |
CCGT |
Combined Cycle Gas Turbine |
EFOR |
Equivalent Forced Outage Rate |
ENS |
Energy Not Served |
ESS |
Energy Storage System |
mFRR |
Manual Frequency Restoration Reserve |
H2 |
Hydrogen |
HNS |
Hydrogen Not Served |
OCGT |
Open Cycle Gas Turbine |
PHS |
Pumped-Hydro Storage |
PNS |
Power Not Served |
PV |
Photovoltaics |
RR |
Replacement Reserve |
VRE |
Variable Renewable Energy |
VRES |
Variable Renewable Energy Source |
Dictionaries. Sets¶
The dictionaries include all the possible elements of the corresponding sets in the optimization problem. You can’t use non-English characters (e.g., ó, º)
File |
Description |
|---|---|
|
Period (e.g., 0, 1, 2). It must be a positive integer equivalent to hours |
|
Scenario. Short-term uncertainties (scenarios) (e.g., s001 to s100) |
|
Stage |
|
Load level (e.g., 01-01 00:00:00+01:00 to 01-01 00:45:00+01:00). Load levels with duration 0 are ignored |
|
Generation units (thermal -nuclear, CCGT, OCGT, coal-, ESS -hydro, pumped-hydro storage PHS, battery BESS, electric vehicle EV, demand response DR, alkaline water electrolyzer AWE, solar thermal- and VRE -wind onshore and offshore, solar PV, run-of-the-river hydro-) |
|
Generation technologies. The technology order is used in the temporal result plot. |
|
ESS storage type (daily < 12 h, weekly < 40 h, monthly > 60 h) |
Input files¶
This is the list of the input data files and their brief description.
File |
Description |
|---|---|
|
Options of use of the HySTEM model |
|
General system parameters |
|
Weight of each period |
|
Duration of the load levels |
|
Short-term uncertainties |
|
Demand |
|
Cost of the energy bought and price of the energy sold |
|
Upward and downward operating reserves (include aFRR, mFRR and RR for electricity balancing from ENTSO-E) |
|
Price of the operating reserve sold |
|
Generation data |
|
Energy inflows for ESS (e.g., storage hydro or open-loop pumped-storage hydro) by load level |
|
Minimum product outflows for ESS (e.g., kg of H2) by load level |
|
Maximum product outflows for ESS (e.g., kg of H2) by load level |
|
Variable maximum power generation by load level |
|
Variable minimum power generation by load level |
|
Variable maximum power consumption by load level |
|
Variable minimum power consumption by load level |
|
Variable maximum storage by load level |
|
Variable minimum storage by load level |
In any input file, only the columns indicated in this document will be read. For example, you can add a column for comments or additional information as needed, but it will not be read by the model.
Options¶
A description of the options included in the file HySTEM_Data_Option.csv follows:
File |
Description |
|
|---|---|---|
IndActIntraDay |
Indicator of activation of the intra-day decisions |
{0 deactivation, 1 activation} |
If the investment decisions are ignored (IndBinGenInvest, IndBinGenRetirement, and IndBinNetInvest take value 2) or there are no investment decisions, all the scenarios with a probability > 0 are solved sequentially (assuming a probability 1) and the periods are considered with a weight 1.
Parameters¶
A description of the system parameters included in the file HySTEM_Data_Parameter.csv follows:
File |
Description |
|
|---|---|---|
ENSCost |
Cost of energy not served. Cost of load curtailment. Value of Lost Load (VoLL) |
€/MWh |
HNSCost |
Cost of hydrogen not served (HNS) |
€/kgH2 |
PNSCost |
Cost of power not served (PNS) associated with the deficit in operating reserve by load level |
€/MW |
CO2Cost |
Cost of CO2 emissions |
€/tCO2 |
Sbase |
Base power used in the DCPF |
MW |
TimeStep |
Duration of the time step for the load levels (hourly, bi-hourly, trihourly, etc.) |
h |
EconomicBaseYear |
Base year for economic parameters affected by the discount rate |
year |
AnnualDiscountRate |
Annual discount rate |
p.u. |
A time step greater than one hour it is a convenient way to reduce the load levels of the time scope. The moving average of the demand, operating reserve, variable generation and ESS product inflows and outflows over the time step load levels is assigned to active load levels (e.g., the mean value of the three hours is associated to the third hour in a trihourly time step).
Period¶
A description of the data included in the file oT_Data_Period.csv follows:
Identifier |
Header |
Description |
|---|---|---|
Period |
Weight |
Weight of each period |
This weight allows the definition of equivalent (representative) years (e.g., year 2030 with a weight of 5 would represent years 2030-2034). Periods are not mathematically connected between them, i.e., no constraints link the operation at different periods.
Scenario¶
A description of the data included in the file oT_Data_Scenario.csv follows:
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|
Period |
Scenario |
Probability |
Probability of each scenario in each period |
p.u. |
For example, the scenarios can be used for obtaining the GEP+SEP+TEP considering hydro energy inflows uncertainty represented by means of three scenarios (wet, dry and average), or two VRE scenarios (windy/cloudy and calm/sunny). The sum of the probabilities of all the scenarios of a period must be 1.
Stage¶
A description of the data included in the file oT_Data_Stage.csv follows:
Identifier |
Header |
Description |
|---|---|---|
Scenario |
Weight |
Weight of each stage |
This weight allows the definition of equivalent (representative) periods (e.g., one representative week with a weight of 52). Stages are not mathematically connected between them, i.e., no constraints link the operation at different stages.
Adequacy reserve margin¶
A description of the data included in the file oT_Data_ReserveMargin.csv follows:
Identifier |
Header |
Description |
|---|---|---|
Scenario |
ReserveMargin |
Adequacy reserve margin for each area |
This parameter is only used for system generation expansion, not for the system operation.
Duration¶
A description of the data included in the file oT_Data_Duration.csv follows:
Header |
Description |
|
|---|---|---|
LoadLevel |
Load level |
datetime |
Duration |
Duration of the load level. Load levels with duration 0 are ignored |
h |
Stage |
Assignment of the load level to a stage |
It is a simple way to use isolated snapshots or representative days or just the first three months instead of all the hours of a year to simplify the optimization problem.
The stage duration as sum of the duration of all the load levels must be larger or equal than the shortest duration of any storage type or any outflows type (both given in the generation data) and multiple of it. Consecutive stages are not tied between them. Consequently, the objective function must be a bit lower.
The initial storage of the ESSs is also fixed at the beginning and end of each stage. For example, the initial storage level is set for the hour 8736 in case of a single stage or for the hours 4368 and 4369 (end of the first stage and beginning of the second stage) in case of two stages, each with 4368 hours.
Electricity demand¶
A description of the data included in the file oT_Data_Demand.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Node |
Power demand of the node for each load level |
MW |
The electricity demand can be negative for the (transmission) nodes where there is (renewable) generation in lower voltage levels. This negative demand is equivalent to generate that power amount in this node. Internally, all the values below if positive demand (or above if negative demand) 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
System inertia¶
A description of the data included in the files oT_Data_Inertia.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Area |
System inertia of the area for each load level |
s |
Given that the system inertia depends on the area, it can be sensible to assign an area as a country, for example. The system inertia can be used for imposing a minimum synchronous power and, consequently, force the commitment of at least some rotating units.
Internally, all the values below 2.5e-5 times the maximum system electricity demand of each area will be converted into 0 by the model.
Upward and downward operating reserves¶
A description of the data included in the files oT_Data_OperatingReserveUp.csv and oT_Data_OperatingReserveDown.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Area |
Upward/downward operating reserves of the area for each load level |
MW |
Given that the operating reserves depend on the area, it can be sensible to assign an area as a country, for example. These operating reserves must include Automatic Frequency Restoration Reserves (aFRR), Manual Frequency Restoration Reserves (mFRR) and Replacement Reserves (RR) for electricity balancing from ENTSO-E.
Internally, all the values below 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
Generation¶
A description of the data included for each generating unit in the file oT_Data_Generation.csv follows:
Header |
Description |
|
|---|---|---|
Node |
Name of the node where generator is located. If left empty, the generator is ignored |
|
Technology |
Technology of the generator (nuclear, coal, CCGT, OCGT, ESS, solar, wind, biomass, etc.) |
|
MutuallyExclusive |
Mutually exclusive generator. Only exclusion in one direction is needed |
|
BinaryCommitment |
Binary unit commitment decision |
Yes/No |
NoOperatingReserve |
No contribution to operating reserve. Yes if the unit doesn’t contribute to the operating reserve |
Yes/No |
StorageType |
Storage type based on storage capacity (hourly, daily, weekly, 4-week, yearly) |
Hourly/Daily/Weekly/Monthly/Yearly |
OutflowsType |
Outflows type based on the electricity demand extracted from the storage (daily, weekly, 4-week, yearly) |
Daily/Weekly/Monthly/Yearly |
EnergyType |
Energy type based on the max/min energy to be produced by the unit (daily, weekly, 4-week, yearly) |
Daily/Weekly/Monthly/Yearly |
MustRun |
Must-run unit |
Yes/No |
InitialPeriod |
Initial period (year) when the unit is installed or can be installed, if candidate |
Year |
FinalPeriod |
Final period (year) when the unit is installed or can be installed, if candidate |
Year |
MaximumPower |
Maximum power output (generation/discharge for ESS units) |
MW |
MinimumPower |
Minimum power output (i.e., minimum stable load in the case of a thermal power plant) |
MW |
MaximumReactivePower |
Maximum reactive power output (discharge for ESS units) (not used in this version) |
MW |
MinimumReactivePower |
Minimum reactive power output (not used in this version) |
MW |
MaximumCharge |
Maximum consumption/charge when the ESS unit is storing energy |
MW |
MinimumCharge |
Minimum consumption/charge when the ESS unit is storing energy |
MW |
InitialStorage |
Initial energy stored at the first instant of the time scope |
GWh |
MaximumStorage |
Maximum energy that can be stored by the ESS unit |
GWh |
MinimumStorage |
Minimum energy that can be stored by the ESS unit |
GWh |
Efficiency |
Round-trip efficiency of the pump/turbine cycle of a pumped-hydro storage power plant or charge/discharge of a battery |
p.u. |
ProductionFunction |
Production function from water inflows to energy (only used for hydropower plants modeled with water units and basin topology) |
kWh/m3 |
ProductionFunctionH2 |
Production function from energy to hydrogen (only used for electrolyzers) |
kWh/kgH2 |
Availability |
Unit availability for system adequacy reserve margin |
p.u. |
Inertia |
Unit inertia constant |
s |
EFOR |
Equivalent Forced Outage Rate |
p.u. |
RampUp |
Ramp up rate for generating units or maximum discharge rate for ESS discharge |
MW/h |
RampDown |
Ramp down rate for generating units or maximum charge rate for ESS charge |
MW/h |
UpTime |
Minimum uptime |
h |
DownTime |
Minimum downtime |
h |
ShiftTime |
Maximum shift time |
h |
FuelCost |
Fuel cost |
€/Mcal |
LinearTerm |
Linear term (slope) of the heat rate straight line |
Mcal/MWh |
ConstantTerm |
Constant term (intercept) of the heat rate straight line |
Mcal/h |
OMVariableCost |
Variable O&M cost |
€/MWh |
OperReserveCost |
Operating reserve cost |
€/MW |
StartUpCost |
Startup cost |
M€ |
ShutDownCost |
Shutdown cost |
M€ |
CO2EmissionRate |
CO2 emission rate. It can be negative for units absorbing CO2 emissions as biomass |
tCO2/MWh |
FixedInvestmentCost |
Overnight investment (capital and fixed O&M) cost |
M€ |
FixedRetirementCost |
Overnight retirement (capital and fixed O&M) cost |
M€ |
FixedChargeRate |
Fixed-charge rate to annualize the overnight investment cost |
p.u. |
StorageInvestment |
Storage capacity and energy inflows linked to the investment decision |
Yes/No |
BinaryInvestment |
Binary unit investment decision |
Yes/No |
InvestmentLo |
Lower bound of investment decision |
p.u. |
InvestmentUp |
Upper bound of investment decision |
p.u. |
BinaryRetirement |
Binary unit retirement decision |
Yes/No |
RetirementLo |
Lower bound of retirement decision |
p.u. |
RetirementUp |
Upper bound of retirement decision |
p.u. |
Daily storage type means that the ESS inventory is assessed every time step, for weekly storage type it is assessed at the end of every day, and monthly/yearly storage type is assessed at the end of every week. Outflows type represents the interval when the energy extracted from the storage must be satisfied (for daily outflows type at the end of every day, i.e., the sum of the energy consumed must be equal to the sum of outflows for every day). Energy type represents the interval when the minimum or maximum energy to be produced by a unit must be satisfied (for daily energy type at the end of every day, i.e., the sum of the energy generated by the unit must be lower/greater to the sum of max/min energy for every day). The storage cycle is the minimum between the inventory assessment period (defined by the storage type), the outflows period (defined by the outflows type), and the energy period (defined by the energy type) (only if outflows or energy power values have been introduced). It can be one time step, one day, and one week. The ESS inventory level at the end of a larger storage cycle is fixed to its initial value, i.e., the inventory of a daily storage type (evaluated on a time step basis) is fixed at the end of the week, the inventory of weekly/monthly storage is fixed at the end of the year, only if the initial inventory lies between the storage limits.
The initial storage of the ESSs is also fixed at the beginning and end of each stage, only if the initial inventory lies between the storage limits. For example, the initial storage level is set for the hour 8736 in case of a single stage or for the hours 4368 and 4369 (end of the first stage and beginning of the second stage) in case of two stages, each with 4368 hours.
A generator with operation cost (sum of the fuel and emission cost, excluding O&M cost) > 0 is considered a non-renewable unit. If the unit has no operation cost and its maximum storage = 0, it is considered a renewable unit. If its maximum storage is > 0, with or without operation cost, is considered an ESS.
Must-run non-renewable units are always committed, i.e., their commitment decision is equal to 1. All must-run units are forced to produce at least their minimum output.
If unit availability is left 0 or empty is changed to 1. For declaring a unit non contributing to system adequacy reserve margin, put the availability equal to a very small number.
EFOR is used to reduce the maximum and minimum power of the unit. For hydro units it can be used to reduce their maximum power by the water head effect. It does not reduce the maximum charge.
Those generators or ESS with fixed cost > 0 are considered candidate and can be installed or not.
Maximum and minimum storage is considered proportional to the invested capacity for the candidate ESS units if StorageInvestment is activated.
If lower and upper bounds of investment/retirement decisions are very close (with a difference < 1e-3) to 0 or 1 are converted into 0 and 1.
Variable maximum and minimum generation¶
A description of the data included in the files oT_Data_VariableMaxGeneration.csv and oT_Data_VariableMinGeneration.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Generator |
Maximum (minimum) power generation of the unit by load level |
MW |
This information can be used for considering scheduled outages or weather-dependent operating capacity.
To force a generator to produce 0 a lower value (e.g., 0.1 MW) strictly > 0, but not 0 (in which case the value will be ignored), must be introduced. This is needed to limit the solar production at night, for example. It can be used also for upper-bounding and/or lower-bounding the output of any generator (e.g., run-of-the-river hydro, wind).
Internally, all the values below 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
Variable maximum and minimum consumption¶
A description of the data included in the files oT_Data_VariableMaxConsumption.csv and oT_Data_VariableMinConsumption.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Generator |
Maximum (minimum) power consumption of the unit by load level |
MW |
To force a ESS to consume 0 a lower value (e.g., 0.1 MW) strictly > 0, but not 0 (in which case the value will be ignored), must be introduced. It can be used also for upper-bounding and/or lower-bounding the consumption of any ESS (e.g., pumped-hydro storage, battery).
Internally, all the values below 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
Variable fuel cost¶
A description of the data included in the file oT_Data_VariableFuelCost.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Generator |
Variable fuel cost |
€/Mcal |
All the generators must be defined as columns of these files.
Internally, all the values below 1e-4 will be converted into 0 by the model.
Fuel cost affects the linear and constant terms of the heat rate, expressed in Mcal/MWh and Mcal/h respectively.
Energy inflows¶
A description of the data included in the file oT_Data_EnergyInflows.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Generator |
Energy inflows by load level |
MWh/h |
All the generators must be defined as columns of these files.
If you have daily energy inflows data just input the daily amount at the first hour of every day if the ESS have daily or weekly storage capacity.
Internally, all the values below 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
Energy inflows are considered proportional to the invested capacity for the candidate ESS units if StorageInvestment is activated.
Energy outflows¶
A description of the data included in the file oT_Data_EnergyOutflows.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Generator |
Energy outflows by load level |
MWh/h |
All the generators must be defined as columns of these files.
These energy outflows can be used to represent the energy extracted from an ESS to produce H2 from electrolyzers, to move EV or as hydro outflows for irrigation. The use of these outflows is incompatible with the charge of the ESS within the same time step (as the discharge of a battery is incompatible with the charge in the same hour).
If you have daily/weekly/monthly/yearly outflows data, you can just input the daily/weekly/monthly/yearly amount at the first hour of every day/week/month/year.
Internally, all the values below 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
Variable maximum and minimum storage¶
A description of the data included in the files oT_Data_VariableMaxStorage.csv and oT_Data_VariableMinStorage.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Generator |
Maximum (minimum) storage of the ESS by load level |
GWh |
All the generators must be defined as columns of these files.
For example, these data can be used for defining the operating guide (rule) curves for the ESS.
Variable maximum and minimum energy¶
A description of the data included in the files oT_Data_VariableMaxEnergy.csv and oT_Data_VariableMinEnergy.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Generator |
Maximum (minimum) energy of the unit by load level |
MW |
All the generators must be defined as columns of these files.
For example, these data can be used for defining the minimum and/or maximum energy to be produced on a daily/weekly/4-week/yearly basis (depending on the EnergyType).
Electricity transmission network¶
A description of the circuit (initial node, final node, circuit) data included in the file oT_Data_Network.csv follows:
Header |
Description |
|
|---|---|---|
LineType |
Line type {AC, DC, Transformer, Converter} |
|
Switching |
The transmission line is able to switch on/off |
Yes/No |
InitialPeriod |
Initial period (year) when the unit is installed or can be installed, if candidate |
Year |
FinalPeriod |
Final period (year) when the unit is installed or can be installed, if candidate |
Year |
Voltage |
Line voltage (e.g., 400, 220 kV, 220/400 kV if transformer). Used only for plotting purposes |
kV |
Length |
Line length (only used for reporting purposes). If not defined, computed as 1.1 times the geographical distance |
km |
LossFactor |
Transmission losses equal to the line flow times this factor |
p.u. |
Resistance |
Resistance (not used in this version) |
p.u. |
Reactance |
Reactance. Lines must have a reactance different from 0 to be considered |
p.u. |
Susceptance |
Susceptance (not used in this version) |
p.u. |
AngMax |
Maximum angle difference (not used in this version) |
º |
AngMin |
Minimum angle difference (not used in this version) |
º |
Tap |
Tap changer (not used in this version) |
p.u. |
Converter |
Converter station (not used in this version) |
Yes/No |
TTC |
Total transfer capacity (maximum permissible thermal load) in forward direction. Static line rating |
MW |
TTCBck |
Total transfer capacity (maximum permissible thermal load) in backward direction. Static line rating |
MW |
SecurityFactor |
Security factor to consider approximately N-1 contingencies. NTC = TTC x SecurityFactor |
p.u. |
FixedInvestmentCost |
Overnight investment (capital and fixed O&M) cost |
M€ |
FixedChargeRate |
Fixed-charge rate to annualize the overnight investment cost |
p.u. |
BinaryInvestment |
Binary line/circuit investment decision |
Yes/No |
InvestmentLo |
Lower bound of investment decision |
p.u. |
InvestmentUp |
Upper bound of investment decision |
p.u. |
SwOnTime |
Minimum switch-on time |
h |
SwOffTime |
Minimum switch-off time |
h |
Depending on the voltage lines are plotted with different colors (orange < 200 kV, 200 < green < 350 kV, 350 < red < 500 kV, 500 < orange < 700 kV, blue > 700 kV).
If there is no data for TTCBck, i.e., TTCBck is left empty or is equal to 0, it is substituted by the TTC in the code. Internally, all the TTC and TTCBck values below 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
Reactance can take a negative value as a result of the approximation of three-winding transformers. No Kirchhoff’s second law disjunctive constraint is formulated for a circuit with negative reactance.
Those lines with fixed cost > 0 are considered candidate and can be installed or not.
If lower and upper bounds of investment decisions are very close (with a difference < 1e-3) to 0 or 1 are converted into 0 and 1.
Node location¶
A description of the data included in the file oT_Data_NodeLocation.csv follows:
Identifier |
Header |
Description |
|
|---|---|---|---|
Node |
Latitude |
Node latitude |
º |
Node |
Longitude |
Node longitude |
º |
Hydrogen System Input Data¶
These input files are specifically introduced for allowing a representation of the hydrogen energy vector to supply hydrogen demand produced with electricity through the hydrogen network.
File |
Description |
|---|---|
|
Hydrogen demand |
|
Hydrogen pipeline network data |
Hydrogen demand¶
A description of the data included in the file oT_Data_DemandHydrogen.csv follows:
Identifier |
Identifier |
Identifier |
Header |
Description |
|
|---|---|---|---|---|---|
Period |
Scenario |
Load level |
Node |
Hydrogen demand of the node for each load level |
tH2/h |
Internally, all the values below if positive demand (or above if negative demand) 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
Hydrogen transmission pipeline network¶
A description of the circuit (initial node, final node, circuit) data included in the file oT_Data_NetworkHydrogen.csv follows:
Header |
Description |
|
|---|---|---|
InitialPeriod |
Initial period (year) when the unit is installed or can be installed, if candidate |
Year |
FinalPeriod |
Final period (year) when the unit is installed or can be installed, if candidate |
Year |
Length |
Pipeline length (only used for reporting purposes). If not defined, computed as 1.1 times the geographical distance |
km |
TTC |
Total transfer capacity (maximum permissible thermal load) in forward direction. Static pipeline rating |
tH2 |
TTCBck |
Total transfer capacity (maximum permissible thermal load) in backward direction. Static pipeline rating |
tH2 |
SecurityFactor |
Security factor to consider approximately N-1 contingencies. NTC = TTC x SecurityFactor |
p.u. |
FixedInvestmentCost |
Overnight investment (capital and fixed O&M) cost |
M€ |
FixedChargeRate |
Fixed-charge rate to annualize the overnight investment cost |
p.u. |
BinaryInvestment |
Binary pipeline investment decision |
Yes/No |
InvestmentLo |
Lower bound of investment decision |
p.u. |
InvestmentUp |
Upper bound of investment decision |
p.u. |
If there is no data for TTCBck, i.e., TTCBck is left empty or is equal to 0, it is substituted by the TTC in the code. Internally, all the TTC and TTCBck values below 2.5e-5 times the maximum system demand of each area will be converted into 0 by the model.
Those pipelines with fixed cost > 0 are considered candidate and can be installed or not.
If lower and upper bounds of investment decisions are very close (with a difference < 1e-3) to 0 or 1 are converted into 0 and 1.