This realization calibrates PE and FE parameters
| Description | Unit | A | |
|---|---|---|---|
| fm_dataglob (char, all_te) |
energy technology characteristics: investment costs, O&M costs, efficiency, learning rates … | x | |
| pm_data (all_regi, char, all_te) |
Large array for most technical parameters of technologies; more detail on the individual technical parameters can be found in the declaration of the set ‘char’ | x | |
| pm_fedemand (tall, all_regi, all_in) |
final energy demand | x | |
| pm_IO_trade (tall, all_regi, all_enty, char) |
Energy trade bounds based on IEA data. | x | |
| pm_secBioShare (ttot, all_regi, all_enty, emi_sectors) |
share of biomass per carrier for each sector | x | |
| sm_EJ_2_TWa | multiplicative factor to convert from EJ to TWa | x |
| Description | Unit | |
|---|---|---|
| pm_fuExtrOwnCons (all_regi, all_enty, all_enty) |
energy own consumption in the extraction sector with first enty being the output produced and the second enty being the input required | |
| pm_histfegrowth (all_regi, all_enty) |
average growth rate of fe use from 1995 to 2005 | |
| pm_IO_input (all_regi, all_enty, all_enty, all_te) |
Energy input based on IEA data | |
| pm_prodCouple (all_regi, all_enty, all_enty, all_te, all_enty) |
own consumption |
This realization used IEA data from 2014. The realization iea2014 serves to caliibrate the conversion efficiencies to be consistent with predefined dataset (here iea2014, but it is flexible for up-dates). The module realization starts with the final energy demands and then derives backwards what the secondary and primary energy demands have been. The file datainput.gms reads in the energy data related to each process. The process related inputs are contained in input/f04_IO_input.cs4r and the output are contained in input/f04_IO_output.cs4r. These files also contain all information about existing and statistically reported joint production processes. Based on these energy flows the corresponding conversion efficiencies that replicate these energy flows. The efficiencies are assigned to the parameter pm_data(,“eta”,).
This realization used IEA data from 2014. The realization iea2014 serves to caliibrate the conversion efficiencies to be consistent with predefined dataset (here iea2014, but it is flexible for up-dates). The module realization starts with the final energy demands and then derives backwards what the secondary and primary energy demands have been. The file datainput.gms reads in the energy data related to each process. The process related inputs are contained in input/f04_IO_input.cs4r and the output are contained in input/f04_IO_output.cs4r. These files also contain all information about existing and statistically reported joint production processes. Based on these energy flows the corresponding conversion efficiencies that replicate these energy flows. The efficiencies are assigned to the parameter pm_data(,“eta”,).
This realization used IEA data from 2014. The realization iea2014 serves to caliibrate the conversion efficiencies to be consistent with predefined dataset (here iea2014, but it is flexible for up-dates). The module realization starts with the final energy demands and then derives backwards what the secondary and primary energy demands have been. The file datainput.gms reads in the energy data related to each process. The process related inputs are contained in input/f04_IO_input.cs4r and the output are contained in input/f04_IO_output.cs4r. These files also contain all information about existing and statistically reported joint production processes. Based on these energy flows the corresponding conversion efficiencies that replicate these energy flows. The efficiencies are assigned to the parameter pm_data(,“eta”,).
Limitations There are no known limitations.
| Description | Unit | A | |
|---|---|---|---|
| f04_IO_input (tall, all_regi, all_enty, all_enty, all_te) |
Energy input based on IEA data | x | |
| f04_IO_output (tall, all_regi, all_enty, all_enty, all_te) |
Energy output based on IEA data | x | |
| p04_aux_data (all_regi, char, all_te) |
auxiliary parameter to store the initial mix0 and eta values for gas electricity before splitting it to ngcc and ngt (needed as long as calibration routine sets ngt to 0) | x | |
| p04_fuExtr (all_regi, all_enty) |
regional fuel extraction for the base year calibration | x | |
| p04_IO_output (all_regi, all_enty, all_enty, all_te) |
Energy output based on IEA data | x | |
| p04_IO_output_beforeFix (ttot, all_regi, all_enty, all_enty, all_te) |
Energy output based on IEA data as read in from input data before correction from FE trajectories | x | |
| p04_IO_output_beforeFix_Total (ttot, all_regi, all_enty) |
Energy output based on IEA data as read in from input data before correction from FE trajectories summed over SE | x | |
| p04_prodCoupleGlob (all_enty, all_enty, all_te, all_enty) |
global couple products | x | |
| p04_shareNGTinGas (all_regi) |
Share of ngt in electricity produced from gas | x | |
| p04_shOilGasEx (all_regi, all_enty) |
share of oil and gas extraction in all regions | x | |
| p04_x_enty2te_dyn04 (all_regi, all_enty, all_enty, all_te, all_te) |
parameter for the allocation of energy flow to technologies | x |
| description | |
|---|---|
| all_enty | all types of quantities |
| all_in | all inputs and outputs of the CES function |
| all_regi | all regions |
| all_te | all energy technologies, including from modules |
| bi2s(all_enty, all_enty, all_te, all_te) | match ESM fe for buildings and industry to stationary |
| char | characteristics of technologies |
| emi_sectors | comprehensive sector set used for more detailed emissions accounting (REMIND-EU) and for CH4 tier 1 scaling - potentially to be integrated with similar set all_exogEmi |
| en2en(all_enty, all_enty, all_te) | all energy conversion mappings |
| en2en2(all_enty, all_enty, all_te) | alias of en2en: all energy conversion mappings |
| enty(all_enty) | all types of quantities |
| entyFe(all_enty) | final energy types. |
| entyFe2Sector(all_enty, emi_sectors) | final energy (stationary and transportation) mapping to sectors (industry, buildings, transportation and cdr) |
| entyFeSec2entyFeDetail(all_enty, emi_sectors, all_enty) | final energy (stationary) and sector mapping to detailed final energy enty split by buildings and industry |
| entyFeTrans(all_enty) | final energy types from transport sector |
| entyPe(all_enty) | Primary energy types (PE) |
| entySe(all_enty) | secondary energy types |
| entySeBio(all_enty) | biomass secondary energy types |
| in(all_in) | All inputs and outputs of the CES function |
| in2enty(all_enty, all_enty, all_te, all_te) | match ESM fe to CES structure |
| in2enty2(all_enty, all_enty, all_te, all_te) | alias of in2enty |
| modules | all the available modules |
| pc2te(all_enty, all_enty, all_te, all_enty) | mapping for own consumption of technologies |
| pe2se(all_enty, all_enty, all_te) | map primary energy carriers to secondary |
| regi(all_regi) | all regions used in the solution process |
| se2fe(all_enty, all_enty, all_te) | map secondary energy to end-use energy using a technology |
| t(ttot) | modeling time, usually starting in 2005, but later for fixed delay runs |
| tall | time index |
| te(all_te) | energy technologies |
| ttot(tall) | time index with spin up |
| uet2fet(all_enty, all_enty, all_te, all_te) | match ESM fe for ue-items of the transport sector to final energy of the transport sector |
04_PE_FE_parameters, 05_initialCap, 24_trade, 32_power, 35_transport, 40_techpol, 70_water, core