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rptmain.rpt
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*++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
* Copyright (C) 2000-2024 Energy Technology Systems Analysis Programme (ETSAP)
* This file is part of the IEA-ETSAP TIMES model generator, licensed
* under the GNU General Public License v3.0 (see file NOTICE-GPLv3.txt).
*---------------------------------------------------------------
* RPTMAIN.RPT
*
* Output routine
* - creating flat dump for VEDA3 and paramaters for VEDA4
*GG* VEDABE 'V4' override to avoid PUT related code (e.g., File & SOLSUBV calls)
*---------------------------------------------------------------
* Output routine for IER extensions
*---------------------------------------------------------------
* - VAR_FLO/VAR_IRE are replaced by the parameters PAR_FLO/PAR_IRE
* which contain the values of the flow variables in the reduced model
* plus the recalculated values of substituted flows
* - calculation of annual cost terms
*
*-----------------------------------------------------------------------
* Declarations
PARAMETER PAR_CAPL(R,T,P);
PARAMETER PAR_CAPM(R,T,P);
PARAMETER PAR_PASTI(R,T,P);
PARAMETER PAR_CAPLO(R,T,P);
PARAMETER PAR_CAPUP(R,T,P);
PARAMETER PAR_NCAPL(R,ALLYEAR,P);
PARAMETER PAR_NCAPM(R,ALLYEAR,P);
PARAMETER PAR_ACTL(REG,ALLYEAR,ALLYEAR,PRC,ALL_TS);
PARAMETER PAR_ACTM(REG,ALLYEAR,ALLYEAR,PRC,ALL_TS);
PARAMETER PAR_COMPRDL(R,ALLYEAR,C,S);
PARAMETER PAR_COMPRDM(R,ALLYEAR,C,S);
PARAMETER PAR_COMNETL(R,ALLYEAR,C,S);
PARAMETER PAR_COMNETM(R,ALLYEAR,C,S);
PARAMETER PAR_COMBALEM(R,ALLYEAR,C,S);
PARAMETER PAR_COMBALGM(R,ALLYEAR,C,S);
PARAMETER PAR_PEAKM(R,ALLYEAR,COM_GRP,S);
PARAMETER PAR_UCLOM(UC_N,*,*,*);
PARAMETER PAR_UCUPM(UC_N,*,*,*);
PARAMETER PAR_UCFXM(UC_N,*,*,*);
PARAMETER F_IN(R,ALLYEAR,T,P,C,S);
PARAMETER F_OUT(R,ALLYEAR,T,P,C,S);
PARAMETER F_INOUT(R,ALLYEAR,T,P,C,IO);
PARAMETER F_INOUTS(R,ALLYEAR,T,P,C,TS,IO);
SET F_IOSET(R,ALLYEAR,T,P,C,TS,IO);
PARAMETERS
TOT_INV(R,ALLYEAR,CUR) 'Total annual disocunted investment costs' //
TOT_DEC(R,ALLYEAR,CUR) 'Total annual disocunted decommissioning costs' //
TOT_FIX(R,ALLYEAR,CUR) 'Total annual disocunted FOM costs' //
TOT_SAL(R,ALLYEAR,CUR) 'Total annual disocunted salvage value' //
TOT_LAT(R,ALLYEAR,CUR) 'Total annual disocunted late costs' //
TOT_ACT(R,ALLYEAR,CUR) 'Total annual disocunted variable costs' //
TOT_COM(R,ALLYEAR,CUR) 'Total annual disocunted commodity costs' //
TOT_FLO(R,ALLYEAR,CUR) 'Total annual disocunted flow costs' //
TOT_BLE(R,ALLYEAR,CUR) 'Total annual disocunted blending costs' //
TOT_OBJ(R,ALLYEAR,CUR) 'Annual discounted objective value ' //;
*-----------------------------------------------------------------------
* Calculation of solution values for (due to reduction) substituted flows
*------------------------------------------------------------------------
$ BATINCLUDE sol_flo.red PAR_FLO '' .L
$ BATINCLUDE sol_flo.red PAR_FLO M .M
* IRE auxiliary flows summed up from all IE flows
LOOP((RPC_IRE(R,P,COM,IE),RPCS_VAR(R,P,COM,TS)),F_IOSET(RTP_VINTYR(R,V,T,P),C,TS,IO)$IRE_FLOSUM(R,T,P,COM,TS,IE,C,IO) = RC(R,C));
$ BATINCLUDE sol_ire.rpt
*---------------------------------------------------------------
* Calculation of annual cost terms
*---------------------------------------------------------------
$ BATINCLUDE eqobjinv.rpt
$ BATINCLUDE eqobjfix.rpt mod
$ BATINCLUDE eqobsalv.rpt rpt
$ BATINCLUDE eqobjvar.rpt mod
$ BATINCLUDE eqobjels.rpt PAR_OBJELS(R,Y_EOH,C,CUR) Y_EOH OBJ_DISC(R,Y_EOH,CUR)*
*------------------------------------------------------------------------
* Include explicit EPS values for zero flows
*------------------------------------------------------------------------
$IF NOT %SUPZERO%==YES
PAR_FLO(RTP_VINTYR(R,V,T,P),C,S)$(RTPCS_VARF(R,T,P,C,S)*RP_FLO(R,P)*(NOT RPC_NOFLO(R,P,C))) $= EPS$(NOT PAR_FLO(R,V,T,P,C,S));
;
$IF NOT %SUPZERO%==YES
PAR_IRE(RTP_VINTYR(R,V,T,P),C,TS,IMPEXP)$(RTPCS_VARF(R,T,P,C,TS)$RPC_IRE(R,P,C,IMPEXP)) $= EPS$(NOT PAR_IRE(R,V,T,P,C,TS,IMPEXP));
;
*---------------------------------------------------------------------
* Annual discounted objective values by cost type(INV, FIX, VAR etc.)
*---------------------------------------------------------------------
* Total investment costs
TOT_INV(R,ALLYEAR,CUR)=SUM(RTP(R,V,P),PAR_OBJINV(R,V,ALLYEAR,P,CUR));
* Total decommissioning costs
TOT_DEC(R,ALLYEAR,CUR)=SUM(RTP(R,V,P),PAR_OBJDEC(R,V,ALLYEAR,P,CUR));
* Total fix costs
TOT_FIX(R,ALLYEAR,CUR)=SUM(RTP(R,V,P),PAR_OBJFIX(R,V,ALLYEAR,P,CUR));
* Total salvage value
TOT_SAL(R,V,CUR)=-SUM(P,PAR_OBJSAL(R,V,P,CUR));
* Total late revenues
TOT_LAT(R,ALLYEAR,CUR)=-SUM(P,PAR_OBJLAT(R,ALLYEAR,P,CUR));
* Total variable costs
TOT_ACT(R,ALLYEAR,CUR)=SUM((RTP_VINTYR(R,V,T,P),TS)$PERIODYR(T,ALLYEAR),PAR_OBJACT(R,V,ALLYEAR,P,TS,CUR));
* Total flow related costs
TOT_FLO(R,ALLYEAR,CUR) = SUM((RTP_VINTYR(R,V,T,P),C,TS)$PERIODYR(T,ALLYEAR),PAR_OBJFLO(R,V,ALLYEAR,P,C,TS,CUR));
* Total commodity related costs
TOT_COM(R,ALLYEAR,CUR)=SUM((C,TS),PAR_OBJCOM(R,ALLYEAR,C,TS,CUR));
* Total blending related costs
TOT_BLE(R,ALLYEAR,CUR)=SUM((C),PAR_OBJBLE(R,ALLYEAR,C,CUR));
* Total yearly objective value
TOT_OBJ(R,ALLYEAR,CUR) = TOT_INV(R,ALLYEAR,CUR) +
TOT_DEC(R,ALLYEAR,CUR) +
TOT_FIX(R,ALLYEAR,CUR) +
TOT_SAL(R,ALLYEAR,CUR) +
TOT_LAT(R,ALLYEAR,CUR) +
TOT_ACT(R,ALLYEAR,CUR) +
TOT_FLO(R,ALLYEAR,CUR) +
TOT_COM(R,ALLYEAR,CUR) +
TOT_BLE(R,ALLYEAR,CUR);
**Aggregate Undiscounted Costs w/out CUR
PARAMETER TOT_OBJV(R,ALLYEAR) //;
TOT_OBJV(R,T) $= SUM(CUR,TOT_OBJ(R,T,CUR)/OBJ_DISC(R,T,CUR));
* Discounted objective value by region
PARAMETER REG_OBJ(REG) //;
REG_OBJ(R) = SUM((CUR,ALLYEAR),TOT_OBJ(R,ALLYEAR,CUR));
*---------------------------------------------------------------------
* calculate discounting for the period
PARAMETER VDA_DISC(R,ALLYEAR) //;
* Refined undiscounting method (MARKAL way not sufficient for TIMES)
*VDA_DISC(R,T) = SUM(CUR,OBJ_DISC(R,T,CUR))*D(T);
LOOP(RDCUR(R,CUR), VDA_DISC(R,T) = SUM(PERIODYR(T,Y_EOH),OBJ_DISC(R,Y_EOH,CUR)));
* Scenario index not supported in current version, use 1
SOW('1') = YES;
*---------------------------------------------------------------------
* Output of VAR_ACT
*---------------------------------------------------------------------
PAR_ACTL(RTP_VINTYR(R,V,T,P),S)$PRC_TS(R,P,S) = EPS;
PAR_ACTL(R,V,T,P,S) $= VAR_ACT.L(R,V,T,P,S);
PAR_ACTM(R,V,T,P,S)$VAR_ACT.M(R,V,T,P,S) = VAR_ACT.M(R,V,T,P,S)/VDA_DISC(R,T);
*---------------------------------------------------------------------
* Output of VAR_CAP
*---------------------------------------------------------------------
RTP_CAPYR(RTP_CPTYR(R,TT,T,P))$VAR_NCAP.L(R,TT,P) = YES;
RTP_CAPYR(RTP_CPTYR(R,PYR,T,P))$NCAP_PASTI(R,PYR,P) = YES;
PAR_PASTI(RTP(R,T,P)) = SUM(RTP_CAPYR(R,PYR,T,P),COEF_CPT(R,PYR,T,P)*NCAP_PASTI(R,PYR,P));
PAR_CAPL(RTP(R,T,P)) = SUM(RTP_CAPYR(R,TT,T,P), COEF_CPT(R,TT,T,P) *VAR_NCAP.L(R,TT,P)) + PAR_PASTI(R,T,P);
PAR_CAPM(RTP(R,T,P)) $= VAR_CAP.M(R,T,P)*(1/VDA_DISC(R,T));
PAR_CAPLO(RTP(R,T,P)) $= CAP_BND(R,T,P,'LO');
PAR_CAPUP(RTP(R,T,P))$(CAP_BND(R,T,P,'UP') NE INF) $= CAP_BND(R,T,P,'UP');
PAR_NCAPL(R,V,P) $= VAR_NCAP.L(R,V,P) ;
* [UR]: undiscounting of dual variable of VAR_NCAP
PAR_NCAPM(R,T,P)$(VAR_NCAP.M(R,T,P)*COEF_OBJINV(R,T,P)) = VAR_NCAP.M(R,T,P)/COEF_OBJINV(R,T,P);
*---------------------------------------------------------------------
* Output of VAR_FLO
* - split by in/out
*---------------------------------------------------------------------
* emission tied to CAP/INV
F_INOUT(RTP_VINTYR(R,V,T,P),C,'IN')$RPC_CAPFLO(R,T,P,C) = COEF_CPT(R,V,T,P) * NCAP_COM(R,V,P,C,'IN') * (VAR_NCAP.L(R,V,P)$T(V) + NCAP_PASTI(R,V,P)$PASTYEAR(V)) +
(COEF_ICOM(R,V,T,P,C) * (VAR_NCAP.L(R,V,P)$T(V) + NCAP_PASTI(R,V,P)$PASTYEAR(V)));
F_INOUT(RTP_VINTYR(R,V,T,P),C,'OUT')$RPC_CAPFLO(R,T,P,C) = COEF_CPT(R,V,T,P) * NCAP_COM(R,V,P,C,'OUT') * (VAR_NCAP.L(R,V,P)$T(V) + NCAP_PASTI(R,V,P)$PASTYEAR(V)) +
(COEF_OCOM(R,V,T,P,C) * (VAR_NCAP.L(R,V,P)$T(V) + NCAP_PASTI(R,V,P)$PASTYEAR(V)));
* Blending flows *** PENDING!!! Code below from EQCOMBAL ***
*PARAMETER F_BLND(R,T,C,TS,IO) //;
* SUM(OPR$BLE_OPR(R,C,OPR),
* RTCS_TSFR(R,T,C,S,'ANNUAL') * BLE_BAL(R,T,C,OPR) * VAR_BLND(R,T,C,OPR)
* ) +
* emissions due to blending operations
* SUM(BLE_ENV(R,COM,BLE,OPR),
* ENV_BL(R,COM,BLE,OPR,T) * VAR_BLND(R,T,BLE,OPR)
* ) +
*---------------------------------------------------------------------
* Process flows
*---------------------------------------------------------------------
* Flow by IN/OUT
* main flows & emissions
F_IN(R,V,T,P,C,S)$TOP(R,P,C,'IN') $= PAR_FLO(R,V,T,P,C,S);
F_OUT(R,V,T,P,C,S)$TOP(R,P,C,'OUT') $= PAR_FLO(R,V,T,P,C,S);
* IRE flows
* [UR] maybe exports as negativ values for net imports in primary energy balance ?
F_IN(R,V,T,P,C,S) $= PAR_IRE(R,V,T,P,C,S,'EXP');
F_OUT(R,V,T,P,C,S) $= PAR_IRE(R,V,T,P,C,S,'IMP');
* Aux flows & emissions tied to INV/CAP
F_IN(R,V,T,P,C,'ANNUAL')$F_INOUT(R,V,T,P,C,'IN') = F_IN(R,V,T,P,C,'ANNUAL')+F_INOUT(R,V,T,P,C,'IN');
F_OUT(R,V,T,P,C,'ANNUAL')$F_INOUT(R,V,T,P,C,'OUT') = F_OUT(R,V,T,P,C,'ANNUAL')+F_INOUT(R,V,T,P,C,'OUT');
* IRE Aux flows & emissions
F_IN(R,V,T,P,C,S)$F_INOUTS(R,V,T,P,C,S,'IN') = F_IN(R,V,T,P,C,S)+F_INOUTS(R,V,T,P,C,S,'IN');
F_OUT(R,V,T,P,C,S)$F_INOUTS(R,V,T,P,C,S,'OUT') = F_OUT(R,V,T,P,C,S)+F_INOUTS(R,V,T,P,C,S,'OUT');
* Storage in/output flows
F_IN(R,V,T,P,C,S)$RPCS_VAR(R,P,C,S) $= VAR_SIN.L(R,V,T,P,C,S);
F_OUT(R,V,T,P,C,S)$RPCS_VAR(R,P,C,S)$= VAR_SOUT.L(R,V,T,P,C,S)*STG_EFF(R,V,P);
*---------------------------------------------------------------------
* Annual undiscounted costs by process/commodity w/out CUR
*---------------------------------------------------------------------
PARAMETER CST_INVV(R,ALLYEAR,ALLYEAR,P) //;
PARAMETER CST_DECV(R,ALLYEAR,ALLYEAR,P) //;
PARAMETER CST_FIXV(R,ALLYEAR,ALLYEAR,P) //;
PARAMETER CST_SALV(R,ALLYEAR,P) //;
PARAMETER CST_LATV(R,ALLYEAR,P) //;
PARAMETER CST_ACTV(R,ALLYEAR,ALLYEAR,P,TS) //;
PARAMETER CST_FLOV(R,ALLYEAR,ALLYEAR,P,C,TS) //;
PARAMETER CST_COMV(R,ALLYEAR,C,TS) //;
PARAMETER CST_ELSV(R,ALLYEAR,C) //;
LOOP(CUR,
CST_INVV(RTP_CPTYR(R,V,T,P)) $= PAR_OBJINV(R,V,T,P,CUR)*(1/OBJ_DISC(R,T,CUR));
CST_DECV(RTP_CPTYR(R,V,T,P)) $= PAR_OBJDEC(R,V,T,P,CUR)*(1/OBJ_DISC(R,T,CUR));
CST_SALV(R,V,P) $= PAR_OBJSAL(R,V,P,CUR);
CST_LATV(RTP(R,T,P)) $= PAR_OBJLAT(R,T,P,CUR)*(1/OBJ_DISC(R,T,CUR));
CST_FIXV(RTP_CPTYR(R,V,T,P)) $= PAR_OBJFIX(R,V,T,P,CUR)*(1/OBJ_DISC(R,T,CUR));
CST_ACTV(RTP_VINTYR(R,V,T,P),TS) $= PAR_OBJACT(R,V,T,P,TS,CUR)*(1/OBJ_DISC(R,T,CUR));
CST_ELSV(RTC(R,T,C)) $= PAR_OBJELS(R,T,C,CUR)*(1/OBJ_DISC(R,T,CUR));
CST_FLOV(RTP_VINTYR(R,V,T,P),C,S) $= PAR_OBJFLO(R,V,T,P,C,S,CUR)*(1/OBJ_DISC(R,T,CUR));
CST_COMV(RTC(R,T,C),TS) $= PAR_OBJCOM(R,T,C,TS,CUR)*(1/OBJ_DISC(R,T,CUR));
);
*--------------------------------------------------------------------------
* Production (PRD) and Difference between production and consumption (NET)
*--------------------------------------------------------------------------
PAR_COMPRDL(R,T,C,S) $= VAR_COMPRD.L(R,T,C,S);
PAR_COMPRDM(R,T,C,S) $= VAR_COMPRD.M(R,T,C,S)*(1/VDA_DISC(R,T));
PAR_COMNETL(R,T,C,S) $= VAR_COMNET.L(R,T,C,S);
PAR_COMNETM(R,T,C,S) $= VAR_COMNET.M(R,T,C,S)*(1/VDA_DISC(R,T));
*--------------------------------------------------------------------------
* Undiscounted annual shadow price of commodity balance and peaking equation
*--------------------------------------------------------------------------
PAR_COMBALEM(R,T,C,S) $= EQE_COMBAL.M(R,T,C,S)*(1/VDA_DISC(R,T));
PAR_COMBALGM(R,T,C,S) $= EQG_COMBAL.M(R,T,C,S)*(1/VDA_DISC(R,T));
PAR_PEAKM(R,T,CG,S) $= EQ_PEAK.M(R,T,CG,S)*(1/VDA_DISC(R,T));
*--------------------------------------------------------------------------
* Shadow prices of user constraints
*--------------------------------------------------------------------------
* Note: undiscounting only done for user constraints having region and period as index
$IF '%VAR_UC%'==YES $GOTO UC_VAR
$ BATINCLUDE par_uc.rpt FXM EQE
$ BATINCLUDE par_uc.rpt LOM EQG
$ BATINCLUDE par_uc.rpt UPM EQL
$GOTO UC_DONE
$LABEL UC_VAR
PAR_UCFXM(UC_N,'NONE','NONE','NONE') $= VAR_UC.M(UC_N);
PAR_UCFXM(UC_N,R,'NONE','NONE') $= VAR_UCR.M(UC_N,R);
PAR_UCFXM(UC_N,'NONE',T,'NONE') $= VAR_UCT.M(UC_N,T);
PAR_UCFXM(UC_N,R,T,'NONE') $= VAR_UCRT.M(UC_N,R,T)*(1/VDA_DISC(R,T));
PAR_UCFXM(UC_N,'NONE',T,S) $= VAR_UCTS.M(UC_N,T,S);
PAR_UCFXM(UC_N,R,T,S) $= VAR_UCRTS.M(UC_N,R,T,S)*(1/VDA_DISC(R,T));
$LABEL UC_DONE
OPTION CLEAR = F_INOUT;
OPTION CLEAR = F_INOUTS;
OPTION CLEAR = F_IOSET;
* Add regional total discounted cost parameter
PARAMETER REG_WOBJ(REG,ITEM,CUR) //;
REG_WOBJ(R,'INV',CUR) = SUM(OBV,SUM_OBJ('OBJINV',OBV)*VAR_OBJ.L(R,OBV,CUR))-VAR_OBJ.L(R,'OBJSAL',CUR);
REG_WOBJ(R,'FIX',CUR) = SUM(OBV,SUM_OBJ('OBJFIX',OBV)*VAR_OBJ.L(R,OBV,CUR));
REG_WOBJ(R,'VAR',CUR) = SUM(OBV,SUM_OBJ('OBJVAR',OBV)*VAR_OBJ.L(R,OBV,CUR));
REG_WOBJ(R,'ELS',CUR) = EPS
$IF %TIMESED% == YES +VAR_OBJELS.L(R,'LO',CUR)-VAR_OBJELS.L(R,'UP',CUR)
;