Create sample.zmpl

2025-12-08 20:38:47 +00:00 · 2014-06-02 15:16:00 -07:00
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 # Mini Manitoba Hydro LP Model
 # Written for zimpl 3.0.0a
 # Licensed under the MIT license
 # Developed for fun using publicly available sources.
 # This software comes with no guarantees and no claims that it is fit for any purpose.
 # john howard, 1 Dec 2009
 # Inflows:
 #  CR churchill river
 #  LT lower nelson tribs
 #  SL south indian lake
 #  RR red river
 #  WR winnipeg river
 #
 # Major Storages:
 #  LW lake winnipeg
 #  CL cedar lake
 #
 # Controlled Channels:
 #  MF missi falls
 #  NT notigi
 #  EC east channel
 #  WC west channel
 #
 # Generation Projects:
 #  GR grand rapids
 #  JP jenpeg
 #  KE kelsey
 #  LN lower nelson projects
 # variables and constraints are named the following way:
 # Type Subtype 2LetterName Kind Modifier
 # (v|k) [c] (..) (q|i|o|p|v|e|s|hk|ss|tw|mb|rc|os|ur) [ Start | End | Max | Min | Adj | Fact | Offset ]
 param kTS := 662;
 set sTime := { 1 .. kTS };
 # for 5 day averaging requires indices spaced 3 apart
 set sTime5 := { <t> in sTime with t < (kTS - 1) and t mod 3 == 0 };
 param kCMSd2KCFSdFact := 35.315 / 1000;
 # column 8 is month
 param vMONTH[ sTime ] := read "historical.csv" as "8n" skip 1;
 set sMonth := { 1 .. 12 };
 #########################
 ### Inital Conditions ###
 # South Indian Lake
 param kSLeMin := 840.0;
 param kSLeMax := 847.9;
 param kSLssFactor := 283.7;
 param kSLvMax := (kSLeMax - kSLeMin) * kSLssFactor;
 # Grand Rapids Pond (Cedar Lake)
 param kGReMin := 830.0;
 param kGReMax := 841.5;
 param kGRssFactor := 330.9;
 param kGRvMax := (kGReMax - kGReMin) * kGRssFactor;
 # Lake Winnipeg
 param kLWeMin := 709.0;
 param kLWeMax := 714.75;
 param kLWssFactor := 3040.0;
 param kLWvMax := (kLWeMax - kLWeMin) * kLWssFactor;
 # Kelsey Pond
 param kKEeMin := 0.0;
 param kKEeMax := 0.1; # as modelled
 param kKEssFactor := 902.0;
 param kKEvMax := (kKEeMax - kKEeMin) * kKEssFactor;
 # Storage at aggregate Lower Nelson Projects
 param kLNeMin := 0.0;
 param kLNeMax := 3.0; # as modelled
 param kLNssFactor := 200.0;
 param kLNvMax := (kLNeMax - kLNeMin) * kLNssFactor;
 param kLNvStart := kLNvMax / 2;
 ####################################################################
 ### Churchill River through South Indian Lake and Notigi Control ###
 param kNToMin := 15; # control discharge limits (KCFS)
 param kNToMax := 35;
 param kMFoMin := 0; # control discharge limits (KCFS)
 param kMFoMax := 10; # as modelled
 param kMFoFact := 0.001; # adjustments (calibrated for 92-94 peroid)
 var vMFo[ sTime ] >= 1 <= kMFoMax; # Missi Falls acts as spill
 var vNTo[ sTime ] >= kNToMin <= kNToMax;
 var vSLv[ sTime ] >= 0 <= kSLvMax;
 # 2nd column for Churchill River
 param vCRq[ sTime ] := read "historical.csv" as "2n" skip 1;
 param kSLiAdj := 2.3; # adjustments (calibrated for 92-94 peroid)
 param kSLvStart := kSLvMax / 2;
 # refill
 subto kcSLvEnd: vSLv[ kTS ] >= kSLvStart;
 # change-in-storage + outflow == inflow
 subto vcSLmb:
 	forall <t> in sTime do
 		if ( t == 1 ) then	vSLv[ 1 ] - kSLvStart + vMFo[ 1 ] +  vNTo[ 1 ]
 		else				vSLv[ t ] - vSLv[ t - 1 ] + vMFo[ t ] +  vNTo[ t ]
 		end
 		== kCMSd2KCFSdFact * vCRq[ t ] + kSLiAdj;
 # Notigi within-week outflow shaping
 param kNTosFact := 0; # as modelled
 subto vcNTosA: forall<t> in sTime5 do vNTo[ t - 2 ] >= vNTo[ t ] - kNTosFact;
 subto vcNTosB: forall<t> in sTime5 do vNTo[ t - 2 ] <= vNTo[ t ] + kNTosFact;
 subto vcNTosC: forall<t> in sTime5 do vNTo[ t - 1 ] >= vNTo[ t ] - kNTosFact;
 subto vcNTosD: forall<t> in sTime5 do vNTo[ t - 1 ] <= vNTo[ t ] + kNTosFact;
 subto vcNTosE: forall<t> in sTime5 do vNTo[ t + 1 ] >= vNTo[ t ] - kNTosFact;
 subto vcNTosF: forall<t> in sTime5 do vNTo[ t + 1 ] <= vNTo[ t ] + kNTosFact;
 subto vcNTosG: forall<t> in sTime5 do vNTo[ t + 2 ] >= vNTo[ t ] - kNTosFact;
 subto vcNTosH: forall<t> in sTime5 do vNTo[ t + 2 ] <= vNTo[ t ] + kNTosFact;
 ###########################################################
 ### Sask River into Cedar Lake and through Grand Rapids ###
 param kGRoMin := 5; # plant/control discharge limits (KCFS)
 param kGRoMax := 53;
 param kGRsMin := 0;
 param kGRsMax := 40;
 param kGRpMax := 472; # generation limits (MW)
 var vGRv[ sTime ] >= 0 <= kGRvMax;
 var vGRs[ sTime ] >= kGRsMin <= kGRsMax;
 var vGRo[ sTime ] >= kGRoMin <= kGRoMax;
 var vGRp[ sTime ] >= 0 <= kGRpMax;
 # 1st column for Sask River
 param vSKRq[ sTime ] := read "historical.csv" as "1n" skip 1;
 param kGRhk := 9.2; # plant HK factors (MW/KCFS)
 param kGRiAdj := -0.6; # adjustments (calibrated for 92-94 peroid)
 param kGRvStart := kGRvMax / 2;
 # refill
 subto kcGRvEnd: vGRv[ kTS ] >= kGRvStart;
 # change-in-storage + outflow == inflow
 subto vcGRmb:
 	forall <t> in sTime do
 		if ( t == 1 ) then	vGRv[ 1 ] - kGRvStart + vGRo[ 1 ] + vGRs[ 1 ]
 		else				vGRv[ t ] - vGRv[ t - 1 ] + vGRo[ t ] + vGRs[ t ]
 		end
 		== kCMSd2KCFSdFact * vSKRq[ t ] + kGRiAdj;
 # compute power from discharge
 subto vcGRp:
 	forall <t> in sTime do
 		vGRp[ t ] == kGRhk * vGRo[ t ];
 # Grand Rapids within-week outflow shaping
 param kGRosFact := 10; # as modelled
 subto vcGRosA: forall<t> in sTime5 do vGRo[ t - 2 ] >= vGRo[ t ] - kGRosFact;
 subto vcGRosB: forall<t> in sTime5 do vGRo[ t - 2 ] <= vGRo[ t ] + kGRosFact;
 subto vcGRosC: forall<t> in sTime5 do vGRo[ t - 1 ] >= vGRo[ t ] - kGRosFact;
 subto vcGRosD: forall<t> in sTime5 do vGRo[ t - 1 ] <= vGRo[ t ] + kGRosFact;
 subto vcGRosE: forall<t> in sTime5 do vGRo[ t + 1 ] >= vGRo[ t ] - kGRosFact;
 subto vcGRosF: forall<t> in sTime5 do vGRo[ t + 1 ] <= vGRo[ t ] + kGRosFact;
 subto vcGRosG: forall<t> in sTime5 do vGRo[ t + 2 ] >= vGRo[ t ] - kGRosFact;
 subto vcGRosH: forall<t> in sTime5 do vGRo[ t + 2 ] <= vGRo[ t ] + kGRosFact;
 ##############################################################################
 ### Lake Winnipeg Storage as operated by JENPEG and effect of Each Channel ###
 param kJPoMin := 0; # plant/control discharge limits (KCFS)
 param kJPoMax := 93;
 param kJPsMin := 0; # plant/control discharge limits (KCFS)
 param kJPsMax := 9e9; # as modelled
 param kJPpMax := 97; # generation limits (MW)
 var vLWv[ sTime ] >= 0 <= kLWvMax;
 var vECo[ sTime ] >= 0; # upper bound determined by rating curve
 var vJPo[ sTime ] >= kJPoMin <= kJPoMax;
 var vJPs[ sTime ] >= kJPsMin <= kJPsMax;
 var vJPp[ sTime ] >= 0 <= kJPpMax;
 # 3rd column for Red River and 4th column for Winnipeg River
 param vRRq[ sTime ] := read "historical.csv" as "3n" skip 1;
 param vWRq[ sTime ] := read "historical.csv" as "4n" skip 1;
 param kLWiAdj := 11.7; # adjustments (calibrated for 92-94 peroid)
 param kLWvStart := kLWvMax / 2;
 param kJPhk := 1; # plant HK factors (MW/KCFS)
 param kJPoNovMaxFact := 0; # curves
 param kJPoNovMaxOffset := 0;
 param kJPtwFact := 0; # TODO
 param kJPtwOffset := 0;
 # refill
 subto kcLWvEnd: vLWv[ kTS ] >= kLWvStart;
 # change-in-storage + outflow == inflow
 subto vcLWmb:
 	forall <t> in sTime do
 		if ( t == 1 ) then	vLWv[ 1 ] - kLWvStart + vJPo[ 1 ] + vJPs[ 1 ] + vECo[ 1 ]
 		else				vLWv[ t ] - vLWv[ t - 1 ] + vJPo[ t ] + vJPs[ t ] + vECo[ t ]
 		end
 		== kCMSd2KCFSdFact * vRRq[ t ] + kCMSd2KCFSdFact * vWRq[ t ] + vGRo[ t ] + vGRs[ t ] + kLWiAdj;
 # compute power from discharge
 subto vcJPp:
 	forall <t> in sTime do
 		vJPp[ t ] == kJPhk * vJPo[ t ];
 # West Channel Max Discharge
 param vWCoMax[ sMonth ] := <1> 8.6440678, <2> 7.79661017, <3> 7.11864407, <4> 6.61016949, <11> 10.3389831, <12> 9.3220339 default 12.5423729;
 subto vJPoA:
 	forall <t,m> in sTime cross sMonth with m == vMONTH[ t ] do
 		vJPo[ t ] <= vLWv[ t ] * vWCoMax[ m ] / kLWssFactor;
 # East Channel Discharge
 subto vcECo:
 	forall <t> in sTime do
 		vECo[ t ] == vLWv[ t ] * 4.67463938 / kLWssFactor; # convert q/ft (from historical 92-94 period data) to q/v
 # Jenpeg within-week outflow shaping
 param kJPosFact := 2; # as modelled
 subto vcJPosA: forall<t> in sTime5 do vJPo[ t - 2 ] >= vJPo[ t ] - kJPosFact;
 subto vcJPosB: forall<t> in sTime5 do vJPo[ t - 2 ] <= vJPo[ t ] + kJPosFact;
 subto vcJPosC: forall<t> in sTime5 do vJPo[ t - 1 ] >= vJPo[ t ] - kJPosFact;
 subto vcJPosD: forall<t> in sTime5 do vJPo[ t - 1 ] <= vJPo[ t ] + kJPosFact;
 subto vcJPosE: forall<t> in sTime5 do vJPo[ t + 1 ] >= vJPo[ t ] - kJPosFact;
 subto vcJPosF: forall<t> in sTime5 do vJPo[ t + 1 ] <= vJPo[ t ] + kJPosFact;
 subto vcJPosG: forall<t> in sTime5 do vJPo[ t + 2 ] >= vJPo[ t ] - kJPosFact;
 subto vcJPosH: forall<t> in sTime5 do vJPo[ t + 2 ] <= vJPo[ t ] + kJPosFact;
 # Jenpeg intra-week shaping
 subto vcJPosI: forall<t> in sTime5 without { kTS - 2 } do vJPo[ t + 3 ] >= vJPo[ t ] - kJPosFact * 2;
 subto vcJPosJ: forall<t> in sTime5 without { kTS - 2 } do vJPo[ t + 3 ] <= vJPo[ t ] + kJPosFact * 2;
 #########################
 ### Kelsey Operations ###
 param kKEoMin := 0; # plant/control discharge limits (KCFS)
 param kKEoMax := 55.4;
 param kKEsMin := 0; # as modelled
 param kKEsMax := 9e9; # as modelled
 param kKEpMax := 211; # generation limits (MW)
 var vKEv[ sTime ] >= 0 <= kKEvMax;
 var vKEs[ sTime ] >= kKEsMin <= kKEsMax;
 var vKEo[ sTime ] >= kKEoMin <= kKEoMax;
 var vKEp[ sTime ] >= 0 <= kKEpMax;
 # 5th column for Gunisao River
 param vGUNq[ sTime ] := read "historical.csv" as "5n" skip 1;
 param kKEhk := 3.8; # plant HK factors (MW/KCFS)
 param kKEiFact := 1; # adjustments (calibrated for 92-94 peroid)
 param kKEtwFact := 0; # curves
 param kKEtwOffset := 0;
 param kKEiAdj := 3; # adjustments (calibrated for 92-94 peroid)
 param kKEvStart := kKEvMax / 2;
 # refill
 subto kcKEvEnd: vKEv[ kTS ] >= kKEvStart;
 # change-in-storage + outflow == inflow
 subto vcKEmb:
 	forall <t> in sTime do
 		if ( t == 1 ) then	vKEv[ 1 ] - kKEvStart + vKEo[ 1 ] + vKEs[ 1 ]
 		else				vKEv[ t ] - vKEv[ t - 1 ] + vKEo[ t ] + vKEs[ t ]
 		end
 		== kKEiFact * kCMSd2KCFSdFact * vGUNq[ t ] + kKEiAdj + vECo[ t ] +	vJPo[ t ] + vJPs[ t ];
 # compute power from discharge
 subto vcKEp:
 	forall <t> in sTime do
 		vKEp[ t ] == kKEhk * vKEo[ t ];
 #########################################################################
 ### Lower Nelson Operations with inflows from Upper Nelson and Notigi ###
 param kLNoMin := 0; # plant/control discharge limits (KCFS)
 param kLNoMax := 165.7;
 param kLNsMin := 0; # plant/control discharge limits (KCFS)
 param kLNsMax := 150; # kpill limits (KCFS)
 param kLNpMax := 3583; # generation limits (MW)
 var vLNv[ sTime ] >= 0 <= kLNvMax;
 var vLNs[ sTime ] >= kLNsMin <= kLNsMax;
 var vLNo[ sTime ] >= kLNoMin <= kLNoMax;
 var vLNp[ sTime ] >= 0 <= kLNpMax;
 # 6th column for Lower Nelson Tribs
 param vLTq[ sTime ] := read "historical.csv" as "6n" skip 1;
 param kLNhk := 21.7; # plant HK factors (MW/KCFS)
 param kLNiAdj := 5; # adjustments (calibrated for 92-94 peroid)
 param kLTiFact := 3; # adjustments (calibrated for 92-94 peroid)
 # refill
 subto kcLNvEnd: vLNv[ kTS ] >= kLNvStart;
 # Routed discharges from Notigi to Lower Nelson
 var vNTor[ sTime ] >= 0;
 set sUIR := { 1, 2, 3, 4 };
 param kNTur[ sUIR ] := <1> 0.0, <2> 0.05, <3> 0.80, <4> 0.15; # as modelled
 subto vcNTorA:
 	forall <t> in sTime without { 1, 2, 3 } do
 		vNTor[ t ] == vNTo[ t - 0 ] * kNTur[ 1 ] + vNTo[ t - 1 ] * kNTur[ 2 ] + vNTo[ t - 2 ] * kNTur[ 3 ] + vNTo[ t - 3 ] * kNTur[ 4 ];
 # change-in-storage + outflow == inflow
 subto vcLNmb:
 	forall <t> in sTime do
 		if ( t == 1 ) then	vLNv[ 1 ] - kLNvStart + vLNo[ 1 ] + vLNs[ 1 ]
 		else				vLNv[ t ] - vLNv[ t - 1 ] + vLNo[ t ] + vLNs[ t ]
 		end
 		== kLTiFact * kCMSd2KCFSdFact * vLTq[ t ] + kLNiAdj + vNTor[ t ] + vKEo[ t ] + vKEs[ t ];
 # compute power from discharge
 subto vcLNp:
 	forall <t> in sTime do
 		vLNp[ t ] == kLNhk * vLNo[ t ];
 # Lowern Nelson within-week outflow shaping
 param kLNosFact := 10; # as modelled
 subto vcLNosA: forall<t> in sTime5 do vLNo[ t - 2 ] >= vLNo[ t ] - kLNosFact;
 subto vcLNosB: forall<t> in sTime5 do vLNo[ t - 2 ] <= vLNo[ t ] + kLNosFact;
 subto vcLNosC: forall<t> in sTime5 do vLNo[ t - 1 ] >= vLNo[ t ] - kLNosFact;
 subto vcLNosD: forall<t> in sTime5 do vLNo[ t - 1 ] <= vLNo[ t ] + kLNosFact;
 subto vcLNosE: forall<t> in sTime5 do vLNo[ t + 1 ] >= vLNo[ t ] - kLNosFact;
 subto vcLNosF: forall<t> in sTime5 do vLNo[ t + 1 ] <= vLNo[ t ] + kLNosFact;
 subto vcLNosG: forall<t> in sTime5 do vLNo[ t + 2 ] >= vLNo[ t ] - kLNosFact;
 subto vcLNosH: forall<t> in sTime5 do vLNo[ t + 2 ] <= vLNo[ t ] + kLNosFact;
 # Lowern Nelson inter-week outflow shaping
 subto vcLNosI: forall<t> in sTime5 without { kTS - 2 } do vLNo[ t + 3 ] >= vLNo[ t ] - kLNosFact * 2;
 subto vcLNosJ: forall<t> in sTime5 without { kTS - 2 } do vLNo[ t + 3 ] <= vLNo[ t ] + kLNosFact * 2;
 ########################################################
 # 7th column for Load
 param vLOAD[ sTime ] := read "historical.csv" as "7n" skip 1;
 var sLOAD >= 0;
 subto vcLOAD:
 	forall <t> in sTime do
 		vGRp[ t ] + vJPp[ t ] + vKEp[ t ] + vLNp[ t ] >= vLOAD[ t ];
 minimize kSPILL:
 	sum <t> in sTime do vMFo[ t ] +
 	sum <t> in sTime do vGRs[ t ] +
 	sum <t> in sTime do vJPs[ t ] +
 	sum <t> in sTime do vKEs[ t ] +
 	sum <t> in sTime do vLNs[ t ];