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main_m.m
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%% Multi-Period Distributed Optimal Power Flow
%% Temporally Brute-Forced, Spatially Distributed, Integer-Relaxed NLP.
clearVars = true;
localUsername = getenv('USERNAME');
listOfUsernames = {'aryan', 'Aryan Ritwajeet Jha'};
if ismember(localUsername, listOfUsernames)
% For user 'aryan', change the current directory to the specified path
wdSim = strcat("C:", filesep, "Users", filesep, localUsername, filesep, "Documents", filesep, ...
"documents_general", filesep, "MultiPeriod-DistOPF-Benchmark", filesep);
cd(wdSim);
addpath(genpath('functions\'))
latex_interpreter
else
fprintf("Are you not me? Might want to add the folder to the path or add folder to the workspace.\n");
end
addDirectories; % adds rawDataFolder, latex_interpreter
rawDataFolder = "rawData";
clearVariables(clearVars);
%%
start = tic;
verbose = false;
logging = true;
logging_Aeq_beq = false;
systemName = 'ieee123'
objFunction0 = "gen_cost"
peakShavingToo = false
% Rated Total System Load = 1164 kW
PTarget_kW = 940;
numAreas = 4
T = 5
macroItrMax = 100; % Max no. of permissible iterations for optimizing an area
noBatteries = false;
alpha = 1e-3;
% gamma = 1e-1;
batteryTerminalChargeConstraint = "hard";
if strcmp(batteryTerminalChargeConstraint, "soft")
gamma = 1e0;
else
gamma = 0;
end
DER_percent = 20;
% Batt_percent = ~noBatteries*DER_percent;
Batt_percent = ~noBatteries * 30;
delta_t = 1.00; % one hour
displayTables = true;
displayNetworkGraphs = false;
displayActualBusNumbersInGraphs = false;
saveNetworkGraphPlots = false;
generateTextFilesForResults = true;
displaySimulationResultPlots = false;
saveSimulationResultPlots = false;
saveSCDPlots = true;
globalPVCoeff = 1.0;
[pvCoeffVals, lambdaVals, S_to_P_ratio_PV, ...
S_to_P_ratio_Batt, costArray] = inputForecastData(rawDataFolder, T, globalPVCoeff);
%%
V_min = 0.95;
V_max = 1.05;
etta_C = 0.95;
etta_D = 0.95;
soc_min = 0.30;
soc_max = 0.95;
if numAreas == 1
copf = true;
myfprintf(verbose, logging, "Centralized OPF it is.");
simNatureString = "Centralized-OPF";
else
copf = false;
myfprintf(verbose, logging, "Perforiming Distributed OPF with %d Areas.", numAreas);
simNatureString = "Spatially-Distributed-OPF";
end
if strcmp(systemName, "ieee123")
N = 128;
m = N-1;
else
error("Unknown Power System")
end
actualBusNums = [1:36, 119, 126, 127, 117, 54:68, 122, 118, 37:53, 120, 125, 128, 69:116, 121, 123, 124]';
% N = max(actualBusNums);
if peakShavingToo
PSubsPeak_kW = PTarget_kW;
suffixObjFunctionPeak = "_peak_shave";
suffixPeak = "_peakShave";
suffixStrObjectiveFunctionPeak = " with Peak Shaving";
else
PSubsPeak_kW = Inf;
suffixObjFunctionPeak = "";
suffixPeak = "";
suffixStrObjectiveFunctionPeak = "";
end
if strcmp(objFunction0, "loss_min")
strObjectiveFunction0 = "Loss Minimization";
suffixObj0 = "minLoss";
elseif strcmp(objFunction0, "gen_cost")
strObjectiveFunction0 = "Cost of Substation Power";
suffixObj0 = "genCost";
else
error("Objective Function NOT recognized.")
end
objFunction = strcat(objFunction0, suffixObjFunctionPeak)
suffixObj = strcat(suffixObj0, suffixPeak);
strObjectiveFunction = strcat(strObjectiveFunction0, suffixStrObjectiveFunctionPeak);
loggingLocationName = "logfiles/";
saveLocationFilename = strcat(loggingLocationName , systemName, "/numAreas_", num2str(numAreas), "/optimizationLogs.txt");
fileOpenedFlag = false;
systemDataFolder = strcat("rawData", filesep, systemName, filesep, "numAreas_", num2str(numAreas), filesep);
kVA_B = 1000; % base kVA
kV_B = 4.16/sqrt(3); % 2.4018
a = [0.25 0.05]; %coefficient for correction step
chargeToPowerRatio = 4;
[CBMatrix, CBTable] = extractConnectionData(systemDataFolder);
numChildAreas = zeros(numAreas, 1);
numRelationships = length(CBTable.parentArea);
uniqueParents = unique(CBTable.parentArea);
numUniqueParents = length(uniqueParents);
[isLeaf, isRoot] = deal( ones(numAreas, 1) );
for relationshipNum = 1:numRelationships
parAr = CBTable.parentArea(relationshipNum);
isLeaf(parAr, 1) = 0;
chAr = CBTable.childArea(relationshipNum);
isRoot(chAr, 1) = 0;
numChildAreas(parAr) = numChildAreas(parAr) + 1; %contains which area has how many children
end
sysInfo = struct();
sysInfo.N = N;
sysInfo.m = m;
sysInfo.nBatt = 0; % will be incremented later
sysInfo.nDER = 0; % will be incremented later
sysInfo.numRelationships = numRelationships;
sysInfo.numAreas = numAreas;
sysInfo.numChildAreas = numChildAreas; % An array of containing no. of
sysInfo.actualBusNums = actualBusNums;
% child areas for each area
sysInfo.systemName = systemName;
sysInfo.isLeaf = isLeaf;
sysInfo.isRoot = isRoot;
sysInfo.kVA_B = kVA_B;
sysInfo.kV_B = kV_B;
sysInfo.Battery.chargeToPowerRatio = chargeToPowerRatio;
sysInfo.CBTable = CBTable;
sysInfo.DER_or_not = zeros(N, 1);
sysInfo.Batt_or_not = zeros(N, 1);
sysInfo.Q_C_Full = zeros(N, 1);
sysInfo.P_L_1toT = zeros(N, T);
sysInfo.P_L_Total_1toT = zeros(T, 1);
sysInfo.pD_Full_1toT = zeros(N, T);
sysInfo.pD_Total_1toT = zeros(T, 1);
sysInfo.qD_Full_1toT = zeros(N, T);
sysInfo.qD_Total_1toT = zeros(T, 1);
sysInfo.Pd_Full_1toT = zeros(N, T);
sysInfo.Pc_Full_1toT = zeros(N, T);
sysInfo.Pdc_Full_1toT = zeros(N, T);
sysInfo.Pd_Total_1toT = zeros(T, 1);
sysInfo.Pc_Total_1toT = zeros(T, 1);
sysInfo.Pdc_Total_1toT = zeros(T, 1);
[PLoss_allT_vs_macroItr, PSubs_allT_vs_macroItr, ...
PSubsCost_allT_vs_macroItr, QSubs_allT_vs_macroItr] = deal(zeros(macroItrMax, 1));
[PLoss_1toT_vs_macroItr, PSubs_1toT_vs_macroItr, ...
PSubsCost_1toT_vs_macroItr, QSubs_1toT_vs_macroItr] = deal(zeros(T, macroItrMax));
sysInfo.PLoss_allT_vs_macroItr = PLoss_allT_vs_macroItr;
sysInfo.PLoss_1toT_vs_macroItr = PLoss_1toT_vs_macroItr;
sysInfo.PSubs_allT_vs_macroItr = PSubs_allT_vs_macroItr;
sysInfo.PSubs_1toT_vs_macroItr = PSubs_1toT_vs_macroItr;
sysInfo.PSubsCost_allT_vs_macroItr = PSubsCost_allT_vs_macroItr;
sysInfo.PSubsCost_1toT_vs_macroItr = PSubsCost_1toT_vs_macroItr;
sysInfo.QSubs_allT_vs_macroItr = QSubs_allT_vs_macroItr;
sysInfo.QSubs_1toT_vs_macroItr = QSubs_1toT_vs_macroItr;
simInfo = struct();
simInfo.wdSim = wdSim;
if copf
simInfo.simName = "MPCOPF";
else
simInfo.simName = "MPDOPF";
end
simInfo.copf = copf;
simInfo.simNatureString = simNatureString;
simInfo.alpha = alpha;
simInfo.batteryTerminalChargeConstraint = batteryTerminalChargeConstraint;
simInfo.gamma = gamma;
simInfo.DER_percent = DER_percent;
simInfo.Batt_percent = Batt_percent;
battstring = strcat('pv_', num2str(DER_percent), '_batt_', num2str(Batt_percent));
simInfo.battstring = battstring;
simInfo.etta_C = etta_C;
simInfo.etta_D = etta_D;
simInfo.chargeToPowerRatio = chargeToPowerRatio;
simInfo.soc_min = soc_min;
simInfo.soc_max = soc_max;
simInfo.V_min = V_min;
simInfo.V_max = V_max;
simInfo.kVA_B = kVA_B;
simInfo.kV_B = kV_B;
simInfo.lambdaVals = lambdaVals;
simInfo.pvCoeffVals = pvCoeffVals;
simInfo.S_to_P_ratio_PV = S_to_P_ratio_PV;
simInfo.S_to_P_ratio_Batt = S_to_P_ratio_Batt;
simInfo.noBatteries = noBatteries;
simInfo.objFunction0 = objFunction0;
simInfo.objFunction = objFunction;
simInfo.strObjectiveFunction = strObjectiveFunction;
simInfo.suffixObj = suffixObj;
simInfo.T = T;
simInfo.PSubsPeak_kW = PSubsPeak_kW;
if copf
simInfo.alg.spatial = "CentralizedOPF";
else
simInfo.alg.spatial = "ENApp";
end
simInfo.costArray = costArray;
simInfo.delta_t = delta_t;
simInfo.alg.temporal = "BruteForce";
simInfo.alg.macroItrMax = macroItrMax;
% stopping criterion
macroItrResidualTolerance = 0.001 ; % Tolerance
simInfo.alg.macroItrResidualTolerance = macroItrResidualTolerance;
simInfo.macroItrsCompleted = 0;
simInfo.alg.correctionStep = a;
simInfo.macroItr = 0;
% simInfo.alg.microItrMax = 100;
simInfo.alg.microItrMax = 200;
simInfo.alg.tolfun = 1e-6;
simInfo.alg.stepTol = 1e-6;
simInfo.alg.constraintTol = 1e-6;
simInfo.alg.optimalityTol = 1e-6;
maxConnectingBusNum = max(CBTable.conBus_parentAreaTo);
% Start with the algorithm
if logging && verbose
error("Kindly specify ONLY one of the following arguments as true: verbose and logging.")
elseif logging && ~verbose
fileOpenedFlag = true;
fid = fopen(saveLocationFilename, 'w');
elseif ~logging
logging = verbose;
fid = 1;
else
fid = 1;
end
myfprintf(true, fid, "A total of %d time-periods (of %d minutes each, so %.2f hours in total) " + ...
"will be run.\n", T, delta_t*60, delta_t*T);
myfprintf(logging, fid, "********Running Full OPF for the system.********\n"); %always true
keepRunningIterations = true;
time_dist = zeros(macroItrMax, numAreas);
maxResidual_vs_macroItr_allT = zeros(macroItrMax, 1);
v1_1 = 1.03^2*ones(numAreas, 1);
v1_1toT = repmat(v1_1, 1, T);
Se_iter = zeros(macroItrMax, numAreas, T);
V_iter = zeros(macroItrMax, N, numUniqueParents, T);
S12_allRelationships = CBTable.S_childArea;
S12_allRelationships_1toT = repmat(S12_allRelationships, 1, T);
S_parent_1toT = zeros(numAreas, T);
S_Areas_1toT = zeros(N, numAreas, T);
v_Areas_1toT = zeros(N, numAreas, T);
v1_1toT_vs_macroItr = zeros(numRelationships, T, macroItrMax);
S12_1toT_vs_macroItr = zeros(numRelationships, T, macroItrMax);
Residuals_1toT_vs_macroItr = zeros(2*numRelationships, T, macroItrMax);
sysInfo = getSysInfo(sysInfo, simInfo, systemName, ...
'verbose', verbose, 'logging', logging, 'displayTables', false);
% if ~copf
% % Retrieve busesWithDERs_Area for COPF Area 1.
% % Take X% of them and save them.
% % Assign the buses in that list into each Area's corresponding list.
% % sysInfo.busesWithDERs0
% % sysInfo.busesWithDERs
% % sysInfo.busesWithBatts0
% % sysInfo.busesWithBatts
% % somehow specify all correct X%, Y% DER, Battery buses in each area
% % USING COPF Area (actual numbered) X%, Y% DER, Battery buses
% % and store them in each areaInfo
% end
xVals_vs_Area_vs_LastMacroItr = struct();
while keepRunningIterations
for Area = 1:numAreas
% for Area = 1
% for Area = [2 3 1 4]
macroItr = simInfo.macroItr;
myfprintf(true, "Macro-iteration %d: Running OPF for Area %d.\n", macroItr+1, Area);
v_parAr_1toT = v1_1toT(Area, 1:T);
S_chArs_1toT = S12_allRelationships_1toT(CBTable.parentArea == Area, 1:T);
if macroItr == 0
areaInfo = struct(); % Area struct not created yet, so create it
areaInfo.Area = Area;
else
areaInfo = sysInfo.Area{Area}; % extract the latest Area struct
end
[xVals_Area, sysInfo, simInfo, ...
time_dist] = ...
...
NL_OPF_dist2(sysInfo, simInfo, areaInfo, v_parAr_1toT, S_chArs_1toT, ...
time_dist, 'verbose', verbose, 'saveToFile', true, 'logging', logging, ...
'saveSCDPlots', false);
xVals_vs_Area_vs_LastMacroItr.Area{Area} = xVals_Area;
simInfo.xVals_vs_Area_vs_LastMacroItr = xVals_vs_Area_vs_LastMacroItr;
%%
nVars1_Area = length(xVals_Area)/T;
xVals_Area_1toT = reshape(xVals_Area, nVars1_Area, T);
myfprintf(true, fid, "Current Macro-iteration %d: OPF for Area %d computed.\n", macroItr+1, Area)
areaInfo = sysInfo.Area{Area};
P_L_Area_1toT_kW = kVA_B*sum(areaInfo.P_L_Area_1toT);
Q_L_Area_1toT_kW = kVA_B*sum(areaInfo.Q_L_Area_1toT);
% myfprintf(true, "Current Macro-iteration %d: Total Load for Area %d is %4.4f kW + %4.4f kVAr.\n", macroItr+1, Area, P_L_Area_1toT_kW, Q_L_Area_1toT_kW);
N_Area = areaInfo.N_Area;
m_Area = areaInfo.m_Area;
nDER_Area = areaInfo.nDER_Area;
nBatt_Area = areaInfo.nBatt_Area;
P_Area_1toT = xVals_Area(areaInfo.indices_Pij); %m_Areax1
Q_Area_1toT = xVals_Area(areaInfo.indices_Qij); %m_Areax1
S_Area_1toT = complex(P_Area_1toT, Q_Area_1toT); %m_Areax1
vAll_Area_1toT = xVals_Area(areaInfo.indices_vAllj); %N_Areax1
V_Area_1toT = sqrt(vAll_Area_1toT);
areaInfo.V_Area_1toT = V_Area_1toT;
sysInfo.Area{Area} = areaInfo;
qD_Area_1toT = xVals_Area(areaInfo.indices_qDj);
qD_AreaFull_1toT = sparseArrayFromDense(qD_Area_1toT, N_Area, areaInfo.busesWithDERs_Area);
PSubs_Area_1toT = P_Area_1toT(1, 1:T);
S_parent_1toT(Area, 1:T) = S_Area_1toT(1, 1:T);
v_Areas_1toT(1:N_Area, Area, 1:T) = vAll_Area_1toT;
S_Areas_1toT(1:m_Area, Area, 1:T) = S_Area_1toT; % Storing all the S flow of the Area
PLoss_allT_vs_macroItr(macroItr+1) = PLoss_allT_vs_macroItr(macroItr+1) + areaInfo.PLoss_allT;
PLoss_1toT_vs_macroItr(1:T, macroItr+1) = PLoss_1toT_vs_macroItr(1:T, macroItr+1) + areaInfo.PLoss_1toT;
if Area == 1
PSubs_allT_vs_macroItr(macroItr+1) = areaInfo.PSubs_allT;
PSubs_1toT_vs_macroItr(1:T, macroItr+1) = areaInfo.PSubs_1toT;
PSubsCost_allT_vs_macroItr(macroItr+1) = areaInfo.PSubsCost_allT;
PSubsCost_1toT_vs_macroItr(1:T, macroItr+1) = areaInfo.PSubsCost_1toT;
QSubs_allT_vs_macroItr(macroItr+1) = areaInfo.QSubs_allT;
QSubs_1toT_vs_macroItr(1:T, macroItr+1) = areaInfo.QSubs_1toT;
end
if macroItr == 0
sysInfo.nDER = sysInfo.nDER + areaInfo.nDER_Area;
sysInfo.nBatt = sysInfo.nBatt + areaInfo.nBatt_Area;
sysInfo.DER_or_not(areaInfo.busesWithDERs_Actual) = 1;
sysInfo.Batt_or_not(areaInfo.busesWithBatts_Actual) = 1;
end
sysInfo.PLoss_allT_vs_macroItr = PLoss_allT_vs_macroItr;
sysInfo.PLoss_1toT_vs_macroItr = PLoss_1toT_vs_macroItr;
sysInfo.PSubs_allT_vs_macroItr = PSubs_allT_vs_macroItr;
sysInfo.PSubs_1toT_vs_macroItr = PSubs_1toT_vs_macroItr;
sysInfo.PSubsCost_allT_vs_macroItr = PSubsCost_allT_vs_macroItr;
sysInfo.PSubsCost_1toT_vs_macroItr = PSubsCost_1toT_vs_macroItr;
sysInfo.QSubs_allT_vs_macroItr = QSubs_allT_vs_macroItr;
sysInfo.QSubs_1toT_vs_macroItr = QSubs_1toT_vs_macroItr;
end
myfprintf(true, "Macro-iteration %d: OPF's for all Areas completed. Checking for convergence.\n", macroItr+1);
if macroItr == 0
myfprintf(true, "Just collecting some mappings for DER and Battery Bus Indices")
if DER_percent > 0
myfprintf(true, "Just collecting some mappings for DER Bus Indices")
sysInfo.busesWithDERs = find(sysInfo.DER_or_not > 0);
end
if Batt_percent > 0
myfprintf(true, "Just collecting some mappings for Battery Bus Indices")
sysInfo.busesWithBatts = find(sysInfo.Batt_or_not > 0);
end
for Area = 1:numAreas
areaInfo = sysInfo.Area{Area};
if DER_percent > 0
areaInfo.DERBusNums_Actual = findIndicesInArray(sysInfo.busesWithDERs, areaInfo.busesWithDERs_Actual);
end
if Batt_percent > 0
areaInfo.BattBusNums_Actual = findIndicesInArray(sysInfo.busesWithBatts, areaInfo.busesWithBatts_Actual);
end
sysInfo.Area{Area} = areaInfo;
end
end
if ~copf
for relationshipNum = 1 : numRelationships
parAr = CBTable.parentArea(relationshipNum);
chAr = CBTable.childArea(relationshipNum);
myfprintf(true, "Checking for convergence between parent Area %d and child Area %d\n", parAr, chAr);
parentAreaConnectingBus = CBTable.conBus_parentAreaTo(relationshipNum);
S12_intoChild_1toT = reshape(S_Areas_1toT(1, chAr, 1:T), 1, T);
if macroItr+1 > 1 % not macroItr == 0
S12_intoChild_1toT_mIm1 = S12_1toT_vs_macroItr(relationshipNum, 1:T, macroItr);
else
S12_intoChild_1toT_mIm1 = 0;
end
delta_S12_1toT = S12_intoChild_1toT - S12_intoChild_1toT_mIm1;
v_parentSide_1toT = reshape(v_Areas_1toT(parentAreaConnectingBus, parAr, 1:T), 1, T);
v1_1toT_vs_macroItr(relationshipNum, 1:T, macroItr+1) = v_parentSide_1toT;
S12_1toT_vs_macroItr(relationshipNum, 1:T, macroItr+1) = S12_intoChild_1toT;
if macroItr+1 > 1 % not macroItr == 0
v1_parentSide_1toT_mIm1 = v1_1toT_vs_macroItr(relationshipNum, 1:T, macroItr);
else
v1_parentSide_1toT_mIm1 = v1_1(1);
end
delta_v_1toT = v_parentSide_1toT - v1_parentSide_1toT_mIm1;
Residual_Area_1toT = reshape([delta_S12_1toT; delta_v_1toT], 2*T, 1);
[currentMaxResidual_1toT, lin_idx] = max(abs(Residual_Area_1toT));
row = lin_idx;
myfprintf(true, "Macro-iteration %d: Current Biggest Residual is %d at index %d.\n", macroItr+1, currentMaxResidual_1toT, row);
if currentMaxResidual_1toT > maxResidual_vs_macroItr_allT(macroItr+1)
maxResidual_vs_macroItr_allT(macroItr+1) = currentMaxResidual_1toT;
myfprintf(true, "It is even bigger than the previous biggest residual.\n");
end
end
myfprintf(true, "Macro-iteration %d: Checking for convergence among all connected areas completed.\n", macroItr+1);
if macroItr == macroItrMax - 1
error("Didn't converge even after %d macro-iterations, terminating.\n", macroItrMax);
elseif currentMaxResidual_1toT < macroItrResidualTolerance
myfprintf(true, "MPOPF for Horizon T = %d Converged in %d macro-iterations!\n", T, macroItr+1);
keepRunningIterations = false;
maxResidual_vs_macroItr_allT = maxResidual_vs_macroItr_allT(1:macroItr+1);
else
myfprintf(true, "MPOPF for Horizon T = %d , Still yet to converge after %d macro-iterations, continuing.\n", T, macroItr+1)
%Communication-
myfprintf(true, "Since there is still a difference in boundary variables, " + ...
"let's exchange boundary variables.\n")
for relationshipNum = 1:numRelationships
parAr = CBTable.parentArea(relationshipNum);
chAr = CBTable.childArea(relationshipNum);
myfprintf(true, "Communicating between parent Area %d and child Area %d\n", parAr, chAr);
busParTo = CBTable.conBus_parentAreaTo(relationshipNum);
areaInfo_par = sysInfo.Area{parAr};
areaInfo_ch = sysInfo.Area{chAr};
V_iter(macroItr+1, busParTo, parAr, 1:T) = v_Areas_1toT(busParTo, parAr, 1:T) ;
Se_iter(macroItr+1, chAr, 1:T) = S_parent_1toT(chAr, 1:T);
if macroItr >= 2
myfprintf(true, "***Macro-iteration %d Communication Voltage:****\n", macroItr+1)
v1_1toT(chAr, 1:T) = a(2)*reshape(V_iter(macroItr, busParTo, parAr, 1:T), 1, T) + ...
a(1)*reshape(V_iter(macroItr+1, busParTo, parAr, 1:T), 1, T) + ...
(1-sum(a))*reshape(v_Areas_1toT(busParTo, parAr, 1:T), 1, T);
myfprintf(true, "***Macro-iteration %d Communication Power:****\n", macroItr+1)
S12_allRelationships_1toT(relationshipNum, 1:T) = a(2)*reshape(Se_iter(macroItr-1, chAr, 1:T), 1, T)+...
a(1)*reshape(Se_iter(macroItr, chAr, 1:T), 1, T)+...
(1-sum(a))*S_parent_1toT(chAr, 1:T);
else
myfprintf(true, "***Macro-iteration %d Communication Voltage:****\n", macroItr+1)
v1_1toT(chAr, 1:T) = v_Areas_1toT(busParTo, parAr, 1:T);
myfprintf(true, "***Macro-iteration %d Communication Power:****\n", macroItr+1)
S12_allRelationships_1toT(relationshipNum, 1:T) = S_parent_1toT(chAr, 1:T);
end
end
simInfo.macroItr = macroItr + 1;
end
else
keepRunningIterations = false;
myfprintf(verbose, "Centralized MPOPF for %d Horizons ended.\n", T);
end
end
%%
sysInfo = truncateSysInfo(sysInfo, macroItr);
sysInfo = collectCentralizedInfo(sysInfo, simInfo);
%%
% saveSCDPlots = true
if Batt_percent > 0 && saveSCDPlots
for Area = 1:numAreas
areaInfo = sysInfo.Area{Area};
xValsArea_1toT = areaInfo.xvals;
checkForSCD(sysInfo, simInfo, areaInfo, T, xValsArea_1toT, 'savePlots', true);
end
end
%%
V_iter = V_iter(1:macroItr+1, :, :, :);
PLoss_allT_vs_macroItr = PLoss_allT_vs_macroItr(1:macroItr+1);
PLoss_1toT_vs_macroItr = PLoss_1toT_vs_macroItr(:, 1:macroItr+1);
PSubs_allT_vs_macroItr = PSubs_allT_vs_macroItr(1:macroItr+1);
PSubs_1toT_vs_macroItr = PSubs_1toT_vs_macroItr(:, 1:macroItr+1);
PSubsCost_allT_vs_macroItr = PSubsCost_allT_vs_macroItr(1:macroItr+1);
PSubsCost_1toT_vs_macroItr = PSubsCost_1toT_vs_macroItr(:, 1:macroItr+1);
v1_1toT_vs_macroItr = v1_1toT_vs_macroItr(:, :, 1:macroItr+1);
S12_1toT_vs_macroItr = S12_1toT_vs_macroItr(:, :, 1:macroItr+1);
P12_1toT_vs_macroItr = real(S12_1toT_vs_macroItr);
time_dist = time_dist(1:macroItr+1, :);
results = struct();
results.PLoss_allT_vs_macroItr = PLoss_allT_vs_macroItr;
results.PLoss_1toT_vs_macroItr = PLoss_1toT_vs_macroItr;
results.PSubs_allT_vs_macroItr = PSubs_allT_vs_macroItr;
results.PSubs_1toT_vs_macroItr = PSubs_1toT_vs_macroItr;
results.PSubsCost_allT_vs_macroItr = PSubsCost_allT_vs_macroItr;
results.PSubsCost_1toT_vs_macroItr = PSubsCost_1toT_vs_macroItr;
results.QSubs_allT_vs_macroItr = QSubs_allT_vs_macroItr;
results.QSubs_1toT_vs_macroItr = QSubs_1toT_vs_macroItr;
results.v1_1toT_vs_macroItr = v1_1toT_vs_macroItr;
results.S12_1toT_vs_macroItr = S12_1toT_vs_macroItr;
results.P12_1toT_vs_macroItr = P12_1toT_vs_macroItr;
results.PLoss_allT = PLoss_allT_vs_macroItr(macroItr+1);
results.PLoss_1toT = PLoss_1toT_vs_macroItr(1:T, macroItr+1);
results.PSubs_allT = PSubs_allT_vs_macroItr(macroItr+1);
results.PSubs_1toT = PSubs_1toT_vs_macroItr(1:T, macroItr+1);
results.PSubsCost_allT = PSubsCost_allT_vs_macroItr(macroItr+1);
results.PSubsCost_1toT = PSubsCost_1toT_vs_macroItr(1:T, macroItr+1);
results.QSubs_allT = QSubs_allT_vs_macroItr(macroItr+1);
results.QSubs_1toT = QSubs_1toT_vs_macroItr(1:T, macroItr+1);
results.simInfo = simInfo;
results.sysInfo = sysInfo;
%%
plot_simulation_results(results)
%%
grandTotalTime = toc(start)
lineLoss_kW_allT = 0;
lineLoss_kW_1toT = zeros(T, 1);
for areaNum = 1:numAreas
areaInfo = sysInfo.Area{areaNum};
lineLoss_Area_kW_1toT = areaInfo.PLoss_1toT * kVA_B;
lineLoss_kW_1toT = lineLoss_kW_1toT + lineLoss_Area_kW_1toT;
lineLoss_Area_kW_allT = areaInfo.PLoss_allT * kVA_B;
lineLoss_kW_allT = lineLoss_kW_allT + lineLoss_Area_kW_allT;
end
area1Info = sysInfo.Area{1};
genCost_dollars_1toT = area1Info.PSubsCost_1toT;
genCost_dollars_allT = area1Info.PSubsCost_allT;
substationPower_kW_1toT = sysInfo.PSubs_1toT * kVA_B;
substationPower_kVAr_1toT = sysInfo.QSubs_1toT * kVA_B;
substationPower_kW_allT = sysInfo.PSubs_allT * kVA_B;
substationPower_kVAr_allT = sysInfo.QSubs_allT * kVA_B;
PSubsMax_allT_kW = max(substationPower_kW_1toT);
battery_scd_Total_kW_1toT = sysInfo.P_scd_Total_1toT * kVA_B;
battery_scd_Total_kW_allT = sysInfo.P_scd_Total_1toT * kVA_B;
battery_soc_abuse_Total_kWh = sysInfo.B_violation_abs_Total * kVA_B;
pL_Total_kW_1toT = sysInfo.P_L_Total_1toT * kVA_B;
pL_Total_kW_allT = sysInfo.P_L_Total_allT * kVA_B;
qL_Total_kVAr_1toT = sysInfo.Q_L_Total_1toT * kVA_B;
qL_Total_kVAr_allT = sysInfo.Q_L_Total_allT * kVA_B;
pD_Total_kW_1toT = sysInfo.pD_Total_1toT * kVA_B;
pD_Total_kW_allT = sysInfo.pD_Total_allT * kVA_B;
qD_Total_kVAr_1toT = sysInfo.qD_Total_1toT * kVA_B;
qD_Total_kVAr_allT = sysInfo.qD_Total_allT * kVA_B;
Pdc_Total_kW_1toT = sysInfo.Pdc_Total_1toT * kVA_B;
Pdc_Total_kW_allT = sysInfo.Pdc_Total_allT * kVA_B;
p_Total_kW_1toT = sysInfo.p_Total_1toT * kVA_B;
p_Total_kW_allT = sysInfo.p_Total_allT * kVA_B;
q_Total_kVAr_1toT = sysInfo.q_Total_1toT * kVA_B;
q_Total_kVAr_allT = sysInfo.q_Total_allT * kVA_B;
qB_Total_kVAr_1toT = sysInfo.qB_Total_1toT * kVA_B;
qB_Total_kVAr_allT = sysInfo.qB_Total_allT * kVA_B;
QC_Total_kVAr_1toT = sysInfo.QC_Total_1toT * kVA_B;
QC_Total_kVAr_allT = sysInfo.QC_Total_allT * kVA_B;
P_scd_Total_kW_1toT = sysInfo.P_scd_Total_1toT * kVA_B;
P_scd_Total_kW_allT = sysInfo.P_scd_Total_allT * kVA_B;
B_violation_abs_Total_kWh = sysInfo.B_violation_abs_Total * kVA_B;
maxTimes_vs_macroItr = max(time_dist, [], 2);
time_if_parallel = sum(maxTimes_vs_macroItr);
time_if_serial = sum(sum(time_dist));
if ~copf
simNatureStringFull = strcat(simNatureString, " with ", num2str(numAreas), " Areas.");
else
simNatureStringFull = simNatureString;
end
%%
vald = struct();
vald.res = results;
vald.loadShape = sysInfo.loadShape;
vald.loadShapePV = sysInfo.loadShapePV;
vald.loadShapeCost = simInfo.costArray;
if DER_percent > 0
vald.busesWithDERs = sysInfo.busesWithDERs;
busesWithDERs = sysInfo.busesWithDERs;
else
vald.busesWithDERs = [];
busesWithDERs = [];
end
vald.Pmpp = sysInfo.Pmpp;
vald.V_1toT = sysInfo.V_1toT;
pLTotal_kW_1toT = sum(sysInfo.P_L_1toT)*kVA_B;
qLTotal_kVAr_1toT = sum(sysInfo.Q_L_1toT)*kVA_B;
pDTotal_kW_1toT = sum(sysInfo.pD_1toT)*kVA_B;
vald.pD_1toT = sysInfo.pD_1toT;
vald.qD_1toT = sysInfo.qD_1toT;
vald.Sder = sysInfo.Sder;
qDTotal_kVAr_1toT = sum(vald.qD_1toT)*kVA_B;
vald.qC_Full = sysInfo.Q_C_Full;
qCTotal_kVAr_1toT = repmat(sum(vald.qC_Full), 1, T)*kVA_B;
if Batt_percent > 0
vald.busesWithBatts = sysInfo.busesWithBatts;
vald.S_battRated = sysInfo.Sbatt;
vald.Pd_1toT = sysInfo.Pd_1toT;
vald.P_battRated = sysInfo.Pbatt;
PdTotal_kW_1toT = sum(vald.Pd_1toT)*kVA_B;
vald.Pc_1toT = sysInfo.Pc_1toT;
PcTotal_kW_1toT = sum(vald.Pc_1toT)*kVA_B;
vald.Pdc_1toT = vald.Pd_1toT - vald.Pc_1toT;
PdcTotal_kW_1toT = PdTotal_kW_1toT - PcTotal_kW_1toT;
Pbatt_abs_Total_kW_1toT = kVA_B*sysInfo.P_batt_abs_Total_1toT;
vald.Pbatt_abs_Total_kW_1toT = Pbatt_abs_Total_kW_1toT;
Pbatt_abs_Total_kW_allT = kVA_B*sysInfo.P_batt_abs_Total_allT;
vald.Pbatt_abs_Total_kW_allT = Pbatt_abs_Total_kW_allT;
qB_abs_Total_kVAr_1toT = kVA_B*sysInfo.qB_abs_Total_1toT;
vald.qB_abs_Total_kVAr_1toT = qB_abs_Total_kVAr_1toT;
qB_abs_Total_kVAr_allT = kVA_B*sysInfo.qB_abs_Total_allT;
vald.qB_abs_Total_kVAr_allT = qB_abs_Total_kVAr_allT;
vald.B_1toT = sysInfo.B_1toT;
BTotal_kWh_1toT = sum(vald.B_1toT)*kVA_B;
vald.B0 = sysInfo.B0;
vald.qB_1toT = sysInfo.qB_1toT;
qBTotal_kVAr_1toT = sum(vald.qB_1toT)*kVA_B;
else
vald.busesWithBatts = [];
vald.S_battRated = [];
vald.Pd_1toT = [];
vald.P_battRated = [];
PdTotal_kW_1toT = zeros(T, 1);
vald.Pc_1toT = [];
PcTotal_kW_1toT = zeros(T, 1);
PdcTotal_kW_1toT = PdTotal_kW_1toT - PcTotal_kW_1toT;
Pbatt_abs_Total_kW_1toT = zeros(T, 1);
vald.Pbatt_abs_Total_kW_1toT = Pbatt_abs_Total_kW_1toT;
Pbatt_abs_Total_kW_allT = 0;
vald.Pbatt_abs_Total_kW_allT = Pbatt_abs_Total_kW_allT;
qB_abs_Total_kVAr_1toT = zeros(T, 1);
vald.qB_abs_Total_kVAr_1toT = qB_abs_Total_kVAr_1toT;
qB_abs_Total_kVAr_allT = 0;
vald.qB_abs_Total_kVAr_allT = qB_abs_Total_kVAr_allT;
vald.B_1toT = [];
BTotal_kWh_1toT = [];
vald.B0 = [];
vald.qB_1toT = zeros(T, 1);
qBTotal_kVAr_1toT = sum(vald.qB_1toT)*kVA_B;
end
pTotal_kW_1toT = PdTotal_kW_1toT + pDTotal_kW_1toT - PcTotal_kW_1toT;
qTotal_kVAr_1toT = qDTotal_kVAr_1toT + qBTotal_kVAr_1toT + qCTotal_kVAr_1toT;
vald.nDER = sysInfo.nDER;
vald.nBatt = sysInfo.nBatt;
vald.simInfo = simInfo;
%%
printAndSaveResults();
%%
plotInputCurves(sysInfo, simInfo);
%%
if ~copf
plotObjectiveConvergenceCurves(sysInfo, simInfo)
end