Latest versions of multiple scripts - modified plotting routines, execution scripts used to generate the latest phase diagrams.

Dipolar-Gas-Simulator/+Plotter/visualizeGSWavefunction.m

@@ -35,7 +35,6 @@ function visualizeGSWavefunction(folder_path, run_index)
     
     %Plotting    
     fig = figure(1); 
-    fig.WindowState = 'maximized';
     clf
     set(gcf,'Position', [100, 100, 1600, 900])
     t = tiledlayout(2, 3, 'TileSpacing', 'compact', 'Padding', 'compact'); % 2x3 grid

Dipolar-Gas-Simulator/+Scripts/plotPhaseDiagramWithBoundaries.m

@@ -1,4 +1,5 @@
-function plotPhaseDiagramWithBoundaries(PhaseDiagramMatrix, NumberOfAtoms, ScatteringLengths, PhaseBoundary_Untilted, TitleString)
+function plotPhaseDiagramWithBoundaries(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, PhaseBoundary, TitleString)                                         
+
     % plotPhaseDiagramWithBoundaries - Plots a phase diagram with overlaid interpolated boundaries
     %
     % Inputs:
@@ -12,43 +13,46 @@ function plotPhaseDiagramWithBoundaries(PhaseDiagramMatrix, NumberOfAtoms, Scatt
     % boundary curves extracted from user-selected points.
 
     % Extract boundary point sets
-    rawPoints = PhaseBoundary_Untilted.SelectedPoints.values;
+    rawPoints = PhaseBoundary.SelectedPoints.values;
     if iscell(rawPoints)
         pointSets = rawPoints;
     else
         pointSets = {rawPoints};
     end
 
-    % Interpolate phase diagram
+    regionNames = ["Unmodulated", "SSD", "Stripe", "Labyrinth", "Honeycomb"];
-    [X, Y]   = meshgrid(NumberOfAtoms, ScatteringLengths);
+    regionColors = [
-    [Xq, Yq] = meshgrid(linspace(min(NumberOfAtoms), max(NumberOfAtoms), 500), ...
+        0.8 0.8 0.8;
-                        linspace(min(ScatteringLengths), max(ScatteringLengths), 500));
+        0.2 0.6 1.0;
-    Mq       = interp2(X, Y, PhaseDiagramMatrix, Xq, Yq, 'nearest');
+        0.2 0.8 0.2;
+        1.0 0.6 0.2;
+        0.8 0.2 0.8
+    ];
 
-    % Plot
+    [X, Y] = meshgrid(NUM_ATOMS_LIST, SCATTERING_LENGTH_RANGE);
-    figure('Color','w');
+    [Xq, Yq] = meshgrid(linspace(min(NUM_ATOMS_LIST), max(NUM_ATOMS_LIST), 500), ...
-    clf
+                        linspace(min(SCATTERING_LENGTH_RANGE), max(SCATTERING_LENGTH_RANGE), 500));
-    set(gcf, 'Position', [100, 100, 950, 800]);
+    Mq = interp2(X, Y, M, Xq, Yq, 'nearest');
-    set(gcf, 'Renderer', 'opengl');
+
-    imagesc([min(NumberOfAtoms), max(NumberOfAtoms)], ...
+    fig = figure('Color', 'w'); clf;
-            [min(ScatteringLengths), max(ScatteringLengths)], Mq);
+    set(fig, 'Position', [100, 100, 1050, 800], 'Renderer', 'opengl');
-    set(gca, 'YDir', 'normal');
+    ax = axes('Parent', fig, 'Position', [0.1 0.15 0.75 0.8]);
-    colormap([
+
-        0.8 0.8 0.8;  % Unmodulated
+    imagesc(ax, [min(NUM_ATOMS_LIST), max(NUM_ATOMS_LIST)], ...
-        0.2 0.6 1.0;  % SSD
+                [min(SCATTERING_LENGTH_RANGE), max(SCATTERING_LENGTH_RANGE)], Mq);
-        0.2 0.8 0.2;  % Stripe
+    set(ax, 'YDir', 'normal');
-        1.0 0.6 0.2;  % Labyrinth
+    colormap(ax, regionColors);
-        0.8 0.2 0.8   % Honeycomb
+    cb = colorbar('Ticks', 0:4, 'TickLabels', regionNames, 'FontSize', 12);
-    ]);
+    cb.Color = 'k';  % set colorbar text color
-    cb = colorbar('Ticks', 0:4, ...
+    clim(ax, [0 4]);
-             'TickLabels', {'Unmodulated','SSD','Stripe','Labyrinth','Honeycomb'}, ...
+    hold(ax, 'on');
-             'FontSize', 12);
+    xlabel(ax, 'Number of Atoms', 'FontSize', 16);
-    cb.Color = 'k';
+    ylabel(ax, 'Scattering Length (\times a_o)', 'FontSize', 16,'Interpreter', 'tex');
-    clim([0 4]);
+    t = title(ax, TitleString, 'FontSize', 18, 'Interpreter', 'tex');
-    xlabel('Number of Atoms');
+    t.Color = 'k';  % force title color to black
-    ylabel('Scattering Length a_s (a_0)');
+    set(ax, 'FontSize', 16, 'Color', 'none');
-    t = title(TitleString);
+    axis(ax, 'tight');
-    t.Color = 'k';
+    grid(ax, 'on');
 
     % Overlay curves
     hold on;

Dipolar-Gas-Simulator/+Scripts/plotSmoothedContourOnPhaseDiagram.m

@@ -1,5 +1,4 @@
-function plotSmoothedContourOnPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, ...
+function plotSmoothedContourOnPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, TitleString, varargin)
-                                           titleString, varargin)
     interpMethod = 'makima';
     showPoints = true;
     matFilePaths = {};
@@ -52,7 +51,8 @@ function plotSmoothedContourOnPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS
 
     xlabel(ax, 'Number of Atoms', 'FontSize', 16);
     ylabel(ax, 'Scattering Length (\times a_o)', 'FontSize', 16);
-    title(ax, titleString, 'FontSize', 18, 'Interpreter', 'tex');
+    t = title(ax, TitleString, 'FontSize', 18, 'Interpreter', 'tex');
+    t.Color = 'k';  % force title color to black
     set(ax, 'FontSize', 16, 'Color', 'none');
     axis(ax, 'tight');
     grid(ax, 'on');

Dipolar-Gas-Simulator/+Scripts/plotSmoothedPhaseDiagram.m

@@ -1,4 +1,4 @@
-function plotSmoothedPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, titleString)
+function plotSmoothedPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, TitleString)
     % Region labels and corresponding colors
     regionNames = ["Unmodulated", "SSD", "Stripe", "Labyrinth", "Honeycomb"];
     regionColors = [
@@ -34,7 +34,7 @@ function plotSmoothedPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, ti
     % Axis formatting
     xlabel('Number of Atoms', 'Interpreter', 'tex', 'FontSize', 16);
     ylabel('Scattering Length (\times a_o)', 'Interpreter', 'tex', 'FontSize', 16);
-    t = title(titleString, 'Interpreter', 'tex', 'FontSize', 18);
+    t = title(TitleString, 'Interpreter', 'tex', 'FontSize', 18);
     t.Color = 'k';  % force title color to black
 
     set(gca, 'FontSize', 16, ...

Dipolar-Gas-Simulator/+Scripts/run_hybrid_worker.m

@@ -23,7 +23,7 @@ function run_hybrid_worker(batchParams, batchIdx)
 
         % Create unique save directory
         jobName = sprintf('aS_%03d_theta_%03d_phi_%03d_N_%d', a_s, theta_deg, phi_deg, N_atoms);
-        saveDir = fullfile('./Results/Data_3D/GradientDescent', jobName);
+        saveDir = fullfile('./Results/Data_3D/PhaseDiagram', jobName);
         if ~exist(saveDir, 'dir')
             mkdir(saveDir);
         end
@@ -43,9 +43,14 @@ function run_hybrid_worker(batchParams, batchIdx)
         OptionsStruct.UseApproximationForLHY  = true;
         OptionsStruct.IncludeDDICutOff        = true;
         OptionsStruct.CutoffType              = 'Cylindrical';
-        OptionsStruct.SimulationMode          = 'EnergyMinimization';
+        OptionsStruct.SimulationMode          = 'ImaginaryTimeEvolution'; % 'ImaginaryTimeEvolution' | 'RealTimeEvolution' | 'EnergyMinimization'
-        OptionsStruct.GradientDescentMethod   = 'NonLinearCGD';
+        OptionsStruct.GradientDescentMethod   = 'NonLinearCGD';           % 'HeavyBall' | 'NonLinearCGD' 
         OptionsStruct.MaxIterationsForGD      = 15000;
+        OptionsStruct.TimeStepSize            = 1E-3;            % in s
+        OptionsStruct.MinimumTimeStepSize     = 1E-6;            % in s
+        OptionsStruct.TimeCutOff              = 2E5;             % in s
+        OptionsStruct.EnergyTolerance         = 5E-10;
+        OptionsStruct.ResidualTolerance       = 1E-05;
         OptionsStruct.NoiseScaleFactor        = 0.010;
 
         OptionsStruct.PlotLive                = false;

Dipolar-Gas-Simulator/+Scripts/run_hybrid_worker_for_phase_boundary.m

@@ -5,70 +5,56 @@ function run_hybrid_worker_for_phase_boundary(batchParams, batchIdx)
     if isnan(nprocs), nprocs = feature('numcores'); end
 
     tmpdir                   = fullfile(getenv('TMPDIR'), sprintf('matlab_job_%d', batchIdx));
-    if ~exist(tmpdir, 'dir'); mkdir(tmpdir); end
+    if ~exist(tmpdir, 'dir'), mkdir(tmpdir); end
     cluster.JobStorageLocation = tmpdir;
 
     pool = parpool(cluster, nprocs);
 
-    nJobs = size(batchParams, 1);
+    % Extract single job parameters
-    parfor k = 1:nJobs
+    initial_a_s = batchParams(1);
-        % Unpack parameter tuple
+    theta_deg   = batchParams(2);
-        initial_a_s  = batchParams(k, 1);
+    phi_deg     = batchParams(3);
-        theta_deg    = batchParams(k, 2);
+    N_atoms     = batchParams(4);
-        phi_deg      = batchParams(k, 3);
-        N_atoms      = batchParams(k, 4);
 
     theta_rad   = deg2rad(theta_deg);
     phi_rad     = deg2rad(phi_deg);
 
-        adjusted_a_s = initial_a_s;
+    % Setup save directory
-    
-        % Create unique save directory
     jobName  = sprintf('aS_%03d_theta_%03d_phi_%03d_N_%d', initial_a_s, theta_deg, phi_deg, N_atoms);
-        saveDir = fullfile('./Results/Data_3D/GradientDescent', jobName);
+    saveDir  = fullfile('./Results/Data_3D/PhaseDiagram', jobName);
-        if ~exist(saveDir, 'dir')
+    initfile = fullfile(saveDir, 'psi_init.mat')
-            mkdir(saveDir);
+    if ~exist(saveDir, 'dir'), mkdir(saveDir); end
-        end
+    if ~exist(initfile, 'file'), warning('Running without user-provided initial state'); end
-        
-        srcFile = './Results/Data_3D/GradientDescent/psi_init.mat';
-        if exist(srcFile, 'file')
-            copyfile(srcFile, fullfile(saveDir, 'psi_init.mat'));
-        end
     
+    % Parallelize attempts
     MaxAttempts = 10;
-        SuccessFlag  = false;
+    parfor attempt = 1:MaxAttempts
-        AttemptCount = 0;
+        new_a_s = initial_a_s - 0.5 * (attempt - 1);
         
-        while ~SuccessFlag && AttemptCount < MaxAttempts
+        try
-            AttemptCount = AttemptCount + 1;
-    
-            % Options for this run
             OptionsStruct = struct;
             OptionsStruct.NumberOfAtoms           = N_atoms;
             OptionsStruct.DipolarPolarAngle       = theta_rad;
             OptionsStruct.DipolarAzimuthAngle     = phi_rad;
-            OptionsStruct.ScatteringLength        = adjusted_a_s;
+            OptionsStruct.ScatteringLength        = new_a_s;
-    
             OptionsStruct.TrapFrequencies         = [50, 20, 150];
             OptionsStruct.TrapPotentialType       = 'Harmonic';
-    
             OptionsStruct.NumberOfGridPoints      = [128, 256, 128];
-            OptionsStruct.Dimensions              = [40, 80, 40];
+            OptionsStruct.Dimensions              = [20, 40, 20];
             OptionsStruct.UseApproximationForLHY  = true;
             OptionsStruct.IncludeDDICutOff        = true;
             OptionsStruct.CutoffType              = 'Cylindrical';
-            OptionsStruct.SimulationMode          = 'ImaginaryTimeEvolution'; % 'ImaginaryTimeEvolution' | 'RealTimeEvolution' | 'EnergyMinimization'
+            OptionsStruct.SimulationMode          = 'ImaginaryTimeEvolution';
-            OptionsStruct.GradientDescentMethod   = 'NonLinearCGD';           % 'HeavyBall' | 'NonLinearCGD' 
+            OptionsStruct.GradientDescentMethod   = 'NonLinearCGD';
             OptionsStruct.MaxIterationsForGD      = 15000;
-            OptionsStruct.TimeStepSize            = 1E-3;            % in s
+            OptionsStruct.TimeStepSize            = 1E-3;
-            OptionsStruct.MinimumTimeStepSize     = 1E-6;            % in s
+            OptionsStruct.MinimumTimeStepSize     = 1E-6;
-            OptionsStruct.TimeCutOff              = 1E6;             % in s
+            OptionsStruct.TimeCutOff              = 2E5;
             OptionsStruct.EnergyTolerance         = 5E-10;
-            OptionsStruct.ResidualTolerance       = 1E-05;
+            OptionsStruct.ResidualTolerance       = 1E-04;
             OptionsStruct.NoiseScaleFactor        = 0.010;
-    
             OptionsStruct.PlotLive                = false;
-            OptionsStruct.JobNumber               = 0;
+            OptionsStruct.JobNumber               = attempt - 1;
             OptionsStruct.RunOnGPU                = true;
             OptionsStruct.SaveData                = true;
             OptionsStruct.SaveDirectory           = saveDir;
@@ -79,35 +65,12 @@ function run_hybrid_worker_for_phase_boundary(batchParams, batchIdx)
             pot = Simulator.Potentials(options{:});
             sim.Potential = pot.trap();
 
-            NumberOfOutputs = 5;
+            [~, ~, ~, ~, ~] = sim.run();
-            try
-                [Params, Transf, psi, ~, ~, stats] = Helper.runWithProfiling(@() sim.run(), NumberOfOutputs, saveDir);
 
-                if Scripts.determineDensityModulation(psi, Params, Transf)
+            fprintf('SUCCESS | Attempt %d: a_s = %.2f\n', attempt, new_a_s);
-                    SuccessFlag = true;
-                    runDir  = fullfile(saveDir, sprintf('Run_%03d', OptionsStruct.JobNumber));
-                    psiFile = fullfile(runDir, 'psi_gs.mat');
-    
-                    if exist(psiFile, 'file')
-                        Scripts.saveUpdatedScatteringLength(psiFile, adjusted_a_s, AttemptCount);
-                    else
-                        warning('Expected file %s not found. Cannot save final a_s.', psiFile);
-                    end
-                else
-                    adjusted_a_s = adjusted_a_s - 0.2;  % Tweak as per your needs
-                end
 
         catch ME
-                fprintf('ERROR in job %d (attempt %d):\n%s\n', k, AttemptCount, getReport(ME, 'extended'));
+            fprintf('FAILURE | Attempt %d: %s\n', attempt, getReport(ME, 'basic'));
-                adjusted_a_s = adjusted_a_s - 0.2;
-            end
-        end
-    
-        if SuccessFlag
-            fprintf('Batch %d | Job %d: a_s = %.2f, theta = %d°, phi = %d°, N = %d | Time = %.2f s\n', ...
-                batchIdx, k, adjusted_a_s, theta_deg, phi_deg, N_atoms, stats.runtime);
-        else
-            fprintf('Batch %d | Job %d FAILED after %d tries.\n', batchIdx, k, MaxAttempts);
         end
     end
 

Dipolar-Gas-Simulator/+Scripts/run_hybrid_worker_for_phase_boundary_wrapper.m

@@ -30,3 +30,14 @@ function run_hybrid_worker_for_phase_boundary_wrapper(batchIdx)
     % Call worker with this batch of parameters
     Scripts.run_hybrid_worker_for_phase_boundary(batchParams, batchIdx);
 end
+
+function vals = parse_environmental_variable(varName, default)
+    str = getenv(varName);
+    if isempty(str)
+        vals = default;
+    elseif startsWith(str, '[')
+        vals = str2num(str); %#ok<ST2NM>
+    else
+        vals = eval(str);  % Trust only controlled environments
+    end
+end

Dipolar-Gas-Simulator/+Scripts/run_locally.m

@@ -557,7 +557,7 @@ SaveDirectory = './Results/Data_Full3D/PhaseDiagram/ImagTimePropagation/aS_8.312
 JobNumber     = 0;
 Plotter.visualizeGSWavefunction(SaveDirectory, JobNumber)
 %%
-SaveDirectory = 'D:/Results - Numerics/Data_Full3D/PhaseDiagram/ImagTimePropagation/Theta20/HighN/aS_9.562000e+01_theta_020_phi_000_N_1325000';
+SaveDirectory = 'D:/Results - Numerics/Data_Full3D/PhaseDiagram/ImagTimePropagation/Theta40/HighN/aS_9.250000e+01_theta_040_phi_000_N_916667';
 JobNumber     = 0;
 Plotter.visualizeGSWavefunction(SaveDirectory, JobNumber)
 %% Identify and count droplets
@@ -661,7 +661,7 @@ SCATTERING_LENGTH_RANGE ="[75.00 76.09 77.18 78.27 79.36 80.00 81.04 82.08 83.12
 NUM_ATOMS_LIST          ="[50000 54545 59091 63636 68182 72727 77273 81818 86364 90909 95455]";
 
 %% Explore the states
-SCATTERING_LENGTH_RANGE = [80.00];
+SCATTERING_LENGTH_RANGE = [97.71];
 NUM_ATOMS_LIST          = [100000 304167 508333 712500 916667 1120833 1325000 1529167 1733333 1937500 2141667 2345833 2550000 2754167 2958333 3162500 3366667 3570833 3775000 3979167 4183333 4387500 4591667 4795833 5000000];
 % NUM_ATOMS_LIST          = [4183333 4387500 4591667 4795833 5000000];
 
@@ -672,7 +672,7 @@ for i = 1:length(SCATTERING_LENGTH_RANGE)
     for j = 1:length(NUM_ATOMS_LIST)
         N = NUM_ATOMS_LIST(j);
         
-        SaveDirectory = sprintf('D:/Results - Numerics/Data_Full3D/PhaseDiagram/ImagTimePropagation/Theta20/HighN/aS_%.6e_theta_020_phi_000_N_%d', aS, N);
+        SaveDirectory = sprintf('D:/Results - Numerics/Data_Full3D/PhaseDiagram/ImagTimePropagation/Theta40/HighN/aS_%.6e_theta_040_phi_000_N_%d', aS, N);
         fprintf('Processing JobNumber %d: %s\n', JobNumber, SaveDirectory);
 
         % Call the plotting function
@@ -756,42 +756,46 @@ Scripts.editPhaseDiagram(PhaseDiagramMatrix, ScatteringLengths, NumberOfAtoms)
 
 %% Smoothen phase diagram
 load('./Results/Data_Full3D/PhaseDiagramTilted_Theta_20.mat');  % Load M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST
-TitleString = "[ \omega_x, \omega_y, \omega_z ] = 2 \pi \times [ 50, 20, 150 ] Hz; \theta = 20^\circ";
+TitleString = "[ \omega_x, \omega_y, \omega_z ] = 2 \pi \times [ 50, 20, 150 ] Hz; \theta = 40^\circ";
 
 Scripts.plotSmoothedPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, TitleString);
+
 %% Select boundary points from original phase diagram
-load('./Results/Data_Full3D/PhaseDiagramUntilted.mat')
+load('./Results/Data_Full3D/PhaseDiagramTilted_Theta_20.mat')
 M = M;
 N_atoms = round(NUM_ATOMS_LIST * 1E-5, 2);
 scatt_lengths = SCATTERING_LENGTH_RANGE;
-savePath = './Results/Data_Full3D//BoundaryPoints/SelectedPoints_Untilted_1.mat';
+savePath = './Results/Data_Full3D//BoundaryPoints/SelectedPoints_Theta20_1.mat';
 
 Scripts.selectPhaseDiagramPoints(M, N_atoms, scatt_lengths, savePath);
+
 %% Interactively modify selected boundary points
-load('./Results/Data_Full3D/PhaseDiagramUntilted.mat')
+load('./Results/Data_Full3D/PhaseDiagramTilted_Theta_20.mat')
 TitleString = "[ \omega_x, \omega_y, \omega_z ] = 2 \pi \times [ 50, 20, 150 ] Hz; \theta = 20^\circ";
 
 Scripts.plotSmoothedContourOnPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, ...
     TitleString, ...
-    './Results/Data_Full3D/BoundaryPoints/SelectedPoints_Untilted_1.mat', './Results/Data_Full3D/BoundaryPoints/SelectedPoints_Untilted_2.mat', './Results/Data_Full3D/BoundaryPoints/SelectedPoints_Untilted_3.mat', ...
+    './Results/Data_Full3D/BoundaryPoints/SelectedPoints_Theta20_1', './Results/Data_Full3D/BoundaryPoints/SelectedPoints_Theta20_2', ...
     'interpMethod', 'pchip', 'showPoints', true);
+
 %% Edit modified points
-load('./Results/Data_Full3D/PhaseDiagramUntilted.mat')
+load('./Results/Data_Full3D/PhaseDiagramTilted_Theta_20.mat')
 TitleString = "[ \omega_x, \omega_y, \omega_z ] = 2 \pi \times [ 50, 20, 150 ] Hz; \theta = 20^\circ";
 
 Scripts.plotSmoothedContourOnPhaseDiagram(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, ...
     TitleString, ...
-    './Results/Data_Full3D//BoundaryPoints/ModifiedPoints_Untilted_1.mat', './Results/Data_Full3D//BoundaryPoints/ModifiedPoints_Untilted_2.mat', './Results/Data_Full3D//BoundaryPoints/ModifiedPoints_Untilted_3.mat', ...
+    './Results/Data_Full3D/BoundaryPoints/ModifiedPoints_Theta20_1', './Results/Data_Full3D/BoundaryPoints/ModifiedPoints_Theta20_2',  ...
     'interpMethod', 'pchip', 'showPoints', true);
+
 %% Plot with interpolated phase boundary
-load('./Results/Data_Full3D/PhaseDiagramUntilted.mat')
+load('./Results/Data_Full3D/PhaseDiagramTilted_Theta_20.mat')
 PhaseDiagramMatrix   = M;
 ScatteringLengths    = SCATTERING_LENGTH_RANGE;
 NumberOfAtoms        = NUM_ATOMS_LIST;
-PhaseBoundary_Untilted = load("./Results/Data_Full3D/BoundaryPoints/PhaseBoundary_Untilted.mat");
+PhaseBoundary        = load("./Results/Data_Full3D/BoundaryPoints/PhaseBoundary_Tilted_Theta20.mat");
-TitleString = "[ \omega_x, \omega_y, \omega_z ] = 2 \pi \times [ 50, 20, 150 ] Hz; \theta = 0^\circ";
+TitleString = "[ \omega_x, \omega_y, \omega_z ] = 2 \pi \times [ 50, 20, 150 ] Hz; \theta = 20^\circ";
 
-Scripts.plotPhaseDiagramWithBoundaries(PhaseDiagramMatrix, NumberOfAtoms, ScatteringLengths, PhaseBoundary_Untilted, TitleString);
+Scripts.plotPhaseDiagramWithBoundaries(M, SCATTERING_LENGTH_RANGE, NUM_ATOMS_LIST, PhaseBoundary, TitleString);
 
 %% Density modulation determination
 

Dipolar-Gas-Simulator/submit_jobs.sh

@@ -1,11 +1,11 @@
 # ----------- Define scan ranges -----------
 
 # Use space-separated floating-point/integer values
-SCATTERING_LENGTH_RANGE="[79.0 80.0 81.0 82.0 83.0 84.0 85.0 86.0 87.0 88.0 89.0 90.0]"
+SCATTERING_LENGTH_RANGE="[75.00 76.09 77.18 78.27 79.36 80.00 81.04 82.08 83.12 84.17 85.21 86.25 87.29]"
-POLAR_ANGLE_RANGE="[0.0 20.0 30.0]"
+POLAR_ANGLE_RANGE="[40.0]"
 AZIMUTHAL_ANGLE_RANGE="[0.0]"
-NUM_ATOMS_LIST="[50000 55000 60000 65000 70000 75000 80000 85000 90000 95000 100000 105000 110000 115000 120000 125000 130000 135000 140000 145000 150000 155000 160000 165000]"
+NUM_ATOMS_LIST="[50000 54545 59091 63636 68182 72727 77273 81818 86364 90909 95455]"
-CHUNK_SIZE=4
+CHUNK_SIZE=1
 
 # ----------- Count total combinations for SLURM array -----------
 
@@ -31,8 +31,8 @@ sbatch --export=SCATTERING_LENGTH_RANGE="$SCATTERING_LENGTH_RANGE",POLAR_ANGLE_R
 #SBATCH --ntasks-per-node=1
 #SBATCH --cpus-per-task=8
 #SBATCH --gres=gpu:1
-#SBATCH --mem=16G
+#SBATCH --mem=32G
-#SBATCH --time=04:00:00
+#SBATCH --time=06:00:00
 #SBATCH --job-name=simulation
 #SBATCH --error=simulation_%A_%a.err
 #SBATCH --output=simulation_%A_%a.out

Dipolar-Gas-Simulator/submit_jobs_for_phase_boundary.sh

@@ -1,11 +1,11 @@
 # ----------- Define scan ranges -----------
 
 # Use space-separated floating-point/integer values
-SCATTERING_LENGTH_RANGE="[82.0 84.0 86.0 88.0 90.0 92.0 94.0 96.0 98.0 100.0]"
+SCATTERING_LENGTH_RANGE="[82.08 83.12 84.17 85.21 86.25 87.29 88.33]"
 POLAR_ANGLE_RANGE="[0.0]"
 AZIMUTHAL_ANGLE_RANGE="[0.0]"
-NUM_ATOMS_LIST="[50000 500000 950000 1400000 1850000 2300000 2750000 3200000 3650000 4100000 4550000 5000000]"
+NUM_ATOMS_LIST="[50000 54545 59091 63636 68182 72727 77273]"
-CHUNK_SIZE=4
+CHUNK_SIZE=1
 
 # ----------- Count total combinations for SLURM array -----------
 
@@ -39,7 +39,7 @@ sbatch --export=SCATTERING_LENGTH_RANGE="$SCATTERING_LENGTH_RANGE",POLAR_ANGLE_R
 #SBATCH --cpus-per-task=8
 #SBATCH --gres=gpu:1
 #SBATCH --mem=16G
-#SBATCH --time=04:00:00
+#SBATCH --time=12:00:00
 #SBATCH --job-name=simulation
 #SBATCH --error=simulation_%A_%a.err
 #SBATCH --output=simulation_%A_%a.out
@@ -51,7 +51,7 @@ module load math/matlab/R2023a
 echo "Initiating Job..."
 
 # Run MATLAB wrapper with this batch index
-matlab -nodisplay -nosplash -r "Scripts.run_hybrid_worker_wrapper(\$SLURM_ARRAY_TASK_ID)"
+matlab -nodisplay -nosplash -r "Scripts.run_hybrid_worker_for_phase_boundary_wrapper(\$SLURM_ARRAY_TASK_ID)"
 
 echo "Job terminated successfully"