%% Compare D→S vs S→D Fit Values % Author: Karthik % Date: 2025-10-17 %% ---------- Load Fit Data ---------- basePath = "C:\Users\Karthik-OfficePC\Documents\GitRepositories\Calculations\Data-Analyzer\+Scripts\"; % D→S direction data = load(fullfile(basePath, "BECToDropletsToStripes\DToS_ASDFitData\fitOfMeanCurve.mat")); DToS_MeanCurveFit = data.fitOfMeanCurve; data = load(fullfile(basePath, "BECToDropletsToStripes\DToS_ASDFitData\meanOfIndividualFits.mat")); DToS_IndividualCurveFit = data.meanOfIndividualFits; data = load(fullfile(basePath, "BECToDropletsToStripes\DToS_ASDFitData\scan_reference_values.mat")); DToS_scanrefVals = data.scan_reference_values; data = load(fullfile(basePath, "BECToStripesToDroplets\SToD_ASDFitData\fitOfMeanCurve.mat")); SToD_MeanCurveFit = data.fitOfMeanCurve; data = load(fullfile(basePath, "BECToStripesToDroplets\SToD_ASDFitData\meanOfIndividualFits.mat")); SToD_IndividualCurveFit = data.meanOfIndividualFits; data = load(fullfile(basePath, "BECToStripesToDroplets\SToD_ASDFitData\scan_reference_values.mat")); SToD_scanrefVals = data.scan_reference_values; % --- Define plotting order and labels --- params = {'mu2','A2','sigma2'}; titles = {'Secondary peak position (\theta)','Secondary peak amplitude','Secondary peak width (\sigma)'}; ylabels = {'\mu_2 (rad)','A_2','\sigma_2 (rad)'}; fontName = 'Bahnschrift'; fontSize = 14; %% ========== Mean Curve Fits ========== fig1 = figure('Name','Mean Curve Fits: D→S vs S→D', ... 'Color','w', 'Position',[100 100 1750 550]); tiledlayout(1,3, 'Padding','compact', 'TileSpacing','compact'); for i = 1:numel(params) nexttile; plot(DToS_scanrefVals, DToS_MeanCurveFit.(params{i}), 'o--', 'LineWidth',1.8, ... 'MarkerSize',6, 'DisplayName','D→S'); hold on; plot(SToD_scanrefVals, SToD_MeanCurveFit.(params{i}), 's--', 'LineWidth',1.8, ... 'MarkerSize',6, 'DisplayName','S→D'); grid on; set(gca, 'FontName', fontName, 'FontSize', fontSize); xlabel('\alpha (degrees)', 'Interpreter','tex', 'FontName',fontName, 'FontSize',fontSize); ylabel(ylabels{i}, 'Interpreter','tex', 'FontName',fontName, 'FontSize',fontSize); title(titles{i}, 'FontName',fontName, 'FontSize',fontSize+2, 'FontWeight','bold'); legend('Location','northeast'); end sgtitle('Comparison of Mean Curve Fits (D→S vs S→D)', ... 'FontName',fontName, 'FontSize',fontSize+4, 'FontWeight','bold'); %% ========== Individual Curve Fits ========== fig2 = figure('Name','Individual Curve Fits: D→S vs S→D', ... 'Color','w', 'Position',[100 100 1750 550]); tiledlayout(1,3, 'Padding','compact', 'TileSpacing','compact'); for i = 1:numel(params) nexttile; plot(DToS_scanrefVals, DToS_IndividualCurveFit.(params{i}), 'o--', 'LineWidth',1.8, ... 'MarkerSize',6, 'DisplayName','D→S'); hold on; plot(SToD_scanrefVals, SToD_IndividualCurveFit.(params{i}), 's--', 'LineWidth',1.8, ... 'MarkerSize',6, 'DisplayName','S→D'); grid on; set(gca, 'FontName', fontName, 'FontSize', fontSize); xlabel('\alpha (degrees)', 'Interpreter','tex', 'FontName',fontName, 'FontSize',fontSize); ylabel(ylabels{i}, 'Interpreter','tex', 'FontName',fontName, 'FontSize',fontSize); title(titles{i}, 'FontName',fontName, 'FontSize',fontSize+2, 'FontWeight','bold'); legend('Location','northeast'); end sgtitle('Comparison of Individual Curve Fits (D→S vs S→D)', ... 'FontName',fontName, 'FontSize',fontSize+4, 'FontWeight','bold');