diff --git a/wk/dashboard.m b/wk/dashboard.m new file mode 100644 index 0000000000000000000000000000000000000000..6c4f65b69c028cad173114e510fddc2d97595a24 --- /dev/null +++ b/wk/dashboard.m @@ -0,0 +1,116 @@ +function [full_fig] = dashboard(DATA) +% Make an overview of the simulations results in one figure +full_fig = figure; +axes = 1:9; + +axes(1) = subplot(8,1,1,'parent',full_fig); +axes(2) = subplot(8,1,2,'parent',full_fig); +axes(3) = subplot(4,2,3,'parent',full_fig); +axes(4) = subplot(4,4,7,'parent',full_fig); +axes(5) = subplot(4,4,8,'parent',full_fig); +axes(6) = subplot(4,2,5,'parent',full_fig); +axes(7) = subplot(4,2,6,'parent',full_fig); +axes(8) = subplot(4,2,7,'parent',full_fig); +axes(9) = subplot(4,2,8,'parent',full_fig); + + +%% Space time diagramm (fig 11 Ivanov 2020) +options.TAVG_0 = 0.1*DATA.Ts3D(end); +options.TAVG_1 = DATA.Ts3D(end); % Averaging times duration +options.NMVA = 1; % Moving average for time traces +options.ST_FIELD = '\phi'; % chose your field to plot in spacetime diag (e.g \phi,v_x,G_x, Q_x) +options.INTERP = 1; +options.NCUT = 4; % Number of cuts for averaging and error estimation +options.RESOLUTION = 256; +PLOT = plot_radial_transport_and_spacetime(DATA,options,'GENE'); +% Put on full fig +axcp = copyobj(PLOT.ax1,full_fig); +set(axcp,'Position',get(axes(1),'position'));delete(axes(1)); +axcp = copyobj(PLOT.ax3,full_fig); +set(axcp,'Position',get(axes(2),'position'));delete(axes(2)); +colormap(axcp,bluewhitered); +close(PLOT.fig); + +%% Show f_i(vpar,mu) +options.T = [ 1]*DATA.Ts3D(end); +options.SPECIES = 'i'; +% options.PLT_FCT = 'contour'; +options.PLT_FCT = 'contourf'; +% options.PLT_FCT = 'surf'; +% options.PLT_FCT = 'surfvv'; +options.non_adiab = 0; +options.RMS = 1; % Root mean square i.e. sqrt(sum_k|f_k|^2) as in Gene +options.folder = DATA.folder; +options.iz = 'avg'; +options.FIELD = '<f_>'; +options.SPAR = linspace(-3,3,32); +options.XPERP = linspace( 0,sqrt(6),16).^2; + +options.ONED = 0; +switch DATA.CODENAME + case 'GENE' + PLOT = plot_fa_gene(options); + case 'GYACOMO' + PLOT = plot_fa(DATA,options); +end +% Put on full fig +axcp = copyobj(PLOT.ax1,full_fig); +set(axcp,'Position',get(axes(3),'position'));delete(axes(3)); +close(PLOT.fig); + +options.ONED = 1; +switch DATA.CODENAME + case 'GENE' + PLOT = plot_fa_gene(options); + case 'GYACOMO' + PLOT = plot_fa(DATA,options); +end +% Put on full fig +axcp = copyobj(PLOT.ax1,full_fig); +set(axcp,'Position',get(axes(4),'position'));delete(axes(4)); +axcp = copyobj(PLOT.ax2,full_fig); +set(axcp,'Position',get(axes(5),'position'));delete(axes(5)); +close(PLOT.fig); + +%% Time averaged spectrum +options.TIME = [100 500]; +options.NORM =1; +% options.NAME = '\phi'; +% options.NAME = 'n_i'; +options.NAME ='\Gamma_x'; +options.PLAN = 'kxky'; +options.COMPZ = 'avg'; +options.OK = 0; +options.COMPXY = 'avg'; % avg/sum/max/zero/ 2D plot otherwise +options.COMPT = 'avg'; +options.PLOT = 'semilogy'; +PLOT = spectrum_1D(DATA,options); + +% Put on full fig +axcp = copyobj(PLOT.ax1,full_fig); +set(axcp,'Position',get(axes(6),'position'));delete(axes(6)); +axcp = copyobj(PLOT.ax2,full_fig); +set(axcp,'Position',get(axes(7),'position'));delete(axes(7)); +close(PLOT.fig); + +%% Mode evolution +options.NORMALIZED = 0; +options.K2PLOT = 1; +options.TIME = 1:700; +options.KX_TW = [25 55]; %kx Growth rate time window +options.KY_TW = [0 20]; %ky Growth rate time window +options.NMA = 1; +options.NMODES = 15; +options.iz = 'avg'; +options.ik = 1; % sum, max or index +options.fftz.flag = 0; +PLOT = mode_growth_meter(DATA,options); + +% Put on full fig +axcp = copyobj(PLOT.axes(1),full_fig); +set(axcp,'Position',get(axes(8),'position'));delete(axes(8)); +axcp = copyobj(PLOT.axes(4),full_fig); +set(axcp,'Position',get(axes(9),'position'));delete(axes(9)); +set(gca,'xtick',[]); +close(PLOT.fig); +end