%% Load results % JOBNUM = 0; load_results; % JOBNUM = 1; load_results; compile_results %% Retrieving max polynomial degree and sampling info Npe = numel(Pe); Nje = numel(Je); [JE,PE] = meshgrid(Je,Pe); Npi = numel(Pi); Nji = numel(Ji); [JI,PI] = meshgrid(Ji,Pi); Ns5D = numel(Ts5D); Ns2D = numel(Ts2D); % renaming and reshaping quantity of interest Ts5D = Ts5D'; Ts2D = Ts2D'; if strcmp(OUTPUTS.write_non_lin,'.true.') Si00 = squeeze(Sipj(1,1,:,:,:)); Se00 = squeeze(Sepj(1,1,:,:,:)); end %% Build grids Nkr = numel(kr); Nkz = numel(kz); [KZ,KR] = meshgrid(kz,kr); Lkr = max(kr)-min(kr); Lkz = max(kz)-min(kz); dkr = Lkr/(Nkr-1); dkz = Lkz/(Nkz-1); Lk = max(Lkr,Lkz); dr = 2*pi/Lk; dz = 2*pi/Lk; Nr = max(Nkr,Nkz); Nz = Nr; r = dr*(-Nr/2:(Nr/2-1)); Lr = max(r)-min(r); z = dz*(-Nz/2:(Nz/2-1)); Lz = max(z)-min(z); [ZZ,RR] = meshgrid(z,r); %% Analysis %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% disp('Analysis :') disp('- iFFT') % IFFT (Lower case = real space, upper case = frequency space) ne00 = zeros(Nr,Nz,Ns2D); ni00 = zeros(Nr,Nz,Ns2D); si00 = zeros(Nr,Nz,Ns5D); phi = zeros(Nr,Nz,Ns2D); drphi = zeros(Nr,Nz,Ns2D); dzphi = zeros(Nr,Nz,Ns2D); for it = 1:numel(Ts2D) NE_ = Ne00(:,:,it); NI_ = Ni00(:,:,it); PH_ = PHI(:,:,it); ne00(:,:,it) = real(fftshift(ifft2((NE_),Nr,Nz))); ni00(:,:,it) = real(fftshift(ifft2((NI_),Nr,Nz))); phi (:,:,it) = real(fftshift(ifft2((PH_),Nr,Nz))); drphi(:,:,it) = real(fftshift(ifft2(1i*KR.*(PH_),Nr,Nz))); dzphi(:,:,it) = real(fftshift(ifft2(1i*KZ.*(PH_),Nr,Nz))); end if strcmp(OUTPUTS.write_non_lin,'.true.') for it = 1:numel(Ts5D) si00(:,:,it) = real(fftshift(ifft2(squeeze(Si00(:,:,it)),Nr,Nz))); end end % Post processing disp('- post processing') E_pot = zeros(1,Ns2D); % Potential energy n^2 E_kin = zeros(1,Ns2D); % Kinetic energy grad(phi)^2 ExB = zeros(1,Ns2D); % ExB drift intensity \propto |\grad \phi| Flux_ri = zeros(1,Ns2D); % Particle flux Gamma = Flux_zi = zeros(1,Ns2D); % Particle flux Gamma = Flux_re = zeros(1,Ns2D); % Particle flux Gamma = Flux_ze = zeros(1,Ns2D); % Particle flux Gamma = Ne_norm = zeros(Npe,Nje,Ns5D);% Time evol. of the norm of Napj Ni_norm = zeros(Npi,Nji,Ns5D);% . if strcmp(OUTPUTS.write_non_lin,'.true.') Se_norm = zeros(Npe,Nje,Ns5D);% Time evol. of the norm of Sapj Si_norm = zeros(Npi,Nji,Ns5D);% . Sne00_norm = zeros(1,Ns2D); % Time evol. of the amp of e nonlin term Sni00_norm = zeros(1,Ns2D); % end Ddr = 1i*KR; Ddz = 1i*KZ; lapl = Ddr.^2 + Ddz.^2; for it = 1:numel(Ts2D) % Loop over 2D arrays NE_ = Ne00(:,:,it); NI_ = Ni00(:,:,it); PH_ = PHI(:,:,it); E_pot(it) = pi/Lr/Lz*sum(sum(abs(NI_).^2))/Nkr/Nkr; % integrate through Parseval id E_kin(it) = pi/Lr/Lz*sum(sum(abs(Ddr.*PH_).^2+abs(Ddz.*PH_).^2))/Nkr/Nkr; ExB(it) = max(max(max(abs(phi(3:end,:,it)-phi(1:end-2,:,it))/(2*dr))),max(max(abs(phi(:,3:end,it)-phi(:,1:end-2,it))'/(2*dz)))); Flux_ri(it) = sum(sum(ni00(:,:,it).*dzphi(:,:,it)))*dr*dz/Lr/Lz; Flux_zi(it) = sum(sum(-ni00(:,:,it).*drphi(:,:,it)))*dr*dz/Lr/Lz; Flux_re(it) = sum(sum(ne00(:,:,it).*dzphi(:,:,it)))*dr*dz/Lr/Lz; Flux_ze(it) = sum(sum(-ne00(:,:,it).*drphi(:,:,it)))*dr*dz/Lr/Lz; end E_kin_KZ = mean(mean(abs(Ddr.*PHI(:,:,it)).^2+abs(Ddz.*PHI(:,:,it)).^2,3),2); E_kin_KR = mean(mean(abs(Ddr.*PHI(:,:,it)).^2+abs(Ddz.*PHI(:,:,it)).^2,3),2); dEdt = diff(E_pot+E_kin)./dt2D; for it = 1:numel(Ts5D) % Loop over 5D arrays Ne_norm(:,:,it)= sum(sum(abs(Nepj(:,:,:,:,it)),3),4)/Nkr/Nkz; Ni_norm(:,:,it)= sum(sum(abs(Nipj(:,:,:,:,it)),3),4)/Nkr/Nkz; if strcmp(OUTPUTS.write_non_lin,'.true.') Se_norm(:,:,it)= sum(sum(abs(Sepj(:,:,:,:,it)),3),4)/Nkr/Nkz; Si_norm(:,:,it)= sum(sum(abs(Sipj(:,:,:,:,it)),3),4)/Nkr/Nkz; Sne00_norm(it) = sum(sum(abs(Se00(:,:,it))))/Nkr/Nkz; Sni00_norm(it) = sum(sum(abs(Si00(:,:,it))))/Nkr/Nkz; end end %% Compute growth rate disp('- growth rate') tend = Ts2D(end); tstart = 0.6*tend; g_ = zeros(Nkr,Nkz); [~,ikr0KH] = min(abs(kr-KR0KH)); for ikr = 1:Nkr for ikz = 1:Nkz g_(ikr,ikz) = LinearFit_s(Ts2D,squeeze(abs(Ni00(ikr,ikz,:))),tstart,tend); end end % gkr0kz_Ni00 = max(real(g_(:,:)),[],1); gkr0kz_Ni00 = real(g_(ikr0KH,:)); %% PLOTS %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% default_plots_options disp('Plots') FMT = '.fig'; if 0 %% Time evolutions fig = figure; FIGNAME = ['t_evolutions',sprintf('_%.2d',JOBNUM)]; set(gcf, 'Position', [100, 100, 900, 800]) subplot(221); for ip = 1:Npe for ij = 1:Nje plt = @(x) squeeze(x(ip,ij,:)); plotname = ['$N_e^{',num2str(Pe(ip)),num2str(Je(ij)),'}$']; semilogy(Ts5D,plt(Ne_norm),'DisplayName',plotname); hold on; end end grid on; ylabel('$\sum_{k_r,k_z}|N_e^{pj}|$'); subplot(222) for ip = 1:Npi for ij = 1:Nji plt = @(x) squeeze(x(ip,ij,:)); plotname = ['$N_i^{',num2str(Pi(ip)),num2str(Ji(ij)),'}$']; semilogy(Ts5D,plt(Ni_norm),'DisplayName',plotname); hold on; end end grid on; ylabel('$\sum_{k_r,k_z}|N_i^{pj}|$'); subplot(223) plot(Ts2D,Flux_ri,'-','DisplayName','$\Gamma_{ri}$'); hold on; plot(Ts2D,Flux_zi,'-','DisplayName','$\Gamma_{zi}$'); hold on; plot(Ts2D,Flux_re,'-','DisplayName','$\Gamma_{re}$') plot(Ts2D,Flux_ze,'-','DisplayName','$\Gamma_{ze}$') grid on; xlabel('$t c_s/R$'); ylabel('$\Gamma$'); %legend('show'); if strcmp(OUTPUTS.write_non_lin,'.true.') subplot(224) for ip = 1:Npi for ij = 1:Nji plt = @(x) squeeze(x(ip,ij,:)); plotname = ['$S_i^{',num2str(ip-1),num2str(ij-1),'}$']; semilogy(Ts5D,plt(Si_norm),'DisplayName',plotname); hold on; end end grid on; xlabel('$t c_s/R$'); ylabel('$\sum_{k_r,k_z}|S_i^{pj}|$'); %legend('show'); else %% Growth rate subplot(224) [~,ikr0KH] = min(abs(kr-KR0KH)); plot(kz(1:Nz/2),gkr0kz_Ni00(1:Nz/2),... 'DisplayName',['J = ',num2str(JMAXI)]); xlabel('$k_z$'); ylabel('$\gamma_{Ni}$'); xlim([0. 1.0]); %ylim([0. 0.04]); end suptitle(['$\nu_{',CONAME,'}=$', num2str(NU), ', $\eta_B=$',num2str(ETAB)]); save_figure end %% if 0 %% Photomaton : real space tf = 0; [~,it] = min(abs(Ts2D-tf)); [~,it5D] = min(abs(Ts5D-tf)); fig = figure; FIGNAME = ['photo_real',sprintf('_t=%.0f',Ts2D(it))]; set(gcf, 'Position', [100, 100, 1500, 500]) subplot(131); plt = @(x) (((x))); pclr = pcolor((RR),(ZZ),plt(ni00(:,:,it))); set(pclr, 'edgecolor','none');pbaspect([1 1 1]) xlabel('$r/\rho_s$'); ylabel('$z/\rho_s$'); legend('$n_i$'); subplot(132); plt = @(x) ((x)); DATA = plt(ni00(:,:,it))-plt(ne00(:,:,it)); pclr = pcolor((RR),(ZZ),DATA./max(max(DATA))); set(pclr, 'edgecolor','none');pbaspect([1 1 1]) xlabel('$r/\rho_s$'); legend('$n_i-n_e$'); set(gca,'ytick',[]); subplot(133); plt = @(x) ((x)); DATA = plt(phi(:,:,it)); pclr = pcolor((RR),(ZZ),DATA./max(max(DATA))); set(pclr, 'edgecolor','none');pbaspect([1 1 1]) xlabel('$r/\rho_s$'); set(gca,'ytick',[]); legend('$\phi$'); % if strcmp(OUTPUTS.write_non_lin,'.true.') % subplot(133); plt = @(x) fftshift((abs(x)),2); % pclr = pcolor((RR),(ZZ),plt(si00(:,:,it5D))); set(pclr, 'edgecolor','none');pbaspect([1 1 1]) % xlabel('$r/\rho_s$'); legend('$|S_i^{00}|$'); set(gca,'ytick',[]) % end suptitle(['$\nu_{',CONAME,'}=$', num2str(NU), ', $\eta_B=$',num2str(ETAB), sprintf(', $t c_s/R=%.0f$',Ts2D(it))]); save_figure end if 1 %% Photomaton : real space % FIELD = ni00; FNAME = 'ni'; FIELD = phi; FNAME = 'phi'; tf = 60; [~,it1] = min(abs(Ts2D-tf)); tf = 65; [~,it2] = min(abs(Ts2D-tf)); tf = 200; [~,it3] = min(abs(Ts2D-tf)); tf = 400; [~,it4] = min(abs(Ts2D-tf)); fig = figure; FIGNAME = [FNAME,'_snaps']; set(gcf, 'Position', [100, 100, 1500, 400]) subplot(141); plt = @(x) ((x)); DATA = plt(FIELD(:,:,it1)); pclr = pcolor((RR),(ZZ),DATA./max(max(DATA))); set(pclr, 'edgecolor','none');pbaspect([1 1 1]) xlabel('$r/\rho_s$'); ylabel('$z/\rho_s$');set(gca,'ytick',[]); title(sprintf('$t c_s/R=%.0f$',Ts2D(it1))); subplot(142); plt = @(x) ((x)); DATA = plt(FIELD(:,:,it2)); pclr = pcolor((RR),(ZZ),DATA./max(max(DATA))); set(pclr, 'edgecolor','none');pbaspect([1 1 1]) xlabel('$r/\rho_s$');ylabel('$z/\rho_s$'); set(gca,'ytick',[]); title(sprintf('$t c_s/R=%.0f$',Ts2D(it2))); subplot(143); plt = @(x) ((x)); DATA = plt(FIELD(:,:,it3)); pclr = pcolor((RR),(ZZ),DATA./max(max(DATA))); set(pclr, 'edgecolor','none');pbaspect([1 1 1]) xlabel('$r/\rho_s$');ylabel('$z/\rho_s$');set(gca,'ytick',[]); title(sprintf('$t c_s/R=%.0f$',Ts2D(it3))); subplot(144); plt = @(x) ((x)); DATA = plt(FIELD(:,:,it4)); pclr = pcolor((RR),(ZZ),DATA./max(max(DATA))); set(pclr, 'edgecolor','none');pbaspect([1 1 1]) xlabel('$r/\rho_s$');ylabel('$z/\rho_s$'); set(gca,'ytick',[]); title(sprintf('$t c_s/R=%.0f$',Ts2D(it4))); % suptitle(['$\',FNAME,'$, $\nu_{',CONAME,'}=$', num2str(NU), ', $\eta_B=$',num2str(ETAB),... % ', $P=',num2str(PMAXI),'$, $J=',num2str(JMAXI),'$']); save_figure end %% t0 = 0; skip_ = 1; DELAY = 0.01*skip_; FRAMES = floor(t0/(Ts2D(2)-Ts2D(1)))+1:skip_:numel(Ts2D); %% GIFS %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if 0 %% Density ion GIFNAME = ['ni',sprintf('_%.2d',JOBNUM)]; INTERP = 1; FIELD = real(ni00); X = RR; Y = ZZ; T = Ts2D; FIELDNAME = '$n_i$'; XNAME = '$r\rho_s$'; YNAME = '$z\rho_s$'; create_gif end if 0 %% Density electron GIFNAME = ['ne',sprintf('_%.2d',JOBNUM)]; INTERP = 1; FIELD = real(ne00); X = RR; Y = ZZ; T = Ts2D; FIELDNAME = '$n_e$'; XNAME = '$r\rho_s$'; YNAME = '$z\rho_s$'; create_gif end if 0 %% Density ion - electron GIFNAME = ['ni-ne',sprintf('_%.2d',JOBNUM)]; INTERP = 1; FIELD = real(ni00+ne00); X = RR; Y = ZZ; T = Ts2D; FIELDNAME = '$n_i-n_e$'; XNAME = '$r\rho_s$'; YNAME = '$z\rho_s$'; create_gif end if 0 %% Phi GIFNAME = ['phi',sprintf('_%.2d',JOBNUM)];INTERP = 1; FIELD = real(phi); X = RR; Y = ZZ; T = Ts2D; FIELDNAME = '$\phi$'; XNAME = '$r/\rho_s$'; YNAME = '$z/\rho_s$'; create_gif end if 0 %% Density ion frequency GIFNAME = ['Ni00',sprintf('_%.2d',JOBNUM)]; INTERP = 0; FIELD =ifftshift((abs(Ni00)),2); X = fftshift(KR,2); Y = fftshift(KZ,2); T = Ts2D; FIELDNAME = '$N_i^{00}$'; XNAME = '$k_r\rho_s$'; YNAME = '$k_z\rho_s$'; create_gif end if 0 %% Density ion frequency @ kr = 0 GIFNAME = ['Ni00_kr0',sprintf('_%.2d',JOBNUM)]; INTERP = 0; FIELD =(squeeze(abs(Ni00(1,:,:)))); linestyle = 'o-.'; X = (kz); T = Ts2D; YMIN = -.1; YMAX = 1.1; XMIN = min(kz); XMAX = max(kz); FIELDNAME = '$N_i^{00}(kr=0)$'; XNAME = '$k_r\rho_s$'; create_gif_1D end %% if 1 %% Space time diagramm (fig 11 Ivanov 2020) t0 = 1; t1 = 400; [~,it0] = min(abs(t0-Ts2D)); [~,it1] = min(abs(t1-Ts2D)); fig = figure; FIGNAME = 'space_time_drphi';set(gcf, 'Position', [100, 100, 1200, 400]) subplot(211) plot(Ts2D(it0:it1),Flux_ri(it0:it1)); ylabel('$\Gamma_r$'); grid on % title(['$\eta=',num2str(ETAB),'\quad',... % '\nu_{',CONAME,'}=',num2str(NU),'$']) % legend(['$P=',num2str(PMAXI),'$, $J=',num2str(JMAXI),'$']) ylim([0,1.1*max(Flux_ri(it0:it1))]); subplot(212) [TY,TX] = meshgrid(r,Ts2D(it0:it1)); pclr = pcolor(TX,TY,squeeze(mean(drphi(:,:,it0:it1),2))'); set(pclr, 'edgecolor','none'); %colorbar; xlabel('$t c_s/R$'), ylabel('$r/\rho_s$') legend('$\langle\partial_r \phi\rangle_z$') save_figure end if 0 %% Flow skip = 10; plt = @(x) x(1:skip:end,1:skip:end); tf = 120; [~,it] = min(abs(Ts2D-tf)); fig = figure; FIGNAME = 'space_time_drphi'; quiver(plt(RR),plt(ZZ),plt(dzphi(:,:,it)),plt(-drphi(:,:,it)),0); xlabel('$r$'), ylabel('$z$') title(sprintf('$v_E$, $t=%.0f c_s/R$',Ts2D(it))); end if 0 %% Growth rate fig = figure; FIGNAME = ['growth_rate',sprintf('_%.2d',JOBNUM)]; [~,ikr0KH] = min(abs(kr-KR0KH)); plot(kz/kr(ikr0KH),gkr0kz_Ni00/(kr(ikr0KH)*A0KH),'DisplayName',['J = ',num2str(JMAXI)]) xlabel('$k_z/k_{r0}$'); ylabel('$\gamma_{Ni}/(A_0k_{r0})$'); xlim([0. 1.0]); ylim([0. 0.6]); save_figure end %% if 0 %% Mode time evolution [~,ik00] = min(abs(kz)); [~,idk] = min(abs(kz-dkz)); [~,ik50] = min(abs(kz-0.5*KR0KH)); [~,ik75] = min(abs(kz-0.7*KR0KH)); [~,ik10] = min(abs(kz-1.00*KR0KH)); plt = @(x) abs(squeeze(x)); fig = figure; FIGNAME = ['mode_time_evolution',sprintf('_%.2d',JOBNUM)]; semilogy(Ts2D,plt(Ni00(ikr0KH,ik00,:)),'DisplayName', ... ['$k_z/k_{r0} = $',num2str(kz(ik00)/KR0KH)]); hold on semilogy(Ts2D,plt(Ni00(ikr0KH,idk,:)),'DisplayName', ... ['$k_z/k_{r0} = $',num2str(kz(idk)/KR0KH)]); hold on semilogy(Ts2D,plt(Ni00(ikr0KH,ik50,:)),'DisplayName', ... ['$k_z/k_{r0} = $',num2str(kz(ik50)/KR0KH)]); hold on semilogy(Ts2D,plt(Ni00(ikr0KH,ik75,:)),'DisplayName', ... ['$k_z/k_{r0} = $',num2str(kz(ik75)/KR0KH)]); hold on semilogy(Ts2D,plt(Ni00(ikr0KH,ik10,:)),'DisplayName', ... ['$k_z/k_{r0} = $',num2str(kz(ik10)/KR0KH)]); hold on xlabel('$t$'); ylabel('$\hat n_i^{00}$'); legend('show'); semilogy(Ts2D,plt(Ni00(ikr0KH,ik00,end))*exp(gkr0kz_Ni00(ik00)*(Ts2D-Ts2D(end))),'k--') semilogy(Ts2D,plt(Ni00(ikr0KH,idk,end))*exp(gkr0kz_Ni00(idk)*(Ts2D-Ts2D(end))),'k--') semilogy(Ts2D,plt(Ni00(ikr0KH,ik50,end))*exp(gkr0kz_Ni00(ik50)*(Ts2D-Ts2D(end))),'k--') semilogy(Ts2D,plt(Ni00(ikr0KH,ik75,end))*exp(gkr0kz_Ni00(ik75)*(Ts2D-Ts2D(end))),'k--') semilogy(Ts2D,plt(Ni00(ikr0KH,ik10,end))*exp(gkr0kz_Ni00(ik10)*(Ts2D-Ts2D(end))),'k--') plot(tstart*[1 1],ylim,'k-','LineWidth',0.5); plot(tend*[1 1],ylim,'k-','LineWidth',0.5); save_figure end %% if 0 %% Show frame in kspace tf = 20; [~,it] = min(abs(Ts5D-tf)); fig = figure; FIGNAME = ['krkz_frame',sprintf('_%.2d',JOBNUM)]; subplot(221); plt = @(x) fftshift((abs(x)),2); pclr = pcolor(fftshift(KR,2),fftshift(KZ,2),plt(PHI(:,:,it))); set(pclr, 'edgecolor','none'); colorbar; xlabel('$k_r$'); ylabel('$k_z$'); title(sprintf('t=%.3d',Ts5D(it))); legend('$|\hat\phi|$'); subplot(222); plt = @(x) fftshift(abs(x),2); pclr = pcolor(fftshift(KR,2),fftshift(KZ,2),plt(Ni00(:,:,it))); set(pclr, 'edgecolor','none'); colorbar; xlabel('$k_r$'); ylabel('$k_z$'); title(sprintf('t=%.3d',Ts5D(it))); legend('$|\hat n_i^{00}|$'); subplot(223); plt = @(x) fftshift(abs(x),2); pclr = pcolor(fftshift(KR,2),fftshift(KZ,2),plt(Ne00(:,:,it))); set(pclr, 'edgecolor','none'); colorbar; xlabel('$k_r$'); ylabel('$k_z$'); title(sprintf('t=%.3d',Ts5D(it))); legend('$|\hat n_e^{00}|$'); if strcmp(OUTPUTS.write_non_lin,'.true.') subplot(224); plt = @(x) fftshift((abs(x)),2); pclr = pcolor(fftshift(KR,2),fftshift(KZ,2),plt(Si00(:,:,it))); set(pclr, 'edgecolor','none'); colorbar; xlabel('$k_r$'); ylabel('$k_z$');legend('$\hat S_i^{00}$'); end save_figure end