% % Tutorials / Circ_Waveguide % % Describtion at: % http://openems.de/index.php/Tutorial:_Circular_Waveguide % % Tested with % - Matlab 2011a / Octave 3.4.3 % - openEMS v0.0.31 % % (C) 2010-2013 Thorsten Liebig close all clear clc %% setup the simulation %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% physical_constants; unit = 1e-3; %drawing unit in mm % waveguide dimensions length = 2000; rad = 350; %waveguide radius in mm % frequency range of interest f_start = 300e6; f_stop = 500e6; mesh_res = [10 2*pi/49.999 10]; %targeted mesh resolution %% setup FDTD parameter & excitation function %%%%%%%%%%%%%%%%%%%%%%%%%%%%% FDTD = InitFDTD('EndCriteria',1e-4,'CoordSystem',1); FDTD = SetGaussExcite(FDTD,0.5*(f_start+f_stop),0.5*(f_stop-f_start)); % boundary conditions BC = [0 0 0 0 3 3]; %pml in pos. and neg. z-direction FDTD = SetBoundaryCond(FDTD,BC); %% setup CSXCAD mesh %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% CSX = InitCSX('CoordSystem',1); % init a cylindrical mesh mesh.r = SmoothMeshLines([0 rad], mesh_res(1)); %mesh in radial direction mesh.a = SmoothMeshLines([0 2*pi], mesh_res(2)); % mesh in aziumthal dir. mesh.z = SmoothMeshLines([0 length], mesh_res(3)); CSX = DefineRectGrid(CSX, unit,mesh); %% apply the waveguide port %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% start=[mesh.r(1) mesh.a(1) mesh.z(8)]; stop =[mesh.r(end) mesh.a(end) mesh.z(15)]; [CSX, port{1}] = AddCircWaveGuidePort( CSX, 0, 1, start, stop, rad*unit, 'TE11', 0, 1); start=[mesh.r(1) mesh.a(1) mesh.z(end-13)]; stop =[mesh.r(end) mesh.a(end) mesh.z(end-14)]; [CSX, port{2}] = AddCircWaveGuidePort( CSX, 0, 2, start, stop, rad*unit, 'TE11'); %% define dump box... %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% CSX = AddDump(CSX,'Et','FileType',1,'SubSampling','4,4,4'); start = [mesh.r(1) mesh.a(1) mesh.z(1)]; stop = [mesh.r(end) mesh.a(end) mesh.z(end)]; CSX = AddBox(CSX,'Et',0 , start,stop); %% Write openEMS compatoble xml-file %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Sim_Path = 'tmp'; Sim_CSX = 'circ_wg.xml'; [status, message, messageid] = rmdir(Sim_Path,'s'); [status, message, messageid] = mkdir(Sim_Path); WriteOpenEMS([Sim_Path '/' Sim_CSX],FDTD,CSX); RunOpenEMS(Sim_Path, Sim_CSX) %% postproc %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% freq = linspace(f_start,f_stop,201); port = calcPort( port, Sim_Path, freq); s11 = port{1}.uf.ref./ port{1}.uf.inc; s21 = port{2}.uf.ref./ port{1}.uf.inc; ZL = port{1}.uf.tot./port{1}.if.tot; %% plot s-parameter %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% figure plot(freq*1e-6,20*log10(abs(s11)),'k-','Linewidth',2); xlim([freq(1) freq(end)]*1e-6); grid on; hold on; plot(freq*1e-6,20*log10(abs(s21)),'r--','Linewidth',2); l = legend('S_{11}','S_{21}','Location','Best'); set(l,'FontSize',12); ylabel('S-Parameter (dB)','FontSize',12); xlabel('frequency (MHz) \rightarrow','FontSize',12); %% compare analytic and numerical wave-impedance %%%%%%%%%%%%%%%%%%%%%%%%%% figure plot(freq*1e-6,real(ZL),'Linewidth',2); hold on; grid on; plot(freq*1e-6,imag(ZL),'r--','Linewidth',2); plot(freq*1e-6,port{1}.ZL,'g-.','Linewidth',2); ylabel('ZL (\Omega)','FontSize',12); xlabel('frequency (MHz) \rightarrow','FontSize',12); xlim([freq(1) freq(end)]*1e-6); l = legend('\Re(Z_L)','\Im(Z_L)','Z_L analytic','Location','Best'); set(l,'FontSize',12);