matlab: add inverted f-antenna (ifa) example

matlab/examples/antennas/ifa.m

@@ -0,0 +1,192 @@
+%
+close all
+clear
+clc
+
+%% setup the simulation
+physical_constants;
+unit = 1e-3; % all length in mm
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%                substrate.width
+%  _______________________________________________    __ substrate.
+% | A                        ifa.l                |\  __    thickness
+% | |ifa.e         __________________________     | |
+% | |             |    ___  _________________| w2 | |
+% | |       ifa.h |   |   ||                      | |
+% |_V_____________|___|___||______________________| |
+% |                .w1   .wf\                     | |
+% |                   |.fp|  \                    | |
+% |                       |    feed point         | |
+% |                       |                       | | substrate.length
+% |<- substrate.width/2 ->|                       | |
+% |                                               | |
+% |_______________________________________________| |
+%  \_______________________________________________\|
+%
+% Note: It's not checked whether your settings make sense, so check
+%       graphical output carefully.
+%
+substrate.width  = 80;             % width of substrate
+substrate.length = 80;             % length of substrate
+substrate.thickness = 1.5;         % thickness of substrate
+substrate.cells = 4;               % use 4 cells for meshing substrate
+
+ifa.h  = 8;            % height of short circuit stub
+ifa.l  = 22.5;         % length of radiating element
+ifa.w1 = 4;            % width of short circuit stub
+ifa.w2 = 2.5;          % width of radiating element
+ifa.wf = 1;            % width of feed element
+ifa.fp = 4;            % position of feed element relative to short
+                       %  circuit stub
+ifa.e  = 10;           % distance to edge
+
+
+% substrate setup
+substrate.epsR   = 4.3;
+substrate.kappa  = 1e-3 * 2*pi*2.45e9 * EPS0*substrate.epsR;
+
+%setup feeding
+feed.R = 50;     %feed resistance
+
+
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+% size of the simulation box
+SimBox = [substrate.width*2 substrate.length*2 150];
+
+%% setup FDTD parameter & excitation function
+f0 = 2.5e9; % center frequency
+fc = 1e9; % 20 dB corner frequency
+
+FDTD = InitFDTD('NrTS',  60000 );
+FDTD = SetGaussExcite( FDTD, f0, fc );
+BC = {'MUR' 'MUR' 'MUR' 'MUR' 'MUR' 'MUR'}; % boundary conditions
+%BC = {'PML_8' 'PML_8' 'PML_8' 'PML_8' 'PML_8' 'PML_8'};
+FDTD = SetBoundaryCond( FDTD, BC );
+
+%% setup CSXCAD geometry & mesh
+CSX = InitCSX();
+
+%initialize the mesh with the "air-box" dimensions
+mesh.x = [-SimBox(1)/2 SimBox(1)/2];
+mesh.y = [-SimBox(2)/2 SimBox(2)/2];
+mesh.z = [-SimBox(3)/2 SimBox(3)/2];
+
+%% create substrate
+CSX = AddMaterial( CSX, 'substrate');
+CSX = SetMaterialProperty( CSX, 'substrate', 'Epsilon',substrate.epsR, 'Kappa', substrate.kappa);
+start = [-substrate.width/2  -substrate.length/2                    0];
+stop  = [ substrate.width/2   substrate.length/2  substrate.thickness];
+CSX = AddBox( CSX, 'substrate', 1, start, stop );
+% add extra cells to discretize the substrate thickness
+mesh.z = [linspace(0,substrate.thickness,substrate.cells+1) mesh.z];
+
+%% create ground plane
+CSX = AddMetal( CSX, 'groundplane' ); % create a perfect electric conductor (PEC)
+start = [-substrate.width/2  -substrate.length/2        substrate.thickness];
+stop  = [ substrate.width/2   substrate.length/2-ifa.e  substrate.thickness];
+CSX = AddBox(CSX, 'groundplane', 10, start,stop);
+
+%% create ifa
+CSX = AddMetal( CSX, 'ifa' ); % create a perfect electric conductor (PEC)
+tl = [0,substrate.length/2-ifa.e,substrate.thickness];   % translate
+start = [0 0 0] + tl;
+stop = start + [ifa.wf ifa.h 0];
+CSX = AddBox( CSX, 'ifa', 10,  start, stop);  % feed element
+start = [-ifa.fp 0 0] + tl;
+stop =  start + [-ifa.w1 ifa.h 0];
+CSX = AddBox( CSX, 'ifa', 10,  start, stop);  % short circuit stub
+start = [(-ifa.fp-ifa.w1) ifa.h 0] + tl;
+stop = start + [ifa.l -ifa.w2 0];
+CSX = AddBox( CSX, 'ifa', 10, start, stop);   % radiating element
+
+ifa_mesh = DetectEdges(CSX, [], 'SetProperty','ifa');
+mesh.x = [mesh.x SmoothMeshLines(ifa_mesh.x, 0.5)];
+mesh.y = [mesh.y SmoothMeshLines(ifa_mesh.y, 0.5)];
+
+%% apply the excitation & resist as a current source
+start = [0 0 0] + tl;
+stop  = start + [ifa.wf 0.5 0];
+[CSX port] = AddLumpedPort(CSX, 5 ,1 ,feed.R, start, stop, [0 1 0], true);
+
+%% finalize the mesh
+% generate a smooth mesh with max. cell size: lambda_min / 20
+mesh = DetectEdges(CSX, mesh);
+mesh = SmoothMesh(mesh, c0 / (f0+fc) / unit / 20);
+CSX = DefineRectGrid(CSX, unit, mesh);
+
+%% add a nf2ff calc box; size is 3 cells away from MUR boundary condition
+start = [mesh.x(4)     mesh.y(4)     mesh.z(4)];
+stop  = [mesh.x(end-3) mesh.y(end-3) mesh.z(end-3)];
+[CSX nf2ff] = CreateNF2FFBox(CSX, 'nf2ff', start, stop);
+
+%% prepare simulation folder
+Sim_Path = 'tmp_IFA';
+Sim_CSX = 'IFA.xml';
+
+try, confirm_recursive_rmdir(false,'local'); end
+ 
+[status, message, messageid] = rmdir( Sim_Path, 's' ); % clear previous directory
+[status, message, messageid] = mkdir( Sim_Path ); % create empty simulation folder
+
+%% write openEMS compatible xml-file
+WriteOpenEMS( [Sim_Path '/' Sim_CSX], FDTD, CSX );
+
+%% show the structure
+if (show == 1)
+  CSXGeomPlot( [Sim_Path '/' Sim_CSX] );
+end
+
+
+%% run openEMS
+RunOpenEMS( Sim_Path, Sim_CSX, '--debug-PEC -v');  %RunOpenEMS( Sim_Path, Sim_CSX, '--debug-PEC -v');
+
+%% postprocessing & do the plots
+freq = linspace( max([1e9,f0-fc]), f0+fc, 501 );
+port = calcPort(port, Sim_Path, freq);
+
+Zin = port.uf.tot ./ port.if.tot;
+s11 = port.uf.ref ./ port.uf.inc;
+P_in = 0.5 * port.uf.inc .* conj( port.if.inc ); % antenna feed power
+
+% plot feed point impedance
+figure
+plot( freq/1e6, real(Zin), 'k-', 'Linewidth', 2 );
+hold on
+grid on
+plot( freq/1e6, imag(Zin), 'r--', 'Linewidth', 2 );
+title( 'feed point impedance' );
+xlabel( 'frequency f / MHz' );
+ylabel( 'impedance Z_{in} / Ohm' );
+legend( 'real', 'imag' );
+
+% plot reflection coefficient S11
+figure
+plot( freq/1e6, 20*log10(abs(s11)), 'k-', 'Linewidth', 2 );
+grid on
+title( 'reflection coefficient S_{11}' );
+xlabel( 'frequency f / MHz' );
+ylabel( 'reflection coefficient |S_{11}|' );
+
+drawnow
+
+%% NFFF contour plots %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%find resonance frequncy from s11
+f_res_ind = find(s11==min(s11));
+f_res = freq(f_res_ind);
+
+%%
+disp( 'calculating 3D far field pattern and dumping to vtk (use Paraview to visualize)...' );
+thetaRange = (0:2:180);
+phiRange = (0:2:360) - 180;
+nf2ff = CalcNF2FF(nf2ff, Sim_Path, f_res, thetaRange*pi/180, phiRange*pi/180,'Verbose',1,'Outfile','3D_Pattern.h5');
+
+plotFF3D(nf2ff)
+
+% display power and directivity
+disp( ['radiated power: Prad = ' num2str(nf2ff.Prad) ' Watt']);
+disp( ['directivity: Dmax = ' num2str(nf2ff.Dmax) ' (' num2str(10*log10(nf2ff.Dmax)) ' dBi)'] );
+disp( ['efficiency: nu_rad = ' num2str(100*nf2ff.Prad./real(P_in(f_res_ind))) ' %']);
+
+E_far_normalized = nf2ff.E_norm{1} / max(nf2ff.E_norm{1}(:)) * nf2ff.Dmax;
+DumpFF2VTK([Sim_Path '/3D_Pattern.vtk'],E_far_normalized,thetaRange,phiRange,1e-3);