function [CSX,port] = AddRectWaveGuidePort( CSX, prio, portnr, start, stop, dir, a, b, mode_name, exc_amp, varargin ) % function [CSX,port] = AddRectWaveGuidePort( CSX, prio, portnr, start, stop, dir, a, b, mode_name, exc_amp, varargin ) % % Create a rectangular waveguide port, including an optional excitation and probes % % Note: - The excitation will be located at the start position in the given direction % - The voltage and current probes at the stop position in the given direction % % input: % CSX: complete CSX structure (must contain a mesh) % prio: priority of primitives % start: start coordinates of waveguide port box % stop: stop coordinates of waveguide port box % dir: direction of port (0/1/2 for x/y/z-direction) % a,b: rectangular waveguide width and height (in meter) % mode_name: mode name, e.g. 'TE11' or 'TM21' % exc_amp: excitation amplitude (set 0 to be passive) % varargin: optional additional excitations options, see also AddExcitation % % output: % CSX: modified CSX structure % port: port structure to use with calcPort % % example: % % create a TE10 circular waveguide mode, using cylindircal coordinates % start=[mesh.r(1) mesh.a(1) 0 ]; % stop =[mesh.r(end) mesh.a(end) 100]; % [CSX,port] = AddCircWaveGuidePort( CSX, 99, 1, start, stop, 320e-3, 'TE11', 0, 1); % % openEMS matlab interface % ----------------------- % (c) 2013 Thorsten Liebig (thorsten.liebig@gmx.de) % % See also InitCSX, AddExcitation, calcWGPort, calcPort if (~strcmpi(mode_name(1:2),'TE')) error 'currently only TE type modes are supported' end if (nargin<10) exc_amp = 0; end m = str2double(mode_name(3)); n = str2double(mode_name(4)); % values by David M. Pozar, Microwave Engineering, third edition kc = sqrt((m*pi/a)^2 + (n*pi/b)^2); if ~isfield(CSX,'RectilinearGrid') error 'mesh needs to be defined! Use DefineRectGrid() first!'; if (~isfield(CSX.RectilinearGrid,'XLines') || ~isfield(CSX.RectilinearGrid,'YLines') || ~isfield(CSX.RectilinearGrid,'ZLines')) error 'mesh needs to be defined! Use DefineRectGrid() first!'; end end unit = CSX.RectilinearGrid.ATTRIBUTE.DeltaUnit; kc_draw = kc*unit; dir_names={'x','y','z'}; dirP = mod((dir+1),3)+1; dirPP = mod((dir+2),3)+1; nameX = ['(' dir_names{dirP} '-' num2str(start(dirP)) ')']; nameY = ['(' dir_names{dirPP} '-' num2str(start(dirPP)) ')']; %convert a&b to drawing units a = a/unit; b = b/unit; % functions by David M. Pozar, Microwave Engineering, third edition % electric field mode profile func_Ex = [num2str( n/b) '*cos(' num2str(m*pi/a) '*' nameX ')*sin(' num2str(n*pi/b) '*' nameY ')']; func_Ey = [num2str(-m/a) '*sin(' num2str(m*pi/a) '*' nameX ')*cos(' num2str(n*pi/b) '*' nameY ')']; % magnetic field mode profile func_Hx = [num2str(m/a) '*sin(' num2str(m*pi/a) '*' nameX ')*cos(' num2str(n*pi/b) '*' nameY ')']; func_Hy = [num2str(n/b) '*cos(' num2str(m*pi/a) '*' nameX ')*sin(' num2str(n*pi/b) '*' nameY ')']; func_E{dir+1} = 0; func_E{dirP} = func_Ex; func_E{dirPP} = func_Ey; func_H{dir+1} = 0; func_H{dirP} = func_Hx; func_H{dirPP} = func_Hy; [CSX,port] = AddWaveGuidePort( CSX, prio, portnr, start, stop, dir, func_E, func_H, kc, exc_amp, varargin{:} );