function [CSX,port] = AddLumpedPort( CSX, portnr, R, start, stop, dir, excitename ) % [CSX,port] = AddLumpedPort( CSX, portnr, materialname, start, stop, dir, evec, excitename ) % % CSX: CSX-object created by InitCSX() % portnr: (integer) number of the port % R: internal resistance of the port % start: 3D start rowvector for port definition % stop: 3D end rowvector for port definition % dir: direction of of port (choices: [1 0 0], [0 1 0] or [0 0 1]) % excitename (optional): if specified, the port will be switched on (see AddExcitation()) % % the mesh must be already initialized % % example: % start = [0 0 height]; stop = [length width height]; dir = [1 0 0]; % this defines a lumped port in x-direction (dir) % the excitation/probe is placed between start(1) and stop(1) % % Sebastian Held % Jun 1 2010 % % See also InitCSX AddExcitation % check dir if ~(dir(1) == dir(2) == 0) && ~(dir(1) == dir(3) == 0) && ~(dir(2) == dir(3) == 0) || (sum(dir) == 0) error 'dir must have exactly one component ~= 0' end dir = dir ./ sum(dir); % dir is now a unit vector % get grid mesh{1} = sort(CSX.RectilinearGrid.XLines); mesh{2} = sort(CSX.RectilinearGrid.YLines); mesh{3} = sort(CSX.RectilinearGrid.ZLines); drawingunit = CSX.RectilinearGrid.ATTRIBUTE.DeltaUnit; % snap to grid idx_plane = 0; for n=1:3 start_idx = interp1( mesh{n}, 1:numel(mesh{n}), start(n), 'nearest' ); stop_idx = interp1( mesh{n}, 1:numel(mesh{n}), stop(n), 'nearest' ); if start_idx == stop_idx idx_plane = n; % two dimensional port: this is the correct index end start(n) = mesh{n}(start_idx); stop(n) = mesh{n}(stop_idx); end if idx_plane == 0 error( 'the port must be two-dimensional!' ); end % normalize start and stop nstart = min( [start;stop] ); nstop = max( [start;stop] ); % determine index (1, 2 or 3) of calibration (e-) line idx_cal = dir * [1;2;3]; % direction of calibration line if stop(idx_cal)-start(idx_cal) > 0 direction = +1; else direction = -1; end % determine the other direction (FIXME is there a better way?) idx1 = [1 2 3]; idx1 = idx1(idx1 ~= idx_plane); idx1 = idx1(idx1 ~= idx_cal); % calculate position of resistive material idx = interp1( mesh{idx_plane}, 1:numel(mesh{idx_plane}), nstart(idx_plane), 'nearest' ); delta2_n = mesh{idx_plane}(idx) - mesh{idx_plane}(idx-1); delta2_p = mesh{idx_plane}(idx+1) - mesh{idx_plane}(idx); m_start = nstart; m_stop = nstop; m_start(idx_plane) = m_start(idx_plane) - delta2_n/2; m_stop(idx_plane) = m_stop(idx_plane) + delta2_p/2; % calculate kappa l = (m_stop(idx_cal) - m_start(idx_cal)) * drawingunit; % length of the "sheet" A = (m_stop(idx1) - m_start(idx1)) * (m_stop(idx_plane) - m_start(idx_plane)) * drawingunit^2; % area of the "sheet" kappa = l/A / R; % [kappa] = S/m CSX = AddMaterial( CSX, ['port' num2str(portnr) '_sheet_resistance'], 'Isotropy', 0 ); kappa_cell = {}; kappa_cell{1} = kappa*dir(1); kappa_cell{2} = kappa*dir(2); kappa_cell{3} = kappa*dir(3); CSX = SetMaterialProperty( CSX, ['port' num2str(portnr) '_sheet_resistance'], 'Kappa', kappa_cell ); CSX = AddBox( CSX, ['port' num2str(portnr) '_sheet_resistance'], 999, m_start, m_stop ); % calculate position of the voltage probe v_start(idx_plane) = start(idx_plane); center1 = interp1( mesh{idx1}, 1:numel(mesh{idx1}), (nstart(idx1)+nstop(idx1))/2, 'nearest' ); v_start(idx1) = mesh{idx1}(center1); v_stop = v_start; v_start(idx_cal) = nstart(idx_cal); v_stop(idx_cal) = nstop(idx_cal); % calculate position of the current probe idx = interp1( mesh{idx1}, 1:numel(mesh{idx1}), nstart(idx1), 'nearest' ); delta1_n = mesh{idx1}(idx) - mesh{idx1}(idx-1); idx = interp1( mesh{idx1}, 1:numel(mesh{idx1}), nstop(idx1), 'nearest' ); delta1_p = mesh{idx1}(idx+1) - mesh{idx1}(idx); h_offset = diff(mesh{idx_cal}); idx = interp1( mesh{idx_cal} + [h_offset h_offset(end)]/2, 1:numel(mesh{idx_cal}), (nstart(idx_cal)+nstop(idx_cal))/2, 'nearest' ); i_start(idx_cal) = mesh{idx_cal}(idx) + h_offset(idx)/2; i_stop(idx_cal) = i_start(idx_cal); i_start(idx1) = nstart(idx1) - delta1_n/2; i_start(idx_plane) = nstart(idx_plane) - delta2_n/2; i_stop(idx1) = nstop(idx1) + delta1_p/2; i_stop(idx_plane) = nstop(idx_plane) + delta2_p/2; % create the probes name = ['port_ut' num2str(portnr)]; weight = -direction; CSX = AddProbe( CSX, name, 0, weight ); CSX = AddBox( CSX, name, 999, v_start, v_stop ); name = ['port_it' num2str(portnr)]; weight = direction; CSX = AddProbe( CSX, name, 1, weight ); CSX = AddBox( CSX, name, 999, i_start, i_stop ); % create port structure port.nr = portnr; port.drawingunit = CSX.RectilinearGrid.ATTRIBUTE.DeltaUnit; % port.start = start; % port.stop = stop; % port.v_start = v_start; % port.v_stop = v_stop; % port.i_start = i_start; % port.i_stop = i_stop; % port.dir = dir; port.direction = direction; % port.idx_cal = idx_cal; % port.idx1 = idx1; % port.idx1 = idx1; port.excite = 0; % create excitation if (nargin >= 7) && ~isempty(excitename) % excitation of this port is enabled port.excite = 1; e_start = nstart; e_stop = nstop; e_start(idx_plane) = start(idx_plane); % excitation-plane is determined by start vector e_stop(idx_plane) = start(idx_plane); CSX = AddExcitation( CSX, excitename, 0, -dir*direction); CSX = AddBox( CSX, excitename, 999, e_start, e_stop ); end