74 lines
2.3 KiB
Matlab
74 lines
2.3 KiB
Matlab
function CSX = AddMRStub( CSX, materialname, prio, MSL_width, len, alpha, resolution, orientation, normVector, position )
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% CSX = AddMRStub( CSX, materialname, prio, MSL_width, len, alpha,
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% resolution, orientation, normVector, position )
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%
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% Microstrip Radial Stub
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%
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% CSX: CSX-object created by InitCSX()
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% materialname: property for the MSL (created by AddMetal() or AddMaterial())
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% prio: priority
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% MSL_width: width of the MSL to connect the stub to (m)
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% len: length of the radial stub (m)
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% alpha: angle subtended by the radial stub (degrees)
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% resolution: discrete angle spacing (degrees)
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% orientation: angle of main direction of the radial stub (degrees)
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% normVector: normal vector of the stub
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% position: position of the end of the MSL
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%
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% This radial stub definition is equivalent to the one Agilent ADS uses.
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%
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% example:
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% CSX = AddMRStub( CSX, 'PEC', 10, 1000, 5900, 30, 1, -90, [0 0 1], [0 -10000 254] );
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%
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%
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% Sebastian Held <sebastian.held@gmx.de>
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% Jun 1 2010
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%
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% See also InitCSX AddMetal AddMaterial
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% check normVector
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if ~(normVector(1) == normVector(2) == 0) && ...
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~(normVector(1) == normVector(3) == 0) && ...
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~(normVector(2) == normVector(3) == 0) || (sum(normVector) == 0)
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error 'normVector must have exactly one component ~= 0'
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end
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normVector = normVector ./ sum(normVector); % normVector is now a unit vector
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% convert angles to radians
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alpha_rad = alpha/180*pi;
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orientation_rad = orientation/180*pi;
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resolution_rad = resolution/180*pi;
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%
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% build stub at origin (0,0,0) and translate/rotate it later
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%
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D = 0.5 * MSL_width / sin(alpha_rad/2);
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R = cos(alpha_rad/2) * D;
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% point at the center of the MSL
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p(1,1) = 0;
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p(2,1) = -MSL_width/2;
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p(1,2) = 0;
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p(2,2) = MSL_width/2;
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for a = alpha_rad/2 : -resolution_rad : -alpha_rad/2
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p(1,end+1) = cos(a) * (D+len) - R;
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p(2,end) = sin(a) * (D+len);
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end
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% rotate
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rot = [cos(-orientation_rad), -sin(-orientation_rad); sin(-orientation_rad), cos(-orientation_rad)];
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p = (p.' * rot).';
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% translate
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idx_elevation = [1 2 3];
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idx_elevation = idx_elevation(normVector>0);
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dim1 = mod( idx_elevation, 3 ) + 1;
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dim2 = mod( idx_elevation+1, 3 ) + 1;
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p(1,:) = p(1,:) + position(dim1);
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p(2,:) = p(2,:) + position(dim2);
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elevation = position(idx_elevation);
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CSX = AddPolygon( CSX, materialname, prio, normVector, elevation, p );
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