%beam1.k=[-1,0]; %beam1.origin=[2,0.5]; beam1.k=[0,-1]; beam1.origin=[.8,2]; %beam1.k=[-1,-1]; %beam1.origin=[2,2]; beam1.face=NA; beam1.intensity = 1; beam1.polarization = 1; % 1 for s and 2 for p beam1.status='incoming'; % could be reflected, refracted, incoming beam2=beam1; beam1.polarization = 2; % 1 for s and 2 for p beams={beam1,beam2}; n_rutile=[2.7532, 2.4885]; % n_s and n_p n_disk= [1.3751, 1.3751]; n_air= [1., 1.]; face1.vertex1=[-1,0]; face1.vertex2=[1,0]; %face1.n_right = n_air; face1.n_right = n_disk; face1.n_left= n_rutile; face2.vertex1=[1,0]; face2.vertex2=[0,1]; face2.n_right = [1, 1]; face2.n_left= n_rutile; face3.vertex1=[0,1]; face3.vertex2=[-1,0]; face3.n_right = [1, 1]; face3.n_left= n_rutile; faces={face1,face2,face3}; border1.vertex1=[-2,-2]; border1.vertex2=[2,-2]; border1.n_right = [1, 1]; border1.n_left= [1, 1]; border2.vertex1=[2,-2]; border2.vertex2=[2,2]; border2.n_right = [1, 1]; border2.n_left= [1, 1]; border3.vertex1=[2,2]; border3.vertex2=[-2,2]; border3.n_right = [1, 1]; border3.n_left= [1, 1]; border4.vertex1=[-2,2]; border4.vertex2=[-2,-2]; border4.n_right = [1, 1]; border4.n_left= [1, 1]; borders={border1,border2, border3, border4}; border_limits=[-2,-2, 2,2]; figure(1); clf; [processed_beams] = beam_trace(beams, faces, borders, border_limits ); text(-1,-1, 'red: s-polarization; blue: p-polarization'); print('beams.eps','-depsc2'); print('beams.png');