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function [ ] = pick_visualization( fitness_energy, possible_lens_placement_uniq, possible_lens_placement, possible_lens_set, index, n_visualizations, q0, qf, Ltot, lambda )
%Picks n_visualizations of sets of data and graphs each 
x0 = 0;

n_possible_lens_placement = min(n_visualizations,size(possible_lens_placement_uniq,1));

for n_graph = 1:n_possible_lens_placement
    figure(n_graph)
    [w_final_trial, r_final_trial] = solution_visualization(q0, x0, qf, Ltot, optics_placer(possible_lens_placement(index(n_graph),:), possible_lens_set(index(n_graph),:)), lambda);
    
    str1=sprintf('\n f_1 = %0.4f, x_1 = %0.4f\n',possible_lens_set(index(n_graph),1),possible_lens_placement(index(n_graph),1));
    str2=sprintf('f_2 = %0.4f, x_2 = %0.4f\n',possible_lens_set(index(n_graph),2),possible_lens_placement(index(n_graph),2));
    str3=sprintf('f_3 = %0.4f, x_3 = %0.4f\n',possible_lens_set(index(n_graph),3),possible_lens_placement(index(n_graph),3));
    tstr='Solution #';
    str_w = ['w_{final}= ',num2str(w_final_trial)];
    str_r = [', r_{final}= ',num2str(r_final_trial)];
    str_E = sprintf('\nEnergy = %.4g',fitness_energy(n_graph));
    title([tstr, num2str(n_graph), str_E, str1, str2, str3, str_w, str_r]);

end

end