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THMMY's "Optimization Techniques" course assignments.
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OptimizationTechniques/Work 1/scripts/interval_over_iterations.m

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  1. function [] = interval_over_iterations(method)

  2. % Calculate and plot the [a,b] interval over the iterations for different

  3. % lambda values (min, mid, max)

  4. %

  5. % method: the minimum calculation method, one of:

  6. %       * bisections

  7. %       * golden_section

  8. %       * fibonacci

  9. %       * bisection_der

  10. % return:

  11. %       none

  12. %

  13. 

  14. 

  15. % Load the functions and interval

  16. GivenEnv;

  17. 

  18. fig_dir = 'figures';

  19. if ~exist(fig_dir, 'dir')

  20.     mkdir(fig_dir);

  21. end

  22. 

  23. % Setup

  24. % ========================

  25. %

  26. % We need to test against the same lambda values for all the methods in

  27. % order to compare them. And since epsilon (which is related to lambda)

  28. % was given for the bisection method, we base our calculations to that.

  29. %

  30. %

  31. % epsilon: e = 0.001

  32. % lambda:  l > 2e =>

  33. % lambda_min: 0.0021

  34. % lambda_max: 0.1

  35. % N: 3 points (3 lambda values min-mid-max)

  36. 

  37. N = 3;

  38. epsilon = 0.001;

  39. lambda_min = 0.0021;

  40. lambda_max = 0.1;

  41. lambda = linspace(lambda_min, lambda_max, N);

  42. k = zeros(1, N); % preallocate k

  43. n = zeros(1, N); % preallocate n

  44. 

  45. 

  46. %

  47. % Call the minimum calculation method for each lambda value for each

  48. % function and keep the number of iterations needed.

  49. % Then Plot the [a,b] interval over iterations for each lambda for each

  50. % function.

  51. %

  52. % note: In order to use the same method call for all methods, we force a 

  53. %       common interface for minimum method functions. Thus some arguments

  54. %       will not be needed for some methods (epsilon is not needed for

  55. %       bisection _der for example).

  56. %

  57. 

  58. disp(" ");

  59. for i = 1:length(funs)

  60.     figure('Name', "interval_over_iterations_" + char(method) + "_fun" + i, 'NumberTitle', 'off');

  61.     set(gcf, 'Position', [100, 100, 1280, 720]); % Set the figure size to HD

  62.     for j = 1:N

  63.         [a, b, k(j), n(j)] = method(funs(i), a_0, b_0, epsilon, lambda(j));

  64.         

  65.         fprintf('%20s(%34s ):  [a, b]= [%f, %f], @lambda=%f, iterations= %d\n', ...

  66.             char(method), char(funs(i)), a(end), b(end), lambda(j), k(j) );

  67.         

  68.         subplot(length(funs), 1, j);

  69.         plot(1:length(a), a, 'ob');

  70.         hold on

  71.         plot(1:length(b), b, '*r');

  72.         if j == 1

  73.             title(titles(i), 'Interpreter', 'latex', 'FontSize', 16);

  74.         end

  75.         xlabel("Iterations @lambda=" + lambda(j));

  76.         ylabel('[a_k, b_k]');

  77.     end

  78.     

  79.     % Print and save the figure

  80.     %fig_epsc = fullfile(fig_dir, "interval_over_iterations_" + char(method) + "_fun" + i + ".epsc");

  81.     fig_png  = fullfile(fig_dir, "interval_over_iterations_" + char(method) + "_fun" + i + ".png");

  82. 

  83.     %print(gcf, fig_epsc, '-depsc', '-r300');

  84.     print(gcf, fig_png, '-dpng', '-r300');

  85.     

  86.     close(gcf);

  87. end