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THMMY's "Optimization Techniques" course assignments.
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OptimizationTechniques/Work2/scripts/LevMar_script.m

LevMar_script.m 2.1 KiB
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WIP: assignment 2
vor 20 Stunden
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  1. % Define environment (functions, gradients etc...)

  2. GivenEnv

  3. 

  4. % Define parameters

  5. max_iter = 300; % Maximum iterations

  6. tol = 1e-4; % Tolerance

  7. 

  8. % Methods tuning

  9. amijo_beta = 0.5; % Armijo reduction factor

  10. amijo_sigma = 0.1; % Armijo condition constant

  11. 

  12. m = 0.01;

  13. 

  14. % Point x0 = (0, 0)

  15. % x0 = [0, 0];

  16. 

  17. 

  18. % Point x0 = (0, 0)

  19. x0s = [0, 0; -1, 1 ; 1, -1]; % Initial points

  20. for i = 1:size(x0s, 1)

  21.     x0 = x0s(i, :);

  22.     point_str = "[" + x0(1) + ", " + x0(2) + "]";

  23. 

  24.     % Find the best fixed gamma

  25.     k = zeros(100, 1);

  26.     j = 1;

  27.     n = linspace(0.1, 1.5, 100);

  28.     for g = n

  29.         gamma_fixed_step = g;

  30.         [~, ~, k(j)] = lev_mar(fun, grad_fun, hessian_fun, m, x0, tol, max_iter, 'fixed');

  31.         j = j + 1;

  32.     end

  33.     plotIterationsOverGamma(n, k, "Iteration for different $\gamma$ values", "LevMar_Iter_o_gamma_" + i + ".png");

  34. 

  35.     [~, j] = min(k);

  36.     gamma_fixed_step = n(j);

  37. 

  38.     [x_fixed, f_fixed, kk] = lev_mar(fun, grad_fun, hessian_fun, m, x0, tol, max_iter, 'fixed');

  39.     fprintf('Fixed step:     Initial point (%f, %f), steps:%d, Final (x,y)=(%f, %f), f(x,y)=%f\n', x0, kk, x_fixed(end, :), f_fixed(end));

  40.     plotPointsOverContour(x_fixed, fun, [-2, 2], [-3, 3], 100, point_str + ": LevMar $\gamma$ = " + gamma_fixed_step, "LevMar_fixed_" + i + ".png");

  41. 

  42. 

  43.     % Minimized f

  44.     [x_minimized, f_minimized, kk] = lev_mar(fun, grad_fun, hessian_fun, m, x0, tol, max_iter, 'minimized');

  45.     fprintf('Minimized f(g): Initial point (%f, %f), steps:%d, Final (x,y)=(%f, %f), f(x,y)=%f\n', x0, kk, x_minimized(end, :), f_minimized(end));

  46.     plotPointsOverContour(x_minimized, fun, [-2, 2], [-3, 3], 100, point_str + ": LevMar minimized $f(x_k + \gamma_kd_k)$", "LevMar_minimized_" + i + ".png");  

  47. 

  48. 

  49.     % Armijo Rule

  50.     [x_armijo, f_armijo, kk] = lev_mar(fun, grad_fun, hessian_fun, m, x0, tol, max_iter, 'armijo');

  51.     fprintf('Armijo step:    Initial point (%f, %f), steps:%d, Final (x,y)=(%f, %f), f(x,y)=%f\n', x0, kk, x_armijo(end, :), f_armijo(end));

  52.     plotPointsOverContour(x_armijo, fun, [-2, 2], [-3, 3], 100, point_str + ": LevMar Armijo method", "LevMar_armijo_" + i + ".png");  

  53. end

  54.