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master-cos
Author | SHA1 | Date |
---|---|---|
EmaMaker | a94c59c489 | |
EmaMaker | 9fcadcde54 | |
EmaMaker | cceb2f1379 | |
EmaMaker | 41f0d66851 | |
EmaMaker | ceb7659bcc | |
EmaMaker | ee076259ca | |
EmaMaker | 57790779d7 | |
EmaMaker | 854247dee1 |
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@ -1,12 +1,11 @@
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function [u, ut, uc, U_corr_history, q_pred] = control_act(t, q, sim_data)
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dc = decouple_matrix(q, sim_data);
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ut = utrack(t, q, sim_data);
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ut = dc*ut;
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[uc, U_corr_history, q_pred] = ucorr(t, q, sim_data);
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ut = dc*ut;
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%uc = dc*uc;
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%uc = zeros(2,1);
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uc = dc*uc;
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u = ut+uc;
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% saturation
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u = min(sim_data.SATURATION, max(-sim_data.SATURATION, u));
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@ -30,19 +29,47 @@ function [u_corr, U_corr_history, q_pred] = ucorr(t, q, sim_data)
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if eq(pred_hor, 0)
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return
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elseif eq(pred_hor, 1)
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H = eye(2);
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f = zeros(2,1);
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T_inv = decouple_matrix(q_act, sim_data);
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ut = utrack(t, q_act, sim_data);
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%A = [T_inv; -T_inv];
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A = [eye(2); -eye(2)];
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if eq(sim_data.costfun,1)
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% minimize v, unicycle and ddr
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% actually minimize xdot^2 + ydot^2 = v
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H = 2*eye(2);
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elseif eq(sim_data.costfun,2)
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% minimize vcorr^2 + wcorr^2, unicycle and ddr
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H = T_inv;
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end
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if eq(sim_data.robot, 0)
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if eq(sim_data.costfun, 3)
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% ex3: unicycle, minimize v
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H = T_inv' * [1 0; 0 0] * T_inv;
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elseif eq(sim_data.costfun, 4)
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% ex4: unicycle, minimize w
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H = T_inv' * [0 0; 0 1] * T_inv;
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end
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else
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if eq(sim_data.costfun, 3)
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% ex1: ddr, minimize v. det(H) = 0 H not symmetric
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R = [sim_data.r/2 sim_data.r/2]
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H = T_inv' * R' * R * T_inv;
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elseif eq(sim_data.costfun, 4)
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% ex2: ddr, minimize w. det(H) = 0
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R = [sim_data.r/sim_data.d -sim_data.r/sim_data.d]
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H = T_inv' * R' * R * T_inv;
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end
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end
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f = zeros(2,1);
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A = [T_inv; -T_inv];
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%A = [eye(2); -eye(2)];
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d = T_inv*ut;
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b = [s_-d;s_+d];
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% solve qp problem
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options = optimoptions('quadprog', 'Display', 'off');
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u_corr = quadprog(H, f, A, b, [],[],[],[],[],options);
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options = optimoptions('quadprog', 'Display', 'off', 'Algorithm', 'active-set');
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u_corr = quadprog(H, f, A, b, [],[],[],[],zeros(2,1),options);
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q_pred = q_act;
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U_corr_history(:,:,1) = u_corr;
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@ -70,7 +97,7 @@ function [u_corr, U_corr_history, q_pred] = ucorr(t, q, sim_data)
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T_inv = decouple_matrix(q_act, sim_data);
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% compute inputs (v, w)/(wr, wl)
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u_ = T_inv * u_track_ + u_corr_;
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u_ = T_inv * (u_track_ + u_corr_);
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% if needed, map (wr, wl) to (v, w) for unicicle
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@ -118,28 +145,65 @@ function [u_corr, U_corr_history, q_pred] = ucorr(t, q, sim_data)
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% A will be at most PREDICTION_HORIZON * 2 * 2 (2: size of T_inv; 2:
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% accounting for T_inv and -T_inv) by PREDICTION_HORIZON (number of
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% vectors in u_corr times the number of elements [2] in each vector)
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A_deq = [];
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b_deq = [];
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H = [];
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for k=1:pred_hor
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T_inv = T_inv_pred(:,:,k);
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u_track = u_track_pred(:,:,k);
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d = T_inv*u_track;
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A_deq = blkdiag(A_deq, [T_inv; -T_inv]);
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b_deq = [b_deq; s_ - d; s_ + d];
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if eq(sim_data.costfun,1)
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% minimize v, unicycle and ddr
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% actually minimize xdot^2 + ydot^2 = v
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H = blkdiag(H, 2*eye(2));
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elseif eq(sim_data.costfun,2)
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% minimize vcorr^2 + wcorr^2, unicycle and ddr
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H = blkdiag(H, T_inv);
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H = kron(eye(pred_hor), T_inv(:, :, :));
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end
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if eq(sim_data.robot, 0)
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if eq(sim_data.costfun, 3)
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% ex3: unicycle, minimize v
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H = blkdiag(H, T_inv' * [1 0; 0 0] * T_inv);
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elseif eq(sim_data.costfun, 4)
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% ex4: unicycle, minimize w
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H = blkdiag(H, T_inv' * [0 0; 0 1] * T_inv);
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end
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else
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if eq(sim_data.costfun, 3)
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% ex1: ddr, minimize v. det(H) = 0 H not symmetric
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R = [sim_data.r/2 sim_data.r/2];
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H = blkdiag(H, T_inv' * (R') * R * T_inv);
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elseif eq(sim_data.costfun, 4)
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% ex2: ddr, minimize w. det(H) = 0
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R = [sim_data.r/sim_data.d -sim_data.r/sim_data.d];
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H = blkdiag(H, T_inv' * (R') * R * T_inv);
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end
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end
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end
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A_deq = kron(eye(pred_hor), [eye(2); -eye(2)]);
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%A_deq = kron(eye(pred_hor), [eye(2); -eye(2)]);
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%A_deq
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%b_deq
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% unknowns
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% squared norm of u_corr. H must be identity,
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% PREDICTION_HORIZON*size(u_corr)
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H = eye(pred_hor*2)*2;
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%H = eye(pred_hor*2)*2;
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%H = kron(eye(pred_hor), 2*ones(2,2));
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% no linear terms
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f = zeros(pred_hor*2, 1);
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% solve qp problem
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options = optimoptions('quadprog', 'Display', 'off');
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U_corr = quadprog(H, f, A_deq, b_deq, [],[],[],[],[],options);
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options = optimoptions('quadprog', 'Display', 'off', 'Algorithm', 'active-set');
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U_corr = quadprog(H, f, A_deq, b_deq, [],[],[],[],zeros(2*pred_hor, 1),options);
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%U_corr = lsqnonlin(@(pred_hor) ones(pred_hor, 1), U_corr_history(:,:,1), [], [], A_deq, b_deq, [], []);
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% reshape the vector of vectors to be an array, each element being
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@ -1,13 +1,11 @@
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clc
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clear all
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close all
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close allQQQ
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%load('results-diffdrive/circle/start_center/10-09-2024 13-27-12/workspace_composite.mat')
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%load('results-diffdrive/circle/start_center/10-09-2024 15-33-08/workspace_composite.mat')
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load('results-diffdrive/circle/start_center/10-09-2024 15-33-08/workspace_composite.mat')
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%load('/home/emamaker/documents/Università/tesi/tesi-sim/results-diffdrive/square/10-09-2024 13-53-35/workspace_composite.mat')
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load('results-diffdrive/figure8/toofast/10-09-2024-22-35-17/workspace_composite.mat')
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y = cell(1,3);
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21
plot_all.m
21
plot_all.m
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@ -8,25 +8,8 @@ disp('Photos will start in 3s')
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pause(3)
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PLOT_TESTS = [
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"results-diffdrive/straightline/chill/11-09-2024-16-57-01";
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"results-diffdrive/straightline/chill_errortheta_pisixths/11-09-2024-16-57-43";
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"results-diffdrive/straightline/chill_errory/11-09-2024-16-59-04";
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"results-diffdrive/straightline/toofast/11-09-2024-16-58-24";
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"results-diffdrive/circle/start_center/11-09-2024-16-59-50";
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"results-diffdrive/square/11-09-2024-17-06-14";
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"results-diffdrive/figure8/chill/11-09-2024-17-00-53";
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%"results-diffdrive/figure8/fancyreps/11-09-2024--45-28";
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"results-diffdrive/figure8/toofast/11-09-2024-17-01-43";
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"results-unicycle/straightline/chill/11-09-2024-17-07-51";
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"results-unicycle/straightline/chill_errortheta_pisixths/11-09-2024-17-08-35";
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"results-unicycle/straightline/chill_errory/11-09-2024-17-10-00";
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"results-unicycle/straightline/toofast/11-09-2024-17-09-18";
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"results-unicycle/circle/start_center/11-09-2024-17-10-48";
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"results-unicycle/square/11-09-2024-17-17-21";
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"results-unicycle/figure8/chill/11-09-2024-17-11-53";
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%"results-unicycle/figure8/fancyreps/11-09-2024--45-28";
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"results-unicycle/figure8/toofast/11-09-2024-17-12-45";
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"results-diffdrive-costfun-ddronly/circle/start_center/ddr-minv-activeset";
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"results-diffdrive-costfun-ddronly/circle/start_center/ddr-minw-activeset";
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]
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s_ = size(PLOT_TESTS)
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10
tesi.m
10
tesi.m
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@ -4,10 +4,11 @@ close all
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% options
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ROBOT = 'unicycle'
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TESTS = ["straightline/chill", "straightline/chill_errortheta_pisixths", "straightline/toofast", "straightline/chill_errory", "circle/start_center", "figure8/chill", "figure8/toofast", "square"]
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%TESTS = ["circle/start_center"]
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%TESTS = ["straightline/chill", "straightline/chill_errortheta_pisixths", "straightline/toofast", "straightline/chill_errory", "circle/start_center", "figure8/chill", "figure8/toofast", "square"]
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TESTS = ["circle/start_center"]
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% main
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s_ = size(TESTS);
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for i = 1:length(TESTS)
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clearvars -except i s_ TESTS ROBOT
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@ -29,6 +30,9 @@ for i = 1:length(TESTS)
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[ref dref] = set_trajectory(sim_data.TRAJECTORY, sim_data);
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sim_data.ref = ref;
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sim_data.dref = dref;
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%sim_data.tfin = 15;
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sim_data.costfun=4
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sim_data.tc=0.05
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% spawn a new worker for each controller
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% 1: track only
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@ -64,7 +68,7 @@ for i = 1:length(TESTS)
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% save simulation data
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f1 = [ TEST '/' char(datetime, 'dd-MM-yyyy-HH-mm-ss')]; % windows compatible name
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f = ['results-' ROBOT '/' f1];
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f = ['results-' ROBOT '-costfun/' f1];
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mkdir(f)
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% save workspace
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dsave([f '/workspace_composite.mat']);
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@ -0,0 +1,130 @@
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clc
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clear all
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close all
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% options
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ROBOT = 'unicycle'
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%TESTS = ["straightline/chill", "straightline/chill_errortheta_pisixths", "straightline/toofast", "straightline/chill_errory", "circle/start_center", "figure8/chill", "figure8/toofast", "square"]
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TESTS = ["figure8/chill"]
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CONTROLLER = 3
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% main
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s_ = size(TESTS);
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for i = 1:length(TESTS)
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clearvars -except i s_ TESTS ROBOT CONTROLLER
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close all
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% load simulation parameters common to all robots and all tests
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sim_data = load(["tests/robot_common.mat"]);
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TEST = convertStringsToChars(TESTS(i))
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% load test data (trajectory, etc)
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test_data = load(['tests/' TEST '/common.mat']);
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for fn = fieldnames(test_data)'
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sim_data.(fn{1}) = test_data.(fn{1});
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end
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% set trajectory and starting conditions
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sim_data.q0 = set_initial_conditions(sim_data.INITIAL_CONDITIONS);
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[ref dref] = set_trajectory(sim_data.TRAJECTORY, sim_data);
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sim_data.ref = ref;
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sim_data.dref = dref;
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% spawn a new worker for each contzroller
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% 1: track only
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% 2: track + 1step
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% 3: track + multistep
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% load controller-specific options
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data = load(['tests/' num2str(CONTROLLER) '.mat']);
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for fn = fieldnames(data)'
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sim_data.(fn{1}) = data.(fn{1});
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end
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% load robot-specific options
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% put here to overwrite any parameter value left over in the tests
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% .mat files, just in case
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data = load(['tests/' ROBOT '.mat']);
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for fn = fieldnames(data)'
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sim_data.(fn{1}) = data.(fn{1});
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end
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% initialize prediction horizon
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sim_data.U_corr_history = zeros(2,1,sim_data.PREDICTION_HORIZON);
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sim_data
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% simulate robot
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tic;
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[t, q, y, ref_t, U, U_track, Q_pred, Prob] = simulate_discr(sim_data);
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toc;
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disp('Done')
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% save simulation data
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f1 = [ TEST '/' char(datetime, 'dd-MM-yyyy-HH-mm-ss')]; % windows compatible name
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f = ['results-' ROBOT '-costfun2-st/' f1];
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mkdir(f)
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% save workspace
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dsave([f '/workspace_composite.mat']);
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% save test file
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copyfile(['tests/' TEST], f);
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% save figures + plot results
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% plot results
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h = figure('Name', [TEST ' ' num2str(CONTROLLER)] );
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plot_results(t, q, ref_t, U, U_track, U_track);
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% save figures
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savefig(h, [f '/figure.fig']);
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end
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%% FUNCTION DECLARATIONS
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% Discrete-time simulation
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function [t, q, y, ref_t, U, U_track, Q_pred, Prob] = simulate_discr(sim_data)
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tc = sim_data.tc;
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steps = sim_data.tfin/tc
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q = sim_data.q0';
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t = 0;
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Q_pred = zeros(sim_data.PREDICTION_HORIZON,3, steps + 1);
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Prob = cell(steps+1, 1);
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[u_discr, u_track, q_pred, prob] = control_act(t(end), q(end, :), sim_data);
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U = u_discr';
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U_track = u_track';
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Q_pred(:, :, 1) = q_pred;
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Prob{1} = prob;
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if eq(sim_data.robot, 0)
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fun = @(t, q, u_discr, sim_data) unicycle(t, q, u_discr, sim_data);
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elseif eq(sim_data.robot, 1)
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fun = @(t, q, u_discr, sim_data) diffdrive(t, q, u_discr, sim_data);
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end
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for n = 1:steps
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tspan = [(n-1)*tc n*tc];
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z0 = q(end, :);
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opt = odeset('MaxStep', 0.005);
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[v, z] = ode45(@(v, z) fun(v, z, u_discr, sim_data), tspan, z0, opt);
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q = [q; z];
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t = [t; v];
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[u_discr, u_track, q_pred, prob] = control_act(t(end), q(end, :), sim_data);
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Prob{1+n} = prob;
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U = [U; ones(length(v), 1)*u_discr'];
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U_track = [U_track; ones(length(v), 1)*u_track'];
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Q_pred(:, :, 1+n) = q_pred;
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end
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y1 = q(:, 1) + sim_data.b * cos(q(:,3));
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y2 = q(:, 2) + sim_data.b * sin(q(:,3));
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y = [y1, y2];
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ref_t = double(subs(sim_data.ref, t'))';
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end
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%%
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