181 lines
5.6 KiB
Matlab
181 lines
5.6 KiB
Matlab
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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[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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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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end
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function [u_corr, U_corr_history, q_pred] = ucorr(t, q, sim_data)
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pred_hor = sim_data.PREDICTION_HORIZON;
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SATURATION = sim_data.SATURATION;
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PREDICTION_SATURATION_TOLERANCE = sim_data.PREDICTION_SATURATION_TOLERANCE;
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tc = sim_data.tc;
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u_corr = zeros(2,1);
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U_corr_history = zeros(2,1,sim_data.PREDICTION_HORIZON);
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q_act = q;
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u_track_pred=zeros(2,1, pred_hor);
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T_inv_pred=zeros(2,2, pred_hor);
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q_pred = [];
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s_ = SATURATION - ones(2,1)*PREDICTION_SATURATION_TOLERANCE;
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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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% minimize wcorr_r^2 + wcorr_l^2
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%H = eye(2);
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% ex1: minimize v=r(wr+wl)/2
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%H = sim_data.r*sim_data.r*0.5*ones(2,2);
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% ex2: minimize w=r(wr-wl)/d
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H = sim_data.r*sim_data.r*2*[1, -1; -1, 1]/(sim_data.d*sim_data.d);
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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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d = T_inv*ut;
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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, [], [], [],[], -s_ - d, s_-d, [], options);
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q_pred = q_act;
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U_corr_history(:,:,1) = u_corr;
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return
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else
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%if pred_hor > 1
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% move the horizon over 1 step and add trailing zeroes
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U_corr_history = cat(3, sim_data.U_corr_history(:,:, 2:end), zeros(2,1));
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%end
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%disp('start of simulation')
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% for each step in the prediction horizon, integrate the system to
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% predict its future state
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for k = 1:pred_hor
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% start from the old (known) state
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% compute the inputs, based on the old state
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% u_corr is the prediction done at some time in the past, as found in U_corr_history
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u_corr_ = U_corr_history(:, :, k);
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% u_track can be computed from q
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t_ = t + tc * (k-1);
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u_track_ = utrack(t_, q_act, 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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% if needed, map (wr, wl) to (v, w) for unicicle
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if eq(sim_data.robot, 1)
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u_ = diffdrive_to_uni(u_, sim_data);
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end
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% integrate unicycle
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theta_new = q_act(3) + tc*u_(2);
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% compute the state integrating with euler
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%x_new = q_act(1) + tc*u_(1) * cos(q_act(3));
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%y_new = q_act(2) + tc*u_(1) * sin(q_act(3));
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% compute the state integrating via runge-kutta
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x_new = q_act(1) + tc*u_(1) * cos(q_act(3) + 0.5*tc*u_(2));
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y_new = q_act(2) + tc*u_(1) * sin(q_act(3) + 0.5*tc*u_(2));
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q_new = [x_new; y_new; theta_new];
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% save history
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q_pred = [q_pred; q_new'];
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u_track_pred(:,:,k) = u_track_;
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T_inv_pred(:,:,k) = T_inv;
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% Prepare old state for next iteration
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q_act = q_new;
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end
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%{
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Now setup the qp problem
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It needs:
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- Unknowns, u_corr at each timestep. Will be encoded as a vector of
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vectors, in which every two elements is a u_j
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i.e. (u_1; u_2; u_3; ...; u_C) = (v_1; w_1; v_2, w_2; v_3, w_3; ...
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; v_C, w_C)
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It is essential that the vector stays a column, so that u'u is the
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sum of the squared norms of each u_j
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- Box constraints: a constraint for each timestep in the horizon.
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Calculated using the predicted state and inputs. They need to be
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put in matrix (Ax <= b) form
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%}
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% box constraints
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lb = [];
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ub = [];
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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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lb = [lb; -s_-d];
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ub = [ub; s_-d];
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end
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% squared norm of u_corr. H must be identity,
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H = eye(pred_hor*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, [], [], [],[],lb,ub,[],options);
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% reshape the vector of vectors to be an array, each element being
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% u_corr_j as a 2x1 vector
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% and add the prediction at t_k+C
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U_corr_history = reshape(U_corr, [2,1,pred_hor]);
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% first result is what to do now
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u_corr=U_corr_history(:,:, 1);
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end
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end
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function u_track = utrack(t, q, sim_data)
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ref_s = double(subs(sim_data.ref, t));
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dref_s = double(subs(sim_data.dref, t));
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f = feedback(q, sim_data.b);
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err = ref_s - f;
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u_track = dref_s + sim_data.K*err;
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end
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function q_track = feedback(q, b)
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q_track = [q(1) + b*cos(q(3)); q(2) + b*sin(q(3)) ];
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end
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function T_inv = decouple_matrix(q, sim_data)
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theta = q(3);
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st = sin(theta);
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ct = cos(theta);
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b = sim_data.b;
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if eq(sim_data.robot, 0)
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T_inv = [ct, st; -st/b, ct/b];
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elseif eq(sim_data.robot, 1)
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r = sim_data.r;
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d = sim_data.d;
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T_inv = [2*b*ct - d*st, d*ct + 2*b*st ; 2*b*ct + d*st, -d*ct+2*b*st] / (2*b*r);
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end
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end
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