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Dynamic-Calibration/ur_idntfcn_drvgns.m

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Matlab
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clc; clear all; close all;
% ------------------------------------------------------------------------
% Load data and procces it (filter and estimate accelerations)
% ------------------------------------------------------------------------
% unloadedTrajectory = parseURData('ur-20_02_12-50sec_12harm.csv', 355, 5090);
unloadedTrajectory = parseURData('ur-20_01_31-unload.csv', 300, 2623);
% unloadedTrajectory = parseURData('ur-20_02_19_14harm50sec.csv', 195, 4966);
unloadedTrajectory = filterData(unloadedTrajectory);
% loadedTrajectory = parseURData('ur-20_01_13-load_2600.csv', 250, 2274);
% loadedTrajectory = parseURData('ur-20_01_31-load.csv', 370, 2881);
loadedTrajectory = parseURData('ur-20_02_19_14harm50secLoad.csv', 308, 5071);
loadedTrajectory = filterData(loadedTrajectory);
% ------------------------------------------------------------------------
% Generate Regressors based on data
% ------------------------------------------------------------------------
% Load matrices that map standard set of paratmers to base parameters
% load('full2base_mapping.mat');
load('baseQR.mat'); % load mapping from full parameters to base parameters
E1 = baseQR.permutationMatrix(:,1:baseQR.numberOfBaseParameters);
m_load = 2.805;
% m_load = 2.602;
% Constracting regressor matrix for unloaded case
Wb_uldd = []; I_uldd = [];
for i = 1:1:length(unloadedTrajectory.t)
Y_ulddi = regressorWithMotorDynamics(unloadedTrajectory.q(i,:)',...
unloadedTrajectory.qd_fltrd(i,:)',...
unloadedTrajectory.q2d_est(i,:)');
Yfrctni = frictionRegressor(unloadedTrajectory.qd_fltrd(i,:)');
Ybi_uldd = [Y_ulddi*E1, Yfrctni];
Wb_uldd = vertcat(Wb_uldd, Ybi_uldd);
I_uldd = vertcat(I_uldd, diag(unloadedTrajectory.i_fltrd(i,:)));
end
% Constracting regressor matrix for loaded case
Wb_ldd = []; Wl = []; I_ldd = [];
for i = 1:1:length(loadedTrajectory.t)
Y_lddi = regressorWithMotorDynamics(loadedTrajectory.q(i,:)',...
loadedTrajectory.qd_fltrd(i,:)',...
loadedTrajectory.q2d_est(i,:)');
Yfrctni = frictionRegressor(loadedTrajectory.qd_fltrd(i,:)');
Ybi_ldd = [Y_lddi*E1, Yfrctni];
Yli = load_regressor_UR10E(loadedTrajectory.q(i,:)',...
loadedTrajectory.qd_fltrd(i,:)',...
loadedTrajectory.q2d_est(i,:)');
Wb_ldd = vertcat(Wb_ldd, Ybi_ldd);
Wl = vertcat(Wl,Yli);
I_ldd = vertcat(I_ldd, diag(loadedTrajectory.i_fltrd(i,:)));
end
Wl_uknown = Wl(:,1:9);
Wl_known = Wl(:,10); % mass of the load is known
%% Using total least squares
Wb_tls = [I_uldd -Wb_uldd zeros(size(I_uldd,1), size(Wl,2));
I_ldd -Wb_ldd -Wl_uknown -Wl_known*m_load];
% SVD decompostion of Wb_tls to solve total least squares
[~,~,V] = svd(Wb_tls,'econ');
% Scaling of the solution
lmda = 1/V(end,end);
pi_tls = lmda*V(:,end);
% drive gains
drvGainsTLS1 = pi_tls(1:6)
% Finding weighting matrix, joint by joint
G = zeros(6);
for i = 1:6
Wib_tls = Wb_tls(i:6:end,:);
[~,Si,Vi] = svd(Wib_tls,'econ');
sgmai = Si(end,end)/sqrt((size(Wib_tls,1)-rank(Wib_tls)));
G(i,i) = 1/sgmai^2;
end
% Weighting observation matrix
for i = 1:6:size(Wb_tls,1)
Wb_tls(i:i+5,:) = G*Wb_tls(i:i+5,:);
end
[~,~,V] = svd(Wb_tls,'econ');
lmda = 1/V(end,end);
pi_tls = lmda*V(:,end);
drvGainsTLS2 = pi_tls(1:6)
%% Identification of parameters including drive gains
Wb_ls = [I_uldd -Wb_uldd zeros(size(I_uldd,1), size(Wl_uknown,2));
I_ldd -Wb_ldd -Wl_uknown];
Yb_ts = [zeros(size(I_uldd,1),1); Wl_known*m_load];
% Compute least squares solution
pi_ls = ((Wb_ls'*Wb_ls)\Wb_ls')*Yb_ts;
drvGainsOLS1 = pi_ls(1:6)
G = zeros(6);
for i = 1:6
Wib_ls = Wb_ls(i:6:end,:);
Yib_ls = Yb_ts(i:6:end);
sgmai_sqrd = norm(Yib_ls - Wib_ls*pi_ls,2)^2/(size(Wib_ls,1)-rank(Wib_ls));
G(i,i) = 1/sqrt(sgmai_sqrd);
end
G = diag([0.05 1 1 1 1 1]);
for i = 1:6:size(Wb_ls,1)
Wb_ls(i:i+5,:) = G*Wb_ls(i:i+5,:);
Yb_ts(i:i+5) = G*Yb_ts(i:i+5);
end
pi_tot = ((Wb_ls'*Wb_ls)\Wb_ls')*Yb_ts;
drvGainsOLS2 = pi_tot(1:6)
%% Set-up SDP optimization procedure
drv_gns = sdpvar(6,1); % variables for base paramters
pi_load_unknw = sdpvar(9,1); % varaibles for unknown load paramters
pi_frctn = sdpvar(18,1);
pi_b = sdpvar(baseQR.numberOfBaseParameters,1); % variables for base paramters
pi_d = sdpvar(26,1); % variables for dependent paramters
% Bijective mapping from [pi_b; pi_d] to standard parameters pi
pii = baseQR.permutationMatrix*[ eye(baseQR.numberOfBaseParameters), ...
-baseQR.beta; ...
zeros(26,baseQR.numberOfBaseParameters), ...
eye(26) ]*[pi_b; pi_d];
% Feasibility contrraints of the link paramteres and rotor inertia
cnstr = [drv_gns(1)>10];
for i = 1:11:66
link_inertia_i = [pii(i), pii(i+1), pii(i+2); ...
pii(i+1), pii(i+3), pii(i+4); ...
pii(i+2), pii(i+4), pii(i+5)];
frst_mmnt_i = vec2skewSymMat(pii(i+6:i+8));
Di = [link_inertia_i, frst_mmnt_i'; frst_mmnt_i, pii(i+9)*eye(3)];
cnstr = [cnstr, Di>0, pii(i+10)>0];
end
% Feasibility constraints on the load paramters
load_inertia = [pi_load_unknw(1), pi_load_unknw(2), pi_load_unknw(3); ...
pi_load_unknw(2), pi_load_unknw(4), pi_load_unknw(5); ...
pi_load_unknw(3), pi_load_unknw(5), pi_load_unknw(6)];
load_frst_mmnt = vec2skewSymMat(pi_load_unknw(7:9));
Dl = [load_inertia, load_frst_mmnt'; load_frst_mmnt, m_load*eye(3)];
cnstr = [cnstr, Dl>0];
% Feasibility constraints on the friction prameters
for i = 1:6
cnstr = [cnstr, pi_frctn(3*i-2)>0, pi_frctn(3*i-1)>0];
end
% Defining pbjective function
t1 = [zeros(size(I_uldd,1),1); -Wl(:,end)*m_load];
t2 = [-I_uldd, Wb_uldd, zeros(size(Wb_uldd,1), size(Wl,2)-1); ...
-I_ldd, Wb_ldd, Wl(:,1:9) ];
obj = norm(t1 - t2*[drv_gns; pi_b; pi_frctn; pi_load_unknw]);
% Solving sdp problem
sol = optimize(cnstr,obj,sdpsettings('solver','sdpt3'));
% Getting values of the estimated patamters
drvGainsSDP = value(drv_gns)
%% Saving obtained drive gains
drvGains = drvGainsSDP;
filename = 'driveGains.mat';
save(filename,'drvGains')
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