Dynamic-Calibration/planar2DOF/pndbt_data_processing.m

% clc; clear all; close all;
% get robot description
run('plnr_idntfcn.m')

% load pendubot data
% rawData = load('position_A_0.5_v_1.mat');
% rawData = load('position_A_0.7_v_0.5.mat');
% rawData = load('position_A_1.2_v_0.05.mat');
% rawData = load('position_A_1.1_v_0.01.mat');


rawData = load('position_A_1.2_v_0.4.mat');

% parse pendubot data
pendubot.time = rawData.data(:,1) - rawData.data(1,1);
pendubot.current = -rawData.data(:,2); % !!!!!!!!!!!!!!!!!
pendubot.current_desired = rawData.data(:,4);
pendubot.torque = -rawData.data(:,3); % !!!!!!!!!!!!!!

pendubot.shldr_position = rawData.data(:,7) - pi/2; % to fit model
pendubot.shldr_velocity = rawData.data(:,9);
pendubot.elbw_position = rawData.data(:,8);
pendubot.elbw_velocity = rawData.data(:,10);

% velocity estimattion from position
qd1 = zeros(size(pendubot.shldr_velocity));
qd2 = zeros(size(pendubot.elbw_velocity));
for i = 2:size(pendubot.shldr_velocity,1)-1
    qd1(i) = (pendubot.shldr_position(i+1) - pendubot.shldr_position(i-1))/...
                (pendubot.time(i+1) - pendubot.time(i-1));
    qd2(i) = (pendubot.elbw_position(i+1) - pendubot.elbw_position(i-1))/...
                (pendubot.time(i+1) - pendubot.time(i-1));
end
pendubot.shldr_velocity_estimated = qd1;
pendubot.elbw_velocity_estimated = qd2;


% filter velocties with zero phase filter
vlcty_fltr = designfilt('lowpassiir','FilterOrder',5, ...
                        'HalfPowerFrequency',0.1,'DesignMethod','butter');
pendubot.shldr_velocity_filtered = filtfilt(vlcty_fltr, pendubot.shldr_velocity);
pendubot.elbw_velocity_filtered = filtfilt(vlcty_fltr, pendubot.elbw_velocity);
pendubot.shldr_velocity_estimated = filtfilt(vlcty_fltr, pendubot.shldr_velocity_estimated);
pendubot.elbw_velocity_estimated = filtfilt(vlcty_fltr, pendubot.elbw_velocity_estimated);


% estimating accelerations based on filtered velocities
q2d1 = zeros(size(pendubot.shldr_velocity));
q2d2 = zeros(size(pendubot.elbw_velocity));
for i = 2:size(pendubot.shldr_velocity,1)-1
    q2d1(i) = (pendubot.shldr_velocity_filtered(i+1) - pendubot.shldr_velocity_filtered(i-1))/...
                (pendubot.time(i+1) - pendubot.time(i-1));
    q2d2(i) = (pendubot.elbw_velocity_filtered(i+1) - pendubot.elbw_velocity_filtered(i-1))/...
                (pendubot.time(i+1) - pendubot.time(i-1));
end
pendubot.shldr_acceleration = q2d1;
pendubot.elbow_acceleration = q2d2;

q2d1 = zeros(size(pendubot.shldr_velocity_estimated));
q2d2 = zeros(size(pendubot.elbw_velocity_estimated));
for i = 2:size(pendubot.shldr_velocity,1)-1
    q2d1(i) = (pendubot.shldr_velocity_estimated(i+1) - pendubot.shldr_velocity_estimated(i-1))/...
                (pendubot.time(i+1) - pendubot.time(i-1));
    q2d2(i) = (pendubot.elbw_velocity_estimated(i+1) - pendubot.elbw_velocity_estimated(i-1))/...
                (pendubot.time(i+1) - pendubot.time(i-1));
end
pendubot.shldr_acceleration2 = q2d1;
pendubot.elbow_acceleration2 = q2d2;


% filter estimated accelerations with zero phase filter
aclrtn_fltr = designfilt('lowpassiir','FilterOrder',5, ...
                        'HalfPowerFrequency',0.2,'DesignMethod','butter');
pendubot.shldr_acceleration_filtered = filtfilt(aclrtn_fltr, pendubot.shldr_acceleration);
pendubot.elbow_acceleration_filtered = filtfilt(aclrtn_fltr, pendubot.elbow_acceleration);

pendubot.shldr_acceleration_filtered2 = filtfilt(aclrtn_fltr, pendubot.shldr_acceleration2);
pendubot.elbow_acceleration_filtered2 = filtfilt(aclrtn_fltr, pendubot.elbow_acceleration2);

% filter torque measurements using zero phase filter
trq_fltr = designfilt('lowpassiir','FilterOrder',5, ...
                       'HalfPowerFrequency',0.1,'DesignMethod','butter');
pendubot.torque_filtered = filtfilt(trq_fltr, pendubot.torque);

%% 

return
plotJointPositions(pendubot)
plotJointVelocities(pendubot); 
plotJointAccelerations(pendubot)
plotTorque(pendubot)

plnr_visualize([pendubot.shldr_position, pendubot.elbw_position], plnr)


%% Functions


function plotTorque(pendubot)
figure
% plot(pendubot.time, pendubot.current*0.123)
hold on
plot(pendubot.time, pendubot.torque)
plot(pendubot.time, pendubot.torque_filtered, 'LineWidth', 1.5)
xlabel('$t$, sec','interpreter', 'latex')
ylabel('$\tau$, Nm', 'interpreter', 'latex');
legend('torque measured', 'torque filtered')
grid on
end

function plotJointPositions(pendubot)
figure
subplot(2,1,1)
    plot(pendubot.time, pendubot.shldr_position)
    hold on
    plot(pendubot.time, pendubot.current_desired)
    xlim([0 1])
    xlabel('$t$, sec','interpreter', 'latex')
    ylabel('$q_1$, rad','interpreter', 'latex')
    grid on
    legend('measured', 'desired')
subplot(2,1,2)
    plot(pendubot.time, pendubot.elbw_position)
    xlim([0 1])
    xlabel('$t$, sec','interpreter', 'latex')
    ylabel('$q_2$, rad','interpreter', 'latex')
    grid on
end

function plotJointVelocities(pendubot)
figure
subplot(2,1,1)
    plot(pendubot.time, pendubot.shldr_velocity)
    hold on
    plot(pendubot.time, pendubot.shldr_velocity_filtered)
    plot(pendubot.time, pendubot.shldr_velocity_estimated)
    xlim([0 5])
    xlabel('$t$, sec','interpreter', 'latex')
    ylabel('$\dot{q}_1$, rad/s','interpreter', 'latex')
    legend('measured', 'filtered', 'estimated')
    grid on
subplot(2,1,2)
    plot(pendubot.time, pendubot.elbw_velocity)
    hold on
    plot(pendubot.time, pendubot.elbw_velocity_filtered)
    plot(pendubot.time, pendubot.elbw_velocity_estimated)
    xlim([0 5])
    xlabel('t, sec','interpreter', 'latex')
    ylabel('$\dot{q}_2$, rad/s','interpreter', 'latex')
    legend('measured', 'filtered', 'estimated')
    grid on
end

function plotJointAccelerations(pendubot)
figure
subplot(2,1,1)
    plot(pendubot.time, pendubot.shldr_acceleration)
    hold on
    plot(pendubot.time, pendubot.shldr_acceleration_filtered)
    plot(pendubot.time, pendubot.shldr_acceleration_filtered2)
    xlim([0 2])
    xlabel('$t$, sec','interpreter', 'latex')
    ylabel('$\ddot{q}_1$, rad/s$^2$','interpreter', 'latex')
    legend('estimate', 'filetered estimate')
    grid on
subplot(2,1,2)
    plot(pendubot.time, pendubot.elbow_acceleration)
    hold on
    plot(pendubot.time, pendubot.elbow_acceleration_filtered)
    plot(pendubot.time, pendubot.elbow_acceleration_filtered2)
    xlim([0 2])
    xlabel('$t$, sec','interpreter', 'latex')
    ylabel('$\ddot{q}_2$, rad/s$^2$','interpreter', 'latex')
    legend('estimate', 'filetered estimate')
    grid on
end
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`% clc; clear all; close all;`
			`% get robot description`
			`run('plnr_idntfcn.m')`

			`% load pendubot data`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`% rawData = load('position_A_0.5_v_1.mat');`
indeitification of UR is changed and writeen in terms of functions in order to ease comparison of different data and drive gains. Pendubot indentification is changed to include validation with parameters from CAD 2020-02-07 12:07:15 +00:00			`% rawData = load('position_A_0.7_v_0.5.mat');`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`% rawData = load('position_A_1.2_v_0.05.mat');`
			`% rawData = load('position_A_1.1_v_0.01.mat');`


			`rawData = load('position_A_1.2_v_0.4.mat');`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00
			`% parse pendubot data`
			`pendubot.time = rawData.data(:,1) - rawData.data(1,1);`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`pendubot.current = -rawData.data(:,2); % !!!!!!!!!!!!!!!!!`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`pendubot.current_desired = rawData.data(:,4);`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`pendubot.torque = -rawData.data(:,3); % !!!!!!!!!!!!!!`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00
			`pendubot.shldr_position = rawData.data(:,7) - pi/2; % to fit model`
			`pendubot.shldr_velocity = rawData.data(:,9);`
			`pendubot.elbw_position = rawData.data(:,8);`
			`pendubot.elbw_velocity = rawData.data(:,10);`

new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`% velocity estimattion from position`
			`qd1 = zeros(size(pendubot.shldr_velocity));`
			`qd2 = zeros(size(pendubot.elbw_velocity));`
			`for i = 2:size(pendubot.shldr_velocity,1)-1`
			`qd1(i) = (pendubot.shldr_position(i+1) - pendubot.shldr_position(i-1))/...`
			`(pendubot.time(i+1) - pendubot.time(i-1));`
			`qd2(i) = (pendubot.elbw_position(i+1) - pendubot.elbw_position(i-1))/...`
			`(pendubot.time(i+1) - pendubot.time(i-1));`
			`end`
			`pendubot.shldr_velocity_estimated = qd1;`
			`pendubot.elbw_velocity_estimated = qd2;`


			`% filter velocties with zero phase filter`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`vlcty_fltr = designfilt('lowpassiir','FilterOrder',5, ...`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`'HalfPowerFrequency',0.1,'DesignMethod','butter');`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`pendubot.shldr_velocity_filtered = filtfilt(vlcty_fltr, pendubot.shldr_velocity);`
			`pendubot.elbw_velocity_filtered = filtfilt(vlcty_fltr, pendubot.elbw_velocity);`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`pendubot.shldr_velocity_estimated = filtfilt(vlcty_fltr, pendubot.shldr_velocity_estimated);`
			`pendubot.elbw_velocity_estimated = filtfilt(vlcty_fltr, pendubot.elbw_velocity_estimated);`

added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00
			`% estimating accelerations based on filtered velocities`
			`q2d1 = zeros(size(pendubot.shldr_velocity));`
			`q2d2 = zeros(size(pendubot.elbw_velocity));`
			`for i = 2:size(pendubot.shldr_velocity,1)-1`
			`q2d1(i) = (pendubot.shldr_velocity_filtered(i+1) - pendubot.shldr_velocity_filtered(i-1))/...`
			`(pendubot.time(i+1) - pendubot.time(i-1));`
			`q2d2(i) = (pendubot.elbw_velocity_filtered(i+1) - pendubot.elbw_velocity_filtered(i-1))/...`
			`(pendubot.time(i+1) - pendubot.time(i-1));`
			`end`
			`pendubot.shldr_acceleration = q2d1;`
			`pendubot.elbow_acceleration = q2d2;`

new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`q2d1 = zeros(size(pendubot.shldr_velocity_estimated));`
			`q2d2 = zeros(size(pendubot.elbw_velocity_estimated));`
			`for i = 2:size(pendubot.shldr_velocity,1)-1`
			`q2d1(i) = (pendubot.shldr_velocity_estimated(i+1) - pendubot.shldr_velocity_estimated(i-1))/...`
			`(pendubot.time(i+1) - pendubot.time(i-1));`
			`q2d2(i) = (pendubot.elbw_velocity_estimated(i+1) - pendubot.elbw_velocity_estimated(i-1))/...`
			`(pendubot.time(i+1) - pendubot.time(i-1));`
			`end`
			`pendubot.shldr_acceleration2 = q2d1;`
			`pendubot.elbow_acceleration2 = q2d2;`


added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`% filter estimated accelerations with zero phase filter`
			`aclrtn_fltr = designfilt('lowpassiir','FilterOrder',5, ...`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`'HalfPowerFrequency',0.2,'DesignMethod','butter');`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`pendubot.shldr_acceleration_filtered = filtfilt(aclrtn_fltr, pendubot.shldr_acceleration);`
			`pendubot.elbow_acceleration_filtered = filtfilt(aclrtn_fltr, pendubot.elbow_acceleration);`

new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`pendubot.shldr_acceleration_filtered2 = filtfilt(aclrtn_fltr, pendubot.shldr_acceleration2);`
			`pendubot.elbow_acceleration_filtered2 = filtfilt(aclrtn_fltr, pendubot.elbow_acceleration2);`

added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`% filter torque measurements using zero phase filter`
			`trq_fltr = designfilt('lowpassiir','FilterOrder',5, ...`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`'HalfPowerFrequency',0.1,'DesignMethod','butter');`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`pendubot.torque_filtered = filtfilt(trq_fltr, pendubot.torque);`

			`%%`
indeitification of UR is changed and writeen in terms of functions in order to ease comparison of different data and drive gains. Pendubot indentification is changed to include validation with parameters from CAD 2020-02-07 12:07:15 +00:00
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`return`
			`plotJointPositions(pendubot)`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`plotJointVelocities(pendubot);`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`plotJointAccelerations(pendubot)`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`plotTorque(pendubot)`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00
			`plnr_visualize([pendubot.shldr_position, pendubot.elbw_position], plnr)`


			`%% Functions`

new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00
			`function plotTorque(pendubot)`
			`figure`
			`% plot(pendubot.time, pendubot.current*0.123)`
			`hold on`
			`plot(pendubot.time, pendubot.torque)`
			`plot(pendubot.time, pendubot.torque_filtered, 'LineWidth', 1.5)`
			`xlabel('$t$, sec','interpreter', 'latex')`
			`ylabel('$\tau$, Nm', 'interpreter', 'latex');`
			`legend('torque measured', 'torque filtered')`
			`grid on`
			`end`

added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`function plotJointPositions(pendubot)`
			`figure`
			`subplot(2,1,1)`
			`plot(pendubot.time, pendubot.shldr_position)`
indeitification of UR is changed and writeen in terms of functions in order to ease comparison of different data and drive gains. Pendubot indentification is changed to include validation with parameters from CAD 2020-02-07 12:07:15 +00:00			`hold on`
			`plot(pendubot.time, pendubot.current_desired)`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`xlim([0 1])`
			`xlabel('$t$, sec','interpreter', 'latex')`
			`ylabel('$q_1$, rad','interpreter', 'latex')`
			`grid on`
indeitification of UR is changed and writeen in terms of functions in order to ease comparison of different data and drive gains. Pendubot indentification is changed to include validation with parameters from CAD 2020-02-07 12:07:15 +00:00			`legend('measured', 'desired')`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`subplot(2,1,2)`
			`plot(pendubot.time, pendubot.elbw_position)`
			`xlim([0 1])`
			`xlabel('$t$, sec','interpreter', 'latex')`
			`ylabel('$q_2$, rad','interpreter', 'latex')`
			`grid on`
			`end`

			`function plotJointVelocities(pendubot)`
			`figure`
			`subplot(2,1,1)`
			`plot(pendubot.time, pendubot.shldr_velocity)`
			`hold on`
			`plot(pendubot.time, pendubot.shldr_velocity_filtered)`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`plot(pendubot.time, pendubot.shldr_velocity_estimated)`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`xlim([0 5])`
			`xlabel('$t$, sec','interpreter', 'latex')`
			`ylabel('$\dot{q}_1$, rad/s','interpreter', 'latex')`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`legend('measured', 'filtered', 'estimated')`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`grid on`
			`subplot(2,1,2)`
			`plot(pendubot.time, pendubot.elbw_velocity)`
			`hold on`
			`plot(pendubot.time, pendubot.elbw_velocity_filtered)`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`plot(pendubot.time, pendubot.elbw_velocity_estimated)`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`xlim([0 5])`
			`xlabel('t, sec','interpreter', 'latex')`
			`ylabel('$\dot{q}_2$, rad/s','interpreter', 'latex')`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`legend('measured', 'filtered', 'estimated')`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`grid on`
			`end`

			`function plotJointAccelerations(pendubot)`
			`figure`
			`subplot(2,1,1)`
			`plot(pendubot.time, pendubot.shldr_acceleration)`
			`hold on`
			`plot(pendubot.time, pendubot.shldr_acceleration_filtered)`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`plot(pendubot.time, pendubot.shldr_acceleration_filtered2)`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`xlim([0 2])`
			`xlabel('$t$, sec','interpreter', 'latex')`
			`ylabel('$\ddot{q}_1$, rad/s$^2$','interpreter', 'latex')`
			`legend('estimate', 'filetered estimate')`
			`grid on`
			`subplot(2,1,2)`
			`plot(pendubot.time, pendubot.elbow_acceleration)`
			`hold on`
			`plot(pendubot.time, pendubot.elbow_acceleration_filtered)`
new trajectories for indentification. Ellipsoid constraint on the center of mass for pendubot 2020-02-21 07:57:10 +00:00			`plot(pendubot.time, pendubot.elbow_acceleration_filtered2)`
added file that check if optimized trajectory collides with table on which the robot is fixed. Moreover kinematics of UR is derived is analytical form, so it can be used in trajectory optimization in order to stay away from table, however is considerably slows down the optimization. Even on sever with 40 cpus patter search computes it for hours. Moreover, added files for identification of the pendubot. 2020-02-05 04:55:09 +00:00			`xlim([0 2])`
			`xlabel('$t$, sec','interpreter', 'latex')`
			`ylabel('$\ddot{q}_2$, rad/s$^2$','interpreter', 'latex')`
			`legend('estimate', 'filetered estimate')`
			`grid on`
			`end`