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merge with rviz branch

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Pavel Lutskov
2019-02-08 13:58:35 +01:00
parent 89559d1b54 b774bfd6ff
commit 622ed91470
5 changed files with 610 additions and 0 deletions
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3
.gitignore vendored
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@@ -15,3 +15,6 @@ CMakeLists.txt.user
# Ignore PDFs on master
literature/
# Pictures stuff
*.png

3
CMakeLists.txt
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@@ -51,4 +51,7 @@ catkin_install_python(PROGRAMS
)
add_executable(aruco_detector src/aruco_detector.cpp)
add_executable(rviz_human src/rviz_human.cpp)
target_link_libraries(aruco_detector ${catkin_LIBRARIES})
target_link_libraries(rviz_human ${catkin_LIBRARIES})

139
script/cartesian_controller.py Executable file
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@@ -0,0 +1,139 @@
#! /usr/bin/env python
import os
import rospy
import numpy as np
import sys
from naoqi import ALProxy
import motion
motionProxy = 0
def get_transform(joint):
frame = motion.FRAME_TORSO
useSensorValues = True
result = motionProxy.getTransform(joint,frame,useSensorValues)
result = np.matrix(result)
print result
result = np.reshape(result, (4,4))
print result
return result
def cartesian_position(joint):
print 'function'
frame = motion.FRAME_TORSO
useSensorValues = True
result = motionProxy.getPosition(joint, frame, useSensorValues)
#print result
return np.array(result[:3])
def jacobian():
# get current positions/ accordint to control figure these values should actually come from the
# integration step in the previous first control loop
end_position = cartesian_position('LArm')
shoulder_position = cartesian_position('LShoulderPitch')
bicep_position = cartesian_position('LShoulderRoll')
elbow_position = cartesian_position('LElbowYaw')
forearm_position = cartesian_position('LElbowRoll')
# get transformed rotation axes, transformation to torso frame
x_axis = np.array([[1, 0, 0, 1]]).T
y_axis = np.array([[0, 1, 0, 1]]).T
z_axis = np.array([[0, 0, 1, 1]]).T
shoulder_axis = get_transform('LShoulderPitch').dot(y_axis)
bicep_axis = get_transform('LShoulderRoll').dot(z_axis)
elbow_axis = get_transform('LElbowYaw').dot(x_axis)
forearm_axis = get_transform('LElbowRoll').dot(z_axis)
# get basis vectors of jacobian
shoulder_basis = np.cross(shoulder_axis[:3].flatten(), end_position - shoulder_position)
bicep_basis = np.cross(bicep_axis[:3].flatten(), end_position - bicep_position)
elbow_basis = np.cross(elbow_axis[:3].flatten(), end_position - elbow_position)
forearm_basis = np.cross(forearm_axis[:3].flatten(), end_position - forearm_position)
# build jacobian matrix
jacobian = np.concatenate([shoulder_basis, bicep_basis, elbow_basis, forearm_basis], axis=0).T
return jacobian
def pseudo_inverse(jacobian):
return np.linalg.pinv(jacobian)
def reference_generator(p_d)
# calculate jacobian
jac_mat = jacobian()
# use jacobian to compute desired joint speed
derivative_speed = (p_d - end_position) / 5
inv_jac = pseudo_inverse(jac_mat)
angular_velocity = derivative_speed * inv_jac
# integrate over desired speed to get desired joint position
names = "LArm"
useSensors = False
commandAnglesLArm = motionProxy.getAngles(names, useSensors)
#names = "RArm"
#useSensors = False
#commandAngles = motionProxy.getAngles(names, useSensors)
goal_angleL = commandAnglesLArm + (angular_velocity * 5)
# return desired joint position and speed
return goal_angleL, commandAnglesLArm
def movement(e)
# scale joint states with matrix K
# add desired joint speed
# move robot arm
return
if __name__ == '__main__':
motionProxy = ALProxy("ALMotion", os.environ['NAO_IP'], 9559)
jacob = jacobian()
print jacob
jacob = pseudo_inverse(jacob)
print(jacob)
# given new desired coordinates
e = 1;
"""
while e bigger some value
# run reference generator to get desired joint postion and speed
# subtract current joint states
# movement
"""
#rospy.init_node('cartesian_controller')
#rospy.spin()

61
src/NAO_Jacobian.cpp Normal file
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#include <Vector3.h>
using namespace std;
// Calculate the Jacobian Matrix for the NAO
// inputs: original angles tau1 - tau4 and new angles tau1' - tau4'
// original endeffector position e1 - e4 and new endeffector position e1' - e4'
typedef struct position{
float x;
float y;
float z;
}position;
typedef struct angles{
float tau_1;
float tau_2;
float tau_3;
float tau_4;
}angles;
angles a_end, a, a_diff;
position e_end, e, e_diff;
e_diff = diff(e_end, e);
a_diff = diff(a_end, a);
vector<float> postion_vec;
postion_vec.vector::push_back(e_diff.x);
postion_vec.vector::push_back(e_diff.y);
postion_vec.vector::push_back(e_diff.z);
vector<float> angles_vec;
angles_vec.vector::push_back(a_diff.tau_1);
angles_vec.vector::push_back(a_diff.tau_2);
angles_vec.vector::push_back(a_diff.tau_3);
angles_vec.vector::push_back(a_diff.tau_4);s
vector<vector<float>> Jacobian;
for (int i = 0; i<3; i++) {
for(int j = 0; j<4; j++ ) {
Jacobian[i][j] = postion_vec[i]/angles_vec[j];
}
}
position diff(position end, position actual){
position temp;
temp.x = end.x - actual.x;
temp.y = end.y - actual.y;
temp.z = end.z - actual.z;
return temp;
}
angles diff(angles end, angles actual){
angles temp;
temp.tau_1 = end.tau_1 - actual.tau_1;
temp.tau_2 = end.tau_2 - actual.tau_2;
temp.tau_3 = end.tau_3 - actual.tau_3;
temp.tau_4 = end.tau_4 - actual.tau_4;
return temp;
}

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src/rviz_human.cpp Normal file
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#include <iostream>
#include <math.h>
#include <ros/ros.h>
#include <visualization_msgs/Marker.h>
#include <tf/transform_listener.h>
struct quarternion {
double x;
double y;
double z;
double w;
};
quarternion toQuaternion(double yaw, double pitch, double roll);
int main( int argc, char** argv )
{
ros::init(argc, argv, "rviz_human");
ros::NodeHandle n;
ros::Rate r(100);
ros::Publisher marker_pub = n.advertise<visualization_msgs::Marker>(
"visualization_marker", 10
);
tf::TransformListener tll;
int i = 0;
int walk = 0;
float l_leg_y = 0.0;
float r_leg_y = 0.0;
// suppose we already have the position of the center marker
// in the correct frame
float x_start = 2;
float y_start = 0;
float z_start = 1.3;
float x_0 = 2;
float y_0 = 0;
float z_0 = 1.3;
float x_1 = 0;
float y_1 = 0;
float z_1 = 0;
while (ros::ok())
{
// tried to subscribe to tf to recieve marker coordinates
tf::StampedTransform aruco_0_tf;
tf::StampedTransform aruco_1_tf;
tf::StampedTransform aruco_2_tf;
try {
tll.lookupTransform(
"/odom", "/Aruco_0_frame",ros::Time(0), aruco_0_tf);
/*ROS_INFO("0: %f",aruco_0_tf.getOrigin()[0]);
ROS_INFO("1: %f",aruco_0_tf.getOrigin()[1]);
ROS_INFO("2: %f",aruco_0_tf.getOrigin()[2]);
*/
tll.lookupTransform(
"/Aruco_0_frame", "/Aruco_1_frame",ros::Time(0), aruco_1_tf);
/*
ROS_INFO("0_1: %f",aruco_1_tf.getOrigin()[0]);
ROS_INFO("1_1: %f",aruco_1_tf.getOrigin()[1]);
ROS_INFO("2_1: %f",aruco_1_tf.getOrigin()[2]);
*/
x_0 = aruco_0_tf.getOrigin()[0];
y_0 = aruco_0_tf.getOrigin()[1];
z_0 = aruco_0_tf.getOrigin()[2];
x_1 = aruco_1_tf.getOrigin()[0];
y_1 = aruco_1_tf.getOrigin()[1];
z_1 = aruco_1_tf.getOrigin()[2];
}
/*
catch (tf::TransformException ex){
ROS_ERROR("%s",ex.what());
ros::Duration(1.0).sleep();
}
try{
*/
catch (tf::TransformException ex) {
ROS_ERROR("%s",ex.what());
ros::Duration(1.0).sleep();
}
visualization_msgs::Marker body;
visualization_msgs::Marker head;
visualization_msgs::Marker l_leg;
visualization_msgs::Marker r_leg;
visualization_msgs::Marker l_arm;
visualization_msgs::Marker r_arm;
visualization_msgs::Marker camera;
// Set the frame ID and timestamp.
// See the TF tutorials for information on these.
body.header.frame_id = "/odom";
body.header.stamp = ros::Time::now();
head.header.frame_id = "/odom";
head.header.stamp = ros::Time::now();
l_leg.header.frame_id = "/odom";
l_leg.header.stamp = ros::Time::now();
r_leg.header.frame_id = "/odom";
r_leg.header.stamp = ros::Time::now();
l_arm.header.frame_id = "/odom";
l_arm.header.stamp = ros::Time::now();
r_arm.header.frame_id = "/odom";
r_arm.header.stamp = ros::Time::now();
camera.header.frame_id = "/odom";
camera.header.stamp = ros::Time::now();
body.ns = "body";
body.id = 0;
head.ns = "head";
head.id = 1;
l_leg.ns = "l_leg";
l_leg.id = 2;
r_leg.ns = "r_leg";
r_leg.id = 3;
l_arm.ns = "l_arm";
l_arm.id = 4;
r_arm.ns = "r_arm";
r_arm.id = 5;
camera.ns = "r_arm";
camera.id = 6;
body.type = visualization_msgs::Marker::CUBE;
head.type = visualization_msgs::Marker::SPHERE;
l_leg.type = visualization_msgs::Marker::CYLINDER;
r_leg.type = visualization_msgs::Marker::CYLINDER;
l_arm.type = visualization_msgs::Marker::CYLINDER;
r_arm.type = visualization_msgs::Marker::CYLINDER;
camera.type = visualization_msgs::Marker::CUBE;
// Set the marker action.
// Options are ADD, DELETE, and new in ROS Indigo: 3 (DELETEALL)
body.action = visualization_msgs::Marker::ADD;
head.action = visualization_msgs::Marker::ADD;
l_arm.action = visualization_msgs::Marker::ADD;
r_arm.action = visualization_msgs::Marker::ADD;
l_leg.action = visualization_msgs::Marker::ADD;
r_arm.action = visualization_msgs::Marker::ADD;
camera.action = visualization_msgs::Marker::ADD;
// Set the pose of the marker.
// This is a full 6DOF pose relative to the
// frame/time specified in the header
body.pose.position.x = x_0;
body.pose.position.y = y_0;
body.pose.position.z = z_0;
body.pose.orientation.x = 0.0;
body.pose.orientation.y = 0.0;
body.pose.orientation.z = 0.0;
body.pose.orientation.w = 1.0;
head.pose.position.x = x_0;
head.pose.position.y = y_0;
head.pose.position.z = z_0+0.5; //1.85
head.pose.orientation.x = 0.0;
head.pose.orientation.y = 0.0;
head.pose.orientation.z = 0.0;
head.pose.orientation.w = 1.0;
l_leg.pose.position.x = x_0;
l_leg.pose.position.y = y_0+0.2;
l_leg.pose.position.z = z_0-0.8; //0.4
l_leg.pose.orientation.x = 0.0;
l_leg.pose.orientation.y = l_leg_y;
l_leg.pose.orientation.z = 0.0;
l_leg.pose.orientation.w = 1.0;
r_leg.pose.position.x = x_0;
r_leg.pose.position.y = y_0-0.2;
r_leg.pose.position.z = z_0-0.8; //0.4
r_leg.pose.orientation.x = 0.0;
r_leg.pose.orientation.y = r_leg_y;
r_leg.pose.orientation.z = 0.0;
r_leg.pose.orientation.w = 1.0;
// calculate left arm angel in z y plane; arm length is 0.5
float alpha = atan(z_1/y_1);
float delta_z = 0;//0.25*sin(alpha);
float delta_y = 0;//0.35*cos(alpha);
//rad to degree
alpha = alpha*180/3.1415;
quarternion q = toQuaternion(0,0, alpha);
ROS_INFO("x: %f, y: %f, z: %f", x_1, y_1, z_1);
ROS_INFO("alpha: %f, z: %f, y: %f", alpha, delta_z, delta_y);
ROS_INFO("qx: %f, qy: %f, qz: %f, qw: %f", q.x,q.y,q.z,q.w);
l_arm.pose.position.x = x_0;
l_arm.pose.position.y = y_0+0.4+delta_y;
l_arm.pose.position.z = z_0+0.3+delta_z; //1.6
l_arm.pose.orientation.x = 0.0+q.x;//+alpha;
l_arm.pose.orientation.y = 0.0+q.y;
l_arm.pose.orientation.z = 0.0+q.z;
l_arm.pose.orientation.w = 1.0+q.w;
r_arm.pose.position.x = x_0;
r_arm.pose.position.y = y_0-0.4;
r_arm.pose.position.z = z_0+0.3; //1.6
r_arm.pose.orientation.x = 1.0;
r_arm.pose.orientation.y = 0.0;
r_arm.pose.orientation.z = 0.0;
r_arm.pose.orientation.w = 1.0;
camera.pose.position.x = 0;
camera.pose.position.y = 0;
camera.pose.position.z = 0.5;
camera.pose.orientation.x = 0.0;
camera.pose.orientation.y = 0.0;
camera.pose.orientation.z = 0.0;
camera.pose.orientation.w = 0.0;
// Set the scale of the marker -- 1x1x1 here means 1m on a side
body.scale.x = 0.2;
body.scale.y = 0.4;
body.scale.z = 0.8;
head.scale.x = 0.3;
head.scale.y = 0.3;
head.scale.z = 0.4;
l_leg.scale.x = 0.2;
l_leg.scale.y = 0.2;
l_leg.scale.z = 0.9;
r_leg.scale.x = 0.2;
r_leg.scale.y = 0.2;
r_leg.scale.z = 0.9;
l_arm.scale.x = 0.2;
l_arm.scale.y = 0.2;
l_arm.scale.z = 0.5;
r_arm.scale.x = 0.2;
r_arm.scale.y = 0.2;
r_arm.scale.z = 0.5;
camera.scale.x = 0.5;
camera.scale.y = 0.5;
camera.scale.z = 1;
// Set the color -- be sure to set alpha to something non-zero!
body.color.r = 0.0f;
body.color.g = 1.0f;
body.color.b = 0.5f;
body.color.a = 1.0;
head.color.r = 0.0f;
head.color.g = 1.0f;
head.color.b = 0.0f;
head.color.a = 1.0;
l_leg.color.r = 1.0f;
l_leg.color.g = 0.5f;
l_leg.color.b = 0.0f;
l_leg.color.a = 1.0;
r_leg.color.r = 1.0f;
r_leg.color.g = 0.5f;
r_leg.color.b = 0.0f;
r_leg.color.a = 1.0;
l_arm.color.r = 1.0f;
l_arm.color.g = 0.5f;
l_arm.color.b = 1.0f;
l_arm.color.a = 1.0;
r_arm.color.r = 1.0f;
r_arm.color.g = 0.5f;
r_arm.color.b = 1.0f;
r_arm.color.a = 1.0;
camera.color.r = 1.0f;
camera.color.g = 1.0f;
camera.color.b = 1.0f;
camera.color.a = 1.0;
body.lifetime = ros::Duration();
head.lifetime = ros::Duration();
l_leg.lifetime = ros::Duration();
r_leg.lifetime = ros::Duration();
l_arm.lifetime = ros::Duration();
r_arm.lifetime = ros::Duration();
camera.lifetime = ros::Duration();
// Publish the marker
while (marker_pub.getNumSubscribers() < 1)
{
if (!ros::ok())
{
return 0;
}
ROS_WARN_ONCE("Please create a subscriber to the marker");
sleep(1);
}
// little walking animation
i++;
if(i % 100 == 0)
{
if(walk == 0)
{
walk = 1;
l_leg_y = 0.2;
r_leg_y = -0.2;
}
else
{
l_leg_y = -0.2;
r_leg_y = 0.2;
walk = 0;
}
}
// move hole human
i++;
// publish markers
body.action = visualization_msgs::Marker::ADD;
head.action = visualization_msgs::Marker::ADD;
l_arm.action = visualization_msgs::Marker::ADD;
r_arm.action = visualization_msgs::Marker::ADD;
l_leg.action = visualization_msgs::Marker::ADD;
r_arm.action = visualization_msgs::Marker::ADD;
marker_pub.publish(body);
marker_pub.publish(head);
marker_pub.publish(l_leg);
marker_pub.publish(r_leg);
marker_pub.publish(l_arm);
marker_pub.publish(r_arm);
marker_pub.publish(camera);
i = i +1;
r.sleep();
}
}
quarternion toQuaternion( double yaw, double pitch, double roll) {
// Abbreviations for the various angular functions
double cy = cos(yaw * 0.5);
double sy = sin(yaw * 0.5);
double cp = cos(pitch * 0.5);
double sp = sin(pitch * 0.5);
double cr = cos(roll * 0.5);
double sr = sin(roll * 0.5);
quarternion q;
q.x = cy * cp * sr - sy * sp * cr;
q.y = sy * cp * sr + cy * sp * cr;
q.z = sy * cp * cr - cy * sp * sr;
q.w = cy * cp * cr + sy * sp * sr;
return q;
}