コード例 #1
0
 def poseCB(self, p):
     self.robot_pose = p.pose.pose
     self.robot_pose.position.x, self.robot_pose.position.y = self.projection(
         p.pose.pose.position.x, p.pose.pose.position.y)
     self.robot_pose.orientation.x = -p.pose.pose.orientation.x
     self.robot_pose.orientation.y = -p.pose.pose.orientation.y
     self.robot_pose.orientation.z = -p.pose.pose.orientation.z
     self.robot_pose.orientation = quat_rot(self.robot_pose.orientation, 0,
                                            0, 90)
     self.pose_get = True
     self.orentation_get = True
     if not self.goal_set:
         return
     self.distance = math.sqrt(
         (self.goal.x - self.robot_pose.position.x)**2 +
         (self.goal.y - self.robot_pose.position.y)**2)
     self.z_dist = self.robot_pose.position.z - self.goal.z
     robot_euler = tf.transformations.euler_from_quaternion(
         (self.robot_pose.orientation.x, self.robot_pose.orientation.y,
          self.robot_pose.orientation.z, self.robot_pose.orientation.w))
     self.roll = 0
     self.pitch = math.atan2(
         self.goal.z - self.robot_pose.position.z,
         math.sqrt((self.goal.x - self.robot_pose.position.x)**2 +
                   (self.goal.y -
                    self.robot_pose.position.y)**2)) - robot_euler[1]
     self.yaw = math.atan2(
         self.goal.y - self.robot_pose.position.y,
         self.goal.x - self.robot_pose.position.x) - robot_euler[2]
     self.roll = fit_in_rad(self.roll)
     self.pitch = fit_in_rad(self.pitch)
     self.yaw = fit_in_rad(self.yaw)
コード例 #2
0
 def cmdCB(self, cmd):
   cmd_parts = cmd.data.split(',')  
   s = cmd_parts[0]
   pos = self.robot_pos
   robot_euler = tf.transformations.euler_from_quaternion((pos.orientation.x, pos.orientation.y, pos.orientation.z, pos.orientation.w))
   robot_th = robot_euler[2] # 2 * math.atan2(odo.pose.pose.orientation.z,odo.pose.pose.orientation.w)
   if s == "fwd":
     dis = float(cmd_parts[1])
     self.target_pos.position.x = pos.position.x + dis * math.cos(robot_th)
     self.target_pos.position.y = pos.position.y + dis * math.sin(robot_th) 
     self.robot_state = self.FORWARDING
     self.finished.data = False
     self.state = self.RUNNING
   elif s == "turn":  
     a = math.radians( float(cmd_parts[1]) )
     target_th = robot_th + a
     target_th = fit_in_rad(target_th)
     target_quat = tf.transformations.quaternion_from_euler(robot_euler[0], robot_euler[1], target_th)
     self.target_pos.orientation.x = target_quat[0]
     self.target_pos.orientation.y = target_quat[1]
     self.target_pos.orientation.z = target_quat[2]
     self.target_pos.orientation.w = target_quat[3]
     self.robot_state = self.TURNING
     self.finished.data = False
     self.state = self.RUNNING
コード例 #3
0
  def Start(self):
    while not rospy.is_shutdown():
      if self.state != self.RUNNING:
        self.rate.sleep()
        continue

      # Calculate relative position
      pos = self.robot_pos
      distance = math.sqrt( (self.target_pos.position.x-pos.position.x)**2 + (self.target_pos.position.y-pos.position.y)**2 )
      z_dist = self.target_pos.position.y - pos.position.y
      robot_euler = tf.transformations.euler_from_quaternion((pos.orientation.x, pos.orientation.y, pos.orientation.z, pos.orientation.w))
      target_euler = tf.transformations.euler_from_quaternion((self.target_pos.orientation.x, self.target_pos.orientation.y, self.target_pos.orientation.z, self.target_pos.orientation.w))
      angle = fit_in_rad( math.atan2((self.target_pos.position.y-pos.position.y),(self.target_pos.position.x-pos.position.x)) - robot_euler[2])
      if math.fabs(angle) < math.pi/2:
        fwd_dir = 1.0
      else:
        fwd_dir = -1.0
      roll = fit_in_rad(target_euler[0] - robot_euler[0]) 
      pitch = fit_in_rad(target_euler[1] - robot_euler[1]) 
      yaw = fit_in_rad(target_euler[2] - robot_euler[2])
      # When the robot is turning
      if self.robot_state == self.TURNING:
        # Stop linear movements
        self.vel.linear.x = 0
        self.vel.linear.y = 0
        self.vel.linear.z = 0
        # Turn if the robot has DOF
        if self.rx_config:
          self.vel.angular.x = self.Accelerate(self.vel.angular.x, self.K_ROLL * roll, self.ACC_R/self.freq)
        else:
          self.vel.angular.x = 0
        if self.ry_config:
          self.vel.angular.y = self.Accelerate(self.vel.angular.y, self.K_PITCH * pitch, self.ACC_R/self.freq)
        else:
          self.vel.angular.y = 0
        if self.rz_config:
          self.vel.angular.z = self.Accelerate(self.vel.angular.z, self.K_YAW * yaw, self.ACC_R/self.freq)
        else:
          self.vel.angular.z = 0
        # Check whether turning process is finished
        finished_turning = True
        if self.rx_config and math.fabs(roll) > self.TURNING_THRES:  
          finished_turning = False
        if self.ry_config and math.fabs(pitch) > self.TURNING_THRES:  
          finished_turning = False
        if self.rz_config and math.fabs(yaw) > self.TURNING_THRES:  
          finished_turning = False
        # If turning is finished          
        if finished_turning:
          if not self.finished.data:
            self.finished.data = True
            self.finished_pub.publish(self.finished)
            self.StopRobot()
            self.robot_state = self.STOP
            self.state = self.STOP
        
      # When the robot is moving forwarding    
      elif self.robot_state == self.FORWARDING:       
        # TODO: movement in x-y plane should be optimised
        self.vel.linear.x = self.Accelerate(self.vel.linear.x, fwd_dir * self.K_RHO * distance, self.ACC/self.freq)
        # If the robot is able to fly
        if self.z_config:
          self.vel.linear.z = self.Accelerate(self.vel.linear.z, self.K_RHO * z_dist, self.ACC_R/self.freq)
        # Correct the orenitation if the robot can
        if self.rx_config:
          self.vel.angular.x = self.Accelerate(self.vel.angular.x, self.K_ROLL * roll, self.ACC_R/self.freq)
        else:
          self.vel.angular.x = 0
        if self.ry_config:
          self.vel.angular.y = self.Accelerate(self.vel.angular.y, self.K_PITCH * pitch, self.ACC_R/self.freq)
        else:
          self.vel.angular.y = 0
        if self.rz_config:
          self.vel.angular.z = self.Accelerate(self.vel.angular.z, self.K_YAW * yaw, self.ACC_R/self.freq)
        else:
          self.vel.angular.z = 0
          
        # Check whether the target is reached
        finished_forwarding = True
        if math.fabs(distance) > self.FORWARDING_THRES:
          finished_forwarding = False
        if self.z_config and math.fabs(z_dist) > self.FLYING_THRES:
          finished_forwarding = False
        # When reach the target, stop the robot and wait for new command
        if finished_forwarding:
          if not self.finished.data:
            self.finished.data = True
            self.finished_pub.publish(self.finished)
            self.StopRobot()
            self.robot_state = self.IDLE
            self.state = self.STOP

      # When the cmd is not known
      else:
        self.robot_state = self.STOP
        self.StopRobot()
        self.state = self.STOP
        
      # Fit the velocity into the limited range    
      self.vel.linear.x = self.LimitRange(self.vel.linear.x, self.VEL_MAX_LIN)
      self.vel.linear.y = self.LimitRange(self.vel.linear.y, self.VEL_MAX_LIN)
      self.vel.linear.z = self.LimitRange(self.vel.linear.z, self.VEL_MAX_LIN)
      self.vel.angular.x = self.LimitRange(self.vel.angular.x, self.VEL_MAX_ANG)
      self.vel.angular.y = self.LimitRange(self.vel.angular.y, self.VEL_MAX_ANG)
      self.vel.angular.z = self.LimitRange(self.vel.angular.z, self.VEL_MAX_ANG)
      self.vel_pub.publish(self.vel)
      self.rate.sleep()
コード例 #4
0
    def Start(self):
        while not rospy.is_shutdown():
            if self.finished.data:
                self.rate.sleep()
                continue

            # Calculate relative position
            pos = self.robot_pos
            distance = math.sqrt(
                (self.target_pos.position.x - pos.position.x)**2 +
                (self.target_pos.position.y - pos.position.y)**2)
            robot_euler = tf.transformations.euler_from_quaternion(
                (pos.orientation.x, pos.orientation.y, pos.orientation.z,
                 pos.orientation.w))
            target_euler = tf.transformations.euler_from_quaternion(
                (self.target_pos.orientation.x, self.target_pos.orientation.y,
                 self.target_pos.orientation.z, self.target_pos.orientation.w))
            angle = fit_in_rad(
                math.atan2((self.target_pos.position.y - pos.position.y),
                           (self.target_pos.position.x - pos.position.x)) -
                robot_euler[2])
            if math.fabs(angle) < math.pi / 2:
                fwd_dir = 1.0
            else:
                fwd_dir = -1.0
            yaw = fit_in_rad(target_euler[2] - robot_euler[2])
            if yaw > 0:
                turn_dir = 1.0
            else:
                turn_dir = -1.0
            # print "distance: " + str(distance)
            # print "yaw: " + str(yaw)
            # When the robot is turning
            if self.robot_state == self.TURNING:
                # Stop linear movements
                self.vel.linear.x = 0
                self.vel.angular.z = turn_dir * self.VEL_ANG

                # Check whether turning process is finished
                finished_turning = True
                if math.fabs(yaw) > self.TURNING_THRES:
                    finished_turning = False

                # If turning is finished
                if finished_turning:
                    if not self.finished.data:
                        self.finished.data = True
                        self.finished_pub.publish(self.finished)
                        self.StopRobot()
                        self.robot_state = self.IDLE

            # When the robot is moving forwarding
            elif self.robot_state == self.FORWARDING:
                self.vel.linear.x = fwd_dir * self.VEL_LIN
                self.vel.angular.z = 0

                # Check whether the target is reached
                finished_forwarding = True
                if math.fabs(distance) > self.FORWARDING_THRES:
                    finished_forwarding = False

                # When reach the target, stop the robot and wait for new command
                if finished_forwarding:
                    if not self.finished.data:
                        self.finished.data = True
                        self.finished_pub.publish(self.finished)
                        self.StopRobot()
                        self.robot_state = self.IDLE

            # When the cmd is not known
            else:
                self.robot_state = self.IDLE
                self.StopRobot()
                self.finished.data = True
                self.finished_pub.publish(self.finished)

            self.vel_pub.publish(self.vel)
            self.rate.sleep()