在理解了move_base的基础上,我们开始机器人的定位与导航。gmaping包是用来生成地图的,需要使用实际的机器人获取激光或者深度数据,所以我们先在已有的地图上进行导航与定位的仿真。
这个lanuch的功能比较多:
(1) 加载机器人驱动
(2) 加载地图
(3) 启动move_base节点,并且加载配置文件
(4) 运行amcl节点
(5) 然后加载nav_test.py执行文件,进行随机导航
相当于是把我们之前实验中的多个lanuch文件合成了一个文件。
现在开始进行测试,先运行ROS:
在监控窗口中,我们可以看到机器人发送的状态信息:
amcl是移动机器人二维环境下的概率定位系统。它实现了自适应(或kld采样)的蒙特卡罗定位方法,其中针对已有的地图使用粒子滤波器跟踪一个机器人的姿态。
一、测试
首先运行机器人节点:
roslaunch rbx1_bringup fake_turtlebot.launch
然后运行amcl节点,使用测试地图:
可以看一下fake_amcl.launch这个文件的内容:
roslaunch rbx1_nav fake_amcl.launch map:=test_map.yaml可以看一下fake_amcl.launch这个文件的内容:
<launch>
<!-- Set the name of the map yaml file: can be overridden on the command line. -->
<arg name="map" default="test_map.yaml" />
<!-- Run the map server with the desired map -->
<node name="map_server" pkg="map_server" type="map_server" args="$(find rbx1_nav)/maps/$(arg map)"/>
<!-- The move_base node -->
<include file="$(find rbx1_nav)/launch/fake_move_base.launch" />
<!-- Run fake localization compatible with AMCL output -->
<node pkg="fake_localization" type="fake_localization" name="fake_localization" output="screen" />
<!-- For fake localization we need static transforms between /odom and /map and /map and /world -->
<node pkg="tf" type="static_transform_publisher" name="odom_map_broadcaster"
args="0 0 0 0 0 0 /odom /map 100" />
</launch>
这个lanuch文件作用是加载地图,并且调用fake_move_base.launch文件打开move_base节点并加载配置文件,最后运行amcl。
然后运行rviz:
然后运行rviz:
rosrun rviz rviz -d `rospack find rbx1_nav`/nav_fuerte.vcg
这时在rvoiz中就应该显示出了地图和机器人:
现在就可以通过rviz在地图上选择目标位置了,然后就会看到机器人自动规划出一条全局路径,并且导航前进:
二、自主导航
在实际应用中,我们往往希望机器人能够自主进行定位和导航,不需要认为的干预,这样才更智能化。在这一节的测试中,我们让目标点在地图中随机生成,然后机器人自动导航到达目标。
这里运行的主要文件是:fake_nav_test.launch,让我们来看一下这个文件的内容:
<launch>
<param name="use_sim_time" value="false" />
<!-- Start the ArbotiX controller -->
<include file="$(find rbx1_bringup)/launch/fake_turtlebot.launch" />
<!-- Run the map server with the desired map -->
<node name="map_server" pkg="map_server" type="map_server" args="$(find rbx1_nav)/maps/test_map.yaml"/>
<!-- The move_base node -->
<node pkg="move_base" type="move_base" respawn="false" name="move_base" output="screen">
<rosparam file="$(find rbx1_nav)/config/fake/costmap_common_params.yaml" command="load" ns="global_costmap" />
<rosparam file="$(find rbx1_nav)/config/fake/costmap_common_params.yaml" command="load" ns="local_costmap" />
<rosparam file="$(find rbx1_nav)/config/fake/local_costmap_params.yaml" command="load" />
<rosparam file="$(find rbx1_nav)/config/fake/global_costmap_params.yaml" command="load" />
<rosparam file="$(find rbx1_nav)/config/fake/base_local_planner_params.yaml" command="load" />
<rosparam file="$(find rbx1_nav)/config/nav_test_params.yaml" command="load" />
</node>
<!-- Run fake localization compatible with AMCL output -->
<node pkg="fake_localization" type="fake_localization" name="fake_localization" output="screen" />
<!-- For fake localization we need static transform between /odom and /map -->
<node pkg="tf" type="static_transform_publisher" name="map_odom_broadcaster" args="0 0 0 0 0 0 /map /odom 100" />
<!-- Start the navigation test -->
<node pkg="rbx1_nav" type="nav_test.py" name="nav_test" output="screen">
<param name="rest_time" value="1" />
<param name="fake_test" value="true" />
</node>
</launch>这个lanuch的功能比较多:
(1) 加载机器人驱动
(2) 加载地图
(3) 启动move_base节点,并且加载配置文件
(4) 运行amcl节点
(5) 然后加载nav_test.py执行文件,进行随机导航
相当于是把我们之前实验中的多个lanuch文件合成了一个文件。
现在开始进行测试,先运行ROS:
roscore
然后我们运行一个监控的窗口,可以实时看到机器人发送的数据:
rxconsole
接着运行lanuch文件,并且在一个新的终端中打开rviz:
roslaunch rbx1_nav fake_nav_test.launch
(打开新终端)
rosrun rviz rviz -d `rospack find rbx1_nav`/nav_test_fuerte.vcg
好了,此时就看到了机器人已经放在地图当中了。然后我们点击rviz上的“2D Pose Estimate”按键,然后左键在机器人上单击,让绿色的箭头和黄色的箭头重合,机器人就开始随机选择目标导航了:
其中包括距离信息、状态信息、目标的编号、成功率和速度等信息。
三、导航代码分析
#!/usr/bin/env python
import roslib; roslib.load_manifest('rbx1_nav')
import rospy
import actionlib
from actionlib_msgs.msg import *
from geometry_msgs.msg import Pose, PoseWithCovarianceStamped, Point, Quaternion, Twist
from move_base_msgs.msg import MoveBaseAction, MoveBaseGoal
from random import sample
from math import pow, sqrt
class NavTest():
def __init__(self):
rospy.init_node('nav_test', anonymous=True)
rospy.on_shutdown(self.shutdown)
# How long in seconds should the robot pause at each location?
# 在每个目标位置暂停的时间
self.rest_time = rospy.get_param("~rest_time", 10)
# Are we running in the fake simulator?
# 是否仿真?
self.fake_test = rospy.get_param("~fake_test", False)
# Goal state return values
# 到达目标的状态
goal_states = ['PENDING', 'ACTIVE', 'PREEMPTED',
'SUCCEEDED', 'ABORTED', 'REJECTED',
'PREEMPTING', 'RECALLING', 'RECALLED',
'LOST']
# Set up the goal locations. Poses are defined in the map frame.
# An easy way to find the pose coordinates is to point-and-click
# Nav Goals in RViz when running in the simulator.
# Pose coordinates are then displayed in the terminal
# that was used to launch RViz.
# 设置目标点的位置
# 如果想要获得某一点的坐标,在rviz中点击 2D Nav Goal 按键,然后单机地图中一点
# 在终端中就会看到坐标信息
locations = dict()
locations['hall_foyer'] = Pose(Point(0.643, 4.720, 0.000), Quaternion(0.000, 0.000, 0.223, 0.975))
locations['hall_kitchen'] = Pose(Point(-1.994, 4.382, 0.000), Quaternion(0.000, 0.000, -0.670, 0.743))
locations['hall_bedroom'] = Pose(Point(-3.719, 4.401, 0.000), Quaternion(0.000, 0.000, 0.733, 0.680))
locations['living_room_1'] = Pose(Point(0.720, 2.229, 0.000), Quaternion(0.000, 0.000, 0.786, 0.618))
locations['living_room_2'] = Pose(Point(1.471, 1.007, 0.000), Quaternion(0.000, 0.000, 0.480, 0.877))
locations['dining_room_1'] = Pose(Point(-0.861, -0.019, 0.000), Quaternion(0.000, 0.000, 0.892, -0.451))
# Publisher to manually control the robot (e.g. to stop it)
# 发布控制机器人的消息
self.cmd_vel_pub = rospy.Publisher('cmd_vel', Twist)
# Subscribe to the move_base action server
# 订阅move_base服务器的消息
self.move_base = actionlib.SimpleActionClient("move_base", MoveBaseAction)
rospy.loginfo("Waiting for move_base action server...")
# Wait 60 seconds for the action server to become available
# 60s等待时间限制
self.move_base.wait_for_server(rospy.Duration(60))
rospy.loginfo("Connected to move base server")
# A variable to hold the initial pose of the robot to be set by
# the user in RViz
# 保存机器人的在rviz中的初始位置
initial_pose = PoseWithCovarianceStamped()
# Variables to keep track of success rate, running time,
# and distance traveled
# 保存成功率、运行时间、和距离的变量
n_locations = len(locations)
n_goals = 0
n_successes = 0
i = n_locations
distance_traveled = 0
start_time = rospy.Time.now()
running_time = 0
location = ""
last_location = ""
# Get the initial pose from the user
# 获取初始位置(仿真中可以不需要)
rospy.loginfo("*** Click the 2D Pose Estimate button in RViz to set the robot's initial pose...")
rospy.wait_for_message('initialpose', PoseWithCovarianceStamped)
self.last_location = Pose()
rospy.Subscriber('initialpose', PoseWithCovarianceStamped, self.update_initial_pose)
# Make sure we have the initial pose
# 确保有初始位置
while initial_pose.header.stamp == "":
rospy.sleep(1)
rospy.loginfo("Starting navigation test")
# Begin the main loop and run through a sequence of locations
# 开始主循环,随机导航
while not rospy.is_shutdown():
# If we've gone through the current sequence,
# start with a new random sequence
# 如果已经走完了所有点,再重新开始排序
if i == n_locations:
i = 0
sequence = sample(locations, n_locations)
# Skip over first location if it is the same as
# the last location
# 如果最后一个点和第一个点相同,则跳过
if sequence[0] == last_location:
i = 1
# Get the next location in the current sequence
# 在当前的排序中获取下一个目标点
location = sequence[i]
# Keep track of the distance traveled.
# Use updated initial pose if available.
# 跟踪形式距离
# 使用更新的初始位置
if initial_pose.header.stamp == "":
distance = sqrt(pow(locations[location].position.x -
locations[last_location].position.x, 2) +
pow(locations[location].position.y -
locations[last_location].position.y, 2))
else:
rospy.loginfo("Updating current pose.")
distance = sqrt(pow(locations[location].position.x -
initial_pose.pose.pose.position.x, 2) +
pow(locations[location].position.y -
initial_pose.pose.pose.position.y, 2))
initial_pose.header.stamp = ""
# Store the last location for distance calculations
# 存储上一次的位置,计算距离
last_location = location
# Increment the counters
# 计数器加1
i += 1
n_goals += 1
# Set up the next goal location
# 设定下一个目标点
self.goal = MoveBaseGoal()
self.goal.target_pose.pose = locations[location]
self.goal.target_pose.header.frame_id = 'map'
self.goal.target_pose.header.stamp = rospy.Time.now()
# Let the user know where the robot is going next
# 让用户知道下一个位置
rospy.loginfo("Going to: " + str(location))
# Start the robot toward the next location
# 向下一个位置进发
self.move_base.send_goal(self.goal)
# Allow 5 minutes to get there
# 五分钟时间限制
finished_within_time = self.move_base.wait_for_result(rospy.Duration(300))
# Check for success or failure
# 查看是否成功到达
if not finished_within_time:
self.move_base.cancel_goal()
rospy.loginfo("Timed out achieving goal")
else:
state = self.move_base.get_state()
if state == GoalStatus.SUCCEEDED:
rospy.loginfo("Goal succeeded!")
n_successes += 1
distance_traveled += distance
rospy.loginfo("State:" + str(state))
else:
rospy.loginfo("Goal failed with error code: " + str(goal_states[state]))
# How long have we been running?
# 运行所用时间
running_time = rospy.Time.now() - start_time
running_time = running_time.secs / 60.0
# Print a summary success/failure, distance traveled and time elapsed
# 输出本次导航的所有信息
rospy.loginfo("Success so far: " + str(n_successes) + "/" +
str(n_goals) + " = " +
str(100 * n_successes/n_goals) + "%")
rospy.loginfo("Running time: " + str(trunc(running_time, 1)) +
" min Distance: " + str(trunc(distance_traveled, 1)) + " m")
rospy.sleep(self.rest_time)
def update_initial_pose(self, initial_pose):
self.initial_pose = initial_pose
def shutdown(self):
rospy.loginfo("Stopping the robot...")
self.move_base.cancel_goal()
rospy.sleep(2)
self.cmd_vel_pub.publish(Twist())
rospy.sleep(1)
def trunc(f, n):
# Truncates/pads a float f to n decimal places without rounding
slen = len('%.*f' % (n, f))
return float(str(f)[:slen])
if __name__ == '__main__':
try:
NavTest()
rospy.spin()
except rospy.ROSInterruptException:
rospy.loginfo("AMCL navigation test finished.")----------------------------------------------------------------
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