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# Soft Arm Sim - ROS 2 柔性机械臂仿真平台
这是一个基于 ROS 2 (Humble) 开发的柔性机械臂Soft Manipulator仿真程序。
项目实现了基于常曲率PCC假设的运动学模型包含可视化仿真、运动控制接口并预留了深度学习与硬件控制的扩展接口。
## 🤖 机器人参数
- **结构**3 段 PCC (Piecewise Constant Curvature) 串联
- **每段配置**
- 长度240mm (3 disks × 80mm间隔)
- 磁盘直径80mm
- 绳索孔距33mm
- **自由度**:配置空间 (Configuration Space) 控制,每段由 `theta` (弯曲角) 和 `phi` (偏转角) 定义。
## 📂 文件结构
```text
src/soft_arm_sim/
├── soft_arm_sim/ # Python 核心源码
│ ├── base/ # ROS 2 仿真节点 (TF发布, Marker绘制)
│ ├── control/ # 控制算法 (测试控制器, PID, 甚至 RL)
│ ├── model/ # 纯数学模型 (PCC运动学, 无ROS依赖)
│ └── deeplearning/ # 强化学习环境 (Gym)
├── launch/ # 启动脚本
├── urdf/ # 机器人视觉模型描述 (Xacro)
└── resource/ # ROS 资源文件

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import os
from ament_index_python.packages import get_package_share_directory
from launch import LaunchDescription
from launch.substitutions import Command
from launch_ros.actions import Node
def generate_launch_description():
pkg_name = 'soft_arm_sim'
share_dir = get_package_share_directory(pkg_name)
# 获取 xacro 文件路径
xacro_file = os.path.join(share_dir, 'urdf', 'soft_arm.urdf.xacro')
# 1. Robot State Publisher
# 使用 Command 进行转换,这样更稳定,且能在终端看到详细报错
robot_description = Command(['xacro ', xacro_file])
node_robot_state_publisher = Node(
package='robot_state_publisher',
executable='robot_state_publisher',
output='screen',
parameters=[{'robot_description': robot_description}]
)
# 2. 仿真节点
node_simulator = Node(
package=pkg_name,
executable='simulator',
output='screen'
)
# 3. Rviz2
node_rviz = Node(
package='rviz2',
executable='rviz2',
name='rviz2',
)
return LaunchDescription([
node_robot_state_publisher,
node_simulator,
node_rviz
])

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<?xml version="1.0"?>
<?xml-model href="http://download.ros.org/schema/package_format3.xsd" schematypens="http://www.w3.org/2001/XMLSchema"?>
<package format="3">
<name>soft_arm_sim</name>
<version>0.0.0</version>
<description>Soft Robot Arm Simulation with 3 PCC sections</description>
<maintainer email="user@todo.todo">mio</maintainer>
<license>TODO: License declaration</license>
<depend>rclpy</depend>
<depend>std_msgs</depend>
<depend>geometry_msgs</depend>
<depend>visualization_msgs</depend>
<depend>tf2_ros</depend>
<depend>robot_state_publisher</depend>
<depend>xacro</depend>
<depend>rviz2</depend>
<!-- Python 库依赖 (虽然 colcon 不一定自动安装 pip 库,但写在这里是好习惯) -->
<exec_depend>python3-numpy</exec_depend>
<exec_depend>python3-scipy</exec_depend>
<test_depend>ament_copyright</test_depend>
<test_depend>ament_flake8</test_depend>
<test_depend>ament_pep257</test_depend>
<test_depend>python3-pytest</test_depend>
<export>
<build_type>ament_python</build_type>
</export>
</package>

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[develop]
script_dir=$base/lib/soft_arm_sim
[install]
install_scripts=$base/lib/soft_arm_sim

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from setuptools import setup, find_packages
import os
from glob import glob
package_name = 'soft_arm_sim'
setup(
name=package_name,
version='0.0.0',
# 自动查找所有包含 __init__.py 的子包
packages=find_packages(exclude=['test']),
data_files=[
('share/ament_index/resource_index/packages',
['resource/' + package_name]),
('share/' + package_name, ['package.xml']),
# 1. 安装 launch 文件
(os.path.join('share', package_name, 'launch'), glob('launch/*.launch.py')),
# 2. 安装 urdf 文件 (非常重要,否则 robot_state_publisher 找不到模型)
(os.path.join('share', package_name, 'urdf'), glob('urdf/*')),
# 3. 配置文件安装
(os.path.join('share', package_name, 'config'), glob('config/*.yaml')),
],
install_requires=['setuptools'],
zip_safe=True,
maintainer='mio',
maintainer_email='user@todo.todo',
description='Soft Robot Arm Simulation',
license='TODO: License declaration',
tests_require=['pytest'],
entry_points={
'console_scripts': [
# 格式: '可执行文件名 = 包名.路径.文件名:函数名'
# 仿真核心节点 (对应 base/simulation_node.py 中的 main 函数)
'simulator = soft_arm_sim.base.simulation_node:main',
# 测试控制器 (对应 control/test_controller.py 中的 main 函数)
'sine_controller = soft_arm_sim.control.test_controller:main',
],
},
)

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import rclpy
from rclpy.node import Node
from rclpy.qos import QoSProfile, ReliabilityPolicy, HistoryPolicy, DurabilityPolicy
from geometry_msgs.msg import TransformStamped, Point
from visualization_msgs.msg import Marker, MarkerArray # 引入 MarkerArray
from std_msgs.msg import Float64MultiArray
from builtin_interfaces.msg import Time
import tf2_ros
import numpy as np
from scipy.spatial.transform import Rotation
from soft_arm_sim.model.pcc_kinematics import SoftArmKinematics
class SoftArmSimulator(Node):
def __init__(self):
super().__init__('soft_arm_simulator')
self.kinematics = SoftArmKinematics()
# TF 广播器 (依然保留,为了保证 base_link 存在,且供其他节点使用)
self.tf_broadcaster = tf2_ros.TransformBroadcaster(self)
# QoS 设置
marker_qos = QoSProfile(
depth=1,
reliability=ReliabilityPolicy.RELIABLE,
history=HistoryPolicy.KEEP_LAST,
durability=DurabilityPolicy.VOLATILE
)
# 注意:这里改成了 MarkerArray
self.marker_pub = self.create_publisher(MarkerArray, 'soft_arm_visual', marker_qos)
self.create_subscription(Float64MultiArray, 'soft_arm/command', self.cmd_callback, 10)
self.current_config = [
(0.0, 0.0, 0.24),
(0.0, 0.0, 0.24),
(0.0, 0.0, 0.24)
]
# 30Hz
self.timer = self.create_timer(0.033, self.update_loop)
def cmd_callback(self, msg):
data = msg.data
if len(data) >= 6:
self.current_config[0] = (data[0], data[1], 0.24)
self.current_config[1] = (data[2], data[3], 0.24)
self.current_config[2] = (data[4], data[5], 0.24)
def update_loop(self):
transforms, curve_points = self.kinematics.forward(self.current_config)
# --- 策略TF 用真实时间(保住 base_linkMarker 用 0 时间(保住同步)---
real_time = self.get_clock().now().to_msg()
# 1. 发布 TF (这是为了系统健全性,不用于显示)
disk_names = [
"sec1_disk1", "sec1_disk2", "sec1_disk3",
"sec2_disk1", "sec2_disk2", "sec2_disk3",
"sec3_disk1", "sec3_disk2", "sec3_disk3"
]
for i, T in enumerate(transforms):
t = TransformStamped()
t.header.stamp = real_time # 真实时间,保证 base_link 不丢
t.header.frame_id = "base_link"
t.child_frame_id = disk_names[i]
t.transform.translation.x = T[0, 3]
t.transform.translation.y = T[1, 3]
t.transform.translation.z = T[2, 3]
r = Rotation.from_matrix(T[:3, :3])
q = r.as_quat()
t.transform.rotation.x = q[0]
t.transform.rotation.y = q[1]
t.transform.rotation.z = q[2]
t.transform.rotation.w = q[3]
self.tf_broadcaster.sendTransform(t)
# 2. 发布全套 Marker (Line + Disks)
self.publish_all_visuals(transforms, curve_points)
def publish_all_visuals(self, transforms, curve_points):
marker_array = MarkerArray()
# 通用设置
zero_time = Time() # 强制零时间,立刻渲染
# --- A. 创建 Disk Markers (替代 RobotModel) ---
for i, T in enumerate(transforms):
disk = Marker()
disk.header.stamp = zero_time
disk.header.frame_id = "base_link"
disk.ns = "disks"
disk.id = i + 1 # ID 从 1 开始
disk.type = Marker.CYLINDER
disk.action = Marker.ADD
# 尺寸 (80mm 直径, 5mm 厚)
disk.scale.x = 0.08
disk.scale.y = 0.08
disk.scale.z = 0.005
# 颜色 (根据段区分)
disk.color.a = 1.0
if i < 3: # Sec 1: Red
disk.color.r, disk.color.g, disk.color.b = 1.0, 0.0, 0.0
elif i < 6: # Sec 2: Green
disk.color.r, disk.color.g, disk.color.b = 0.0, 1.0, 0.0
else: # Sec 3: Blue
disk.color.r, disk.color.g, disk.color.b = 0.0, 0.0, 1.0
# 位置
disk.pose.position.x = T[0, 3]
disk.pose.position.y = T[1, 3]
disk.pose.position.z = T[2, 3]
# 姿态
r = Rotation.from_matrix(T[:3, :3])
q = r.as_quat()
disk.pose.orientation.x = q[0]
disk.pose.orientation.y = q[1]
disk.pose.orientation.z = q[2]
disk.pose.orientation.w = q[3]
disk.lifetime.sec = 0
disk.lifetime.nanosec = 0
marker_array.markers.append(disk)
# --- B. 创建 Backbone Marker (白色中轴) ---
line = Marker()
line.header.stamp = zero_time
line.header.frame_id = "base_link"
line.ns = "backbone"
line.id = 0
line.type = Marker.LINE_STRIP
line.action = Marker.ADD
line.scale.x = 0.008
line.color.a = 1.0
line.color.r = 0.9
line.color.g = 0.9
line.color.b = 0.9
line.lifetime.sec = 0
line.lifetime.nanosec = 0
# 填充点
for p_np in curve_points:
p = Point()
p.x, p.y, p.z = float(p_np[0]), float(p_np[1]), float(p_np[2])
line.points.append(p)
marker_array.markers.append(line)
# 发布
self.marker_pub.publish(marker_array)
def main(args=None):
rclpy.init(args=args)
node = SoftArmSimulator()
rclpy.spin(node)
node.destroy_node()
rclpy.shutdown()

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import rclpy
from rclpy.node import Node
from std_msgs.msg import Float64MultiArray
import numpy as np
class SineWaveController(Node):
def __init__(self):
super().__init__('sine_controller')
self.pub = self.create_publisher(Float64MultiArray, 'soft_arm/command', 10)
self.timer = self.create_timer(0.05, self.timer_callback)
self.t = 0.0
def timer_callback(self):
msg = Float64MultiArray()
# 让三个段做不同相位的摆动
# [theta1, phi1, theta2, phi2, theta3, phi3]
theta1 = 0.5 * np.sin(self.t) + 0.5 # 弯曲程度
phi1 = self.t # 旋转方向
theta2 = 0.5 * np.sin(self.t + 1.0) + 0.5
phi2 = self.t + 1.0
theta3 = 0.5 * np.sin(self.t + 2.0) + 0.5
phi3 = self.t + 2.0
msg.data = [theta1, phi1, theta2, phi2, theta3, phi3]
self.pub.publish(msg)
self.t += 0.05
def main(args=None):
rclpy.init(args=args)
node = SineWaveController()
rclpy.spin(node)
node.destroy_node()
rclpy.shutdown()

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import numpy as np
class PCCSection:
def __init__(self, length=0.240, disk_num=3, disk_radius=0.033):
self.L0 = length
self.n_disks = disk_num
self.d_per_segment = length / disk_num
def _get_transform_at_s(self, s, q):
"""
计算圆弧上任意位置 s 处的变换矩阵
q: [theta, phi, length]
"""
theta, phi, s_total = q
T = np.eye(4)
# 奇异点处理:直线状态
if abs(theta) < 1e-6:
T[0, 3] = 0
T[1, 3] = 0
T[2, 3] = s
else:
# 常曲率公式
k = theta / s_total # 曲率
# 注意:这里的 s 是当前点在弧上的长度
# 当 s > s_total 时(拉伸),我们假设曲率均匀分布在整个 s_total 上
# 这里简化处理,直接用 s 计算几何
ct = np.cos(theta * (s / s_total))
st = np.sin(theta * (s / s_total))
cp = np.cos(phi)
sp = np.sin(phi)
R = np.array([
[cp*cp*(ct-1)+1, cp*sp*(ct-1), cp*st],
[cp*sp*(ct-1), sp*sp*(ct-1)+1, sp*st],
[-cp*st, -sp*st, ct]
])
p = np.array([
(cp * (1 - ct)) / k,
(sp * (1 - ct)) / k,
st / k
])
T[:3, :3] = R
T[:3, 3] = p
return T
def forward_kinematics(self, q):
"""返回所有 Disk 的变换矩阵 (用于 TF)"""
theta, phi, s_total = q
transforms = []
for i in range(1, self.n_disks + 1):
s = (s_total / self.n_disks) * i
transforms.append(self._get_transform_at_s(s, q))
return transforms
def get_curve_points(self, q, num_points=10):
"""
返回用于画线的密集点集 (相对坐标)
:param num_points: 这一段生成的点数 (越多越平滑)
"""
theta, phi, s_total = q
points = []
# 生成从 0 到 L 的密集点
s_values = np.linspace(0, s_total, num_points)
for s in s_values:
T = self._get_transform_at_s(s, q)
points.append(T[:3, 3]) # 只取位置 xyz
return points
class SoftArmKinematics:
def __init__(self):
# 3段 PCC
self.sections = [
PCCSection(length=0.24, disk_num=3),
PCCSection(length=0.24, disk_num=3),
PCCSection(length=0.24, disk_num=3)
]
def forward(self, joint_configs):
"""
返回:
1. transforms: 用于发布 TF (Base -> Disk)
2. path_points: 用于发布 Marker (平滑曲线)
"""
all_transforms = []
all_path_points = []
T_current_base = np.eye(4) # 当前段基座
# 初始点 (0,0,0)
all_path_points.append(T_current_base[:3, 3])
for i, config in enumerate(joint_configs):
# 1. 计算 TF (Disks)
section_transforms = self.sections[i].forward_kinematics(config)
# 2. 计算 曲线点 (Marker)
# 获取当前段内的局部密集点
local_points = self.sections[i].get_curve_points(config, num_points=15)
# 将局部点转换到全局坐标系
for p_local in local_points:
# 点: p_global = R * p_local + t
p_global = T_current_base[:3, :3] @ p_local + T_current_base[:3, 3]
all_path_points.append(p_global)
# 处理 TF 级联
for T_local in section_transforms:
T_global = T_current_base @ T_local
all_transforms.append(T_global)
# 更新下一段基座
if section_transforms:
T_current_base = all_transforms[-1]
return all_transforms, all_path_points

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<?xml version="1.0"?>
<robot xmlns:xacro="http://www.ros.org/wiki/xacro" name="soft_arm">
<xacro:property name="disk_radius" value="0.04" />
<xacro:property name="disk_height" value="0.005" />
<!-- Base Link -->
<link name="base_link">
<visual>
<geometry>
<box size="0.1 0.1 0.02"/>
</geometry>
<material name="grey">
<color rgba="0.5 0.5 0.5 1"/>
</material>
</visual>
</link>
<!-- Macro for a Disk -->
<xacro:macro name="pcc_disk" params="name parent color">
<link name="${name}">
<visual>
<geometry>
<cylinder radius="${disk_radius}" length="${disk_height}"/>
</geometry>
<origin xyz="0 0 0" rpy="0 0 0"/>
<material name="${color}_mat">
<color rgba="${color} 1"/>
</material>
</visual>
</link>
<!-- !!!核心修改在这里!!! -->
<!-- 必须添加 Joint否则 robot_state_publisher 会崩溃 -->
<!-- type="floating" 表示这个关节是浮动的,位置由外部 TF 决定 -->
<joint name="${name}_joint" type="floating">
<parent link="${parent}"/>
<child link="${name}"/>
</joint>
</xacro:macro>
<!-- Section 1 -->
<xacro:pcc_disk name="sec1_disk1" parent="base_link" color="1 0 0"/>
<xacro:pcc_disk name="sec1_disk2" parent="base_link" color="1 0 0"/>
<xacro:pcc_disk name="sec1_disk3" parent="base_link" color="1 0 0"/>
<!-- Section 2 -->
<xacro:pcc_disk name="sec2_disk1" parent="base_link" color="0 1 0"/>
<xacro:pcc_disk name="sec2_disk2" parent="base_link" color="0 1 0"/>
<xacro:pcc_disk name="sec2_disk3" parent="base_link" color="0 1 0"/>
<!-- Section 3 -->
<xacro:pcc_disk name="sec3_disk1" parent="base_link" color="0 0 1"/>
<xacro:pcc_disk name="sec3_disk2" parent="base_link" color="0 0 1"/>
<xacro:pcc_disk name="sec3_disk3" parent="base_link" color="0 0 1"/>
</robot>