feat: 添加机械臂 ROS 2 控制节点和视觉抓取系统

- 创建 arm_control_msgs 包:定义机械臂控制的消息和服务接口
  - 消息:JointState, TCPPose
  - 服务:MoveJoints, MovePose, GetPose, SetGripper

- 实现 arm_control 节点:独立的机械臂控制 ROS 节点
  - 完整的逆运动学和正运动学
  - 关节空间和笛卡尔空间运动控制
  - UDP 通信与 ESP32
  - 状态发布(10Hz)

- 实现 vision_grasp 节点:自动化视觉抓取
  - 相机坐标系到基坐标系的完整变换
  - 自动抓取流程:释放→移动→抓取→回收
  - 自动释放流程:移动→释放→回收
  - 多线程执行器支持

- 添加完整文档
  - ARM_CONTROL_README.md: 机械臂控制节点使用指南
  - VISION_GRASP_README.md: 视觉抓取节点使用指南
  - QUICKSTART.md: 快速开始指南
  - 文档重命名:docs/craic.md → docs/arm.md
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# arm_control ROS 节点使用指南
## 概述
`arm_control` 是一个封装了机械臂控制功能的 ROS 2 节点,基于 `udp_control.py` 改造,提供服务接口进行机械臂控制。
## 功能特性
- ✅ 关节空间运动控制(带插值)
- ✅ 笛卡尔空间运动控制(带逆运动学)
- ✅ 正运动学查询
- ✅ 夹爪控制
- ✅ 状态发布(关节状态 + TCP 位姿)
- ✅ 状态缓存(平滑运动)
## 编译
```bash
cd ros2
# 1. 编译消息包
colcon build --packages-select arm_control_msgs
# 2. Source 消息包
source install/setup.bash
# 3. 编译控制节点
colcon build --packages-select udp_teleop
# 4. Source 控制节点
source install/setup.bash
```
## 运行
### 启动控制节点
```bash
# 使用默认参数
ros2 run udp_teleop arm_control
# 使用配置文件
ros2 run udp_teleop arm_control \
--ros-args --params-file src/udp_teleop/config/arm_control.yaml
# 覆盖特定参数
ros2 run udp_teleop arm_control \
--ros-args -p udp_ip:=192.168.233.67 -p udp_port:=8888
```
## 服务接口
### 1. 关节空间运动
```bash
ros2 service call /arm_control/move_joints arm_control_msgs/srv/MoveJoints \
"{height: -100, j2: 10, j3: 20, j4: 30, j5: 81, j6: 30, duration: 2.0}"
```
### 2. 笛卡尔空间运动
```bash
# 基本运动
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -100.0, phi: 45.0, duration: 2.0}"
# 带夹爪控制
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -100.0, phi: 45.0, grip: true, duration: 2.0}"
```
### 3. 查询当前位姿
```bash
ros2 service call /arm_control/get_pose arm_control_msgs/srv/GetPose
```
输出示例:
```
success: true
message: ''
x: 150.234
y: 75.123
z: -100.0
phi: 45.678
height: -100
j2: 13
j3: 27
j4: 55
j5: 81
j6: 30
```
### 4. 夹爪控制
```bash
# 抓取
ros2 service call /arm_control/set_gripper arm_control_msgs/srv/SetGripper \
"{grip: true}"
# 释放
ros2 service call /arm_control/set_gripper arm_control_msgs/srv/SetGripper \
"{release: true}"
```
## 话题订阅
### 1. 关节状态
```bash
ros2 topic echo /arm_control/joint_states
```
输出:
```yaml
header:
stamp:
sec: 1234567890
nanosec: 123456789
frame_id: ''
height: -100
j2: 13
j3: 27
j4: 55
j5: 81
j6: 30
```
### 2. TCP 位姿
```bash
ros2 topic echo /arm_control/tcp_pose
```
输出:
```yaml
header:
stamp:
sec: 1234567890
nanosec: 123456789
frame_id: ''
x: 150.234
y: 75.123
z: -100.0
phi: 45.678
```
## Python 客户端示例
```python
#!/usr/bin/env python3
import rclpy
from rclpy.node import Node
from arm_control_msgs.srv import MovePose
class MyArmController(Node):
def __init__(self):
super().__init__('my_controller')
self.cli = self.create_client(MovePose, 'arm_control/move_pose')
self.cli.wait_for_service()
def move_to(self, x, y, z, phi):
req = MovePose.Request()
req.x = x
req.y = y
req.z = z
req.phi = phi
req.duration = 2.0
future = self.cli.call_async(req)
rclpy.spin_until_future_complete(self, future)
return future.result().success
def main():
rclpy.init()
controller = MyArmController()
# 移动到目标位置
controller.move_to(200.0, 100.0, -100.0, 45.0)
controller.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()
```
## 完整抓取流程示例
```bash
# 运行示例客户端(包含完整抓取流程)
ros2 run udp_teleop arm_control_client
```
或手动调用:
```bash
# 1. 查询当前位姿
ros2 service call /arm_control/get_pose arm_control_msgs/srv/GetPose
# 2. 移动到物体上方
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -50.0, phi: 45.0, release: true, duration: 2.0}"
# 3. 下降到抓取位置
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -150.0, phi: 45.0, release: true, duration: 1.0}"
# 4. 抓取
ros2 service call /arm_control/set_gripper arm_control_msgs/srv/SetGripper \
"{grip: true}"
# 5. 提升
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -50.0, phi: 45.0, grip: true, duration: 1.0}"
```
## 参数配置
编辑 `config/arm_control.yaml`
```yaml
arm_control:
ros__parameters:
# UDP 配置
udp_ip: '192.168.4.1'
udp_port: 8888
# 机械臂几何参数
l1: 125.0
l2: 125.0
x4: 110.0
z4: 80.0
# 关节限位
height_min: -290
height_max: 0
j2_min: -110
j2_max: 115
# ... (更多参数见配置文件)
```
## 调试
### 查看服务列表
```bash
ros2 service list | grep arm_control
```
### 查看话题列表
```bash
ros2 topic list | grep arm_control
```
### 查看服务接口定义
```bash
ros2 interface show arm_control_msgs/srv/MovePose
```
### 实时监控状态
```bash
# 终端 1: 查看关节状态
ros2 topic echo /arm_control/joint_states
# 终端 2: 查看 TCP 位姿
ros2 topic echo /arm_control/tcp_pose
# 终端 3: 发送控制命令
ros2 service call /arm_control/move_pose ...
```
## 常见问题
### Q1: 服务调用失败
**检查**
1. 节点是否正在运行?`ros2 node list`
2. UDP 连接是否正常?检查 `udp_ip` 参数
3. 关节限位是否合理?查看错误消息
### Q2: 运动不平滑
**调整参数**
- 增加 `duration`(运动时长)
- 增加 `default_rate`(插值频率)
### Q3: 状态不更新
**检查**
- `use_state_cache` 是否启用?
- `tools/.udp_control_state.json` 是否可写?
## 与原始 udp_control.py 对比
| 功能 | udp_control.py | arm_control 节点 |
|------|---------------|-----------------|
| 接口 | 命令行 | ROS 服务 + 话题 |
| 集成 | 独立脚本 | ROS 生态系统 |
| 状态查询 | 文件缓存 | 服务调用 |
| 多客户端 | 不支持 | 支持 |
| 实时监控 | 不支持 | 话题订阅 |
## 下一步
- 集成视觉系统:创建视觉抓取节点,订阅相机话题,调用 arm_control 服务
- 添加轨迹规划:创建轨迹规划器,生成平滑路径
- 碰撞检测:添加工作空间限制和碰撞检测
## 相关文件
- 节点实现:`udp_teleop/arm_control.py`
- 消息定义:`arm_control_msgs/msg/`
- 服务定义:`arm_control_msgs/srv/`
- 配置文件:`udp_teleop/config/arm_control.yaml`
- 示例客户端:`udp_teleop/arm_control_client.py`

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# 编译成功!🎉
## ✅ 已完成
1. **消息包编译** - arm_control_msgs ✓
2. **控制节点编译** - udp_teleop ✓
## 🚀 快速测试
### 1. 启动控制节点
```bash
# 激活环境
conda activate ros2_humble
# Source 工作空间
cd ros2
source install/setup.bash
# 启动节点(修改 IP 为你的 ESP32 IP
ros2 run udp_teleop arm_control \
--ros-args --params-file src/udp_teleop/config/arm_control.yaml
```
### 2. 测试服务(新终端)
```bash
# 激活环境
conda activate ros2_humble
cd ros2
source install/setup.bash
# 查询当前位姿
ros2 service call /arm_control/get_pose arm_control_msgs/srv/GetPose
# 移动到指定位置
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -100.0, phi: 45.0, duration: 2.0}"
```
### 3. 查看状态
```bash
# 查看关节状态
ros2 topic echo /arm_control/joint_states
# 查看 TCP 位姿
ros2 topic echo /arm_control/tcp_pose
# 查看所有服务
ros2 service list | grep arm_control
```
## ⚠️ 重要提示
### 编译说明
由于 robostack 的 Python 配置问题,编译时需要显式指定 Python 路径:
```bash
# 已在 build_arm_control.sh 中自动处理
export PYTHON_EXECUTABLE=$CONDA_PREFIX/bin/python
export PYTHON_INCLUDE_DIR=$CONDA_PREFIX/include/python3.12
export PYTHON_LIBRARY=$CONDA_PREFIX/lib/libpython3.12.so
```
### 修改配置
编辑 `src/udp_teleop/config/arm_control.yaml` 修改参数:
```yaml
arm_control:
ros__parameters:
udp_ip: '192.168.4.1' # 修改为你的 ESP32 IP
udp_port: 8888
```
修改后直接重启节点即可,无需重新编译。
## 📝 下一步
1. **修改 ESP32 IP**: 编辑 `config/arm_control.yaml`
2. **测试连接**: 启动节点,查看是否有错误
3. **调用服务**: 使用上面的命令测试
4. **运行示例**: `ros2 run udp_teleop arm_control_client`
## 🐛 故障排查
### 问题:找不到服务
**解决**
```bash
# 检查节点是否运行
ros2 node list
# 重新 source 环境
source install/setup.bash
```
### 问题UDP 发送失败
**解决**
1. 检查 ESP32 IP 是否正确
2. 测试网络连接:`ping 192.168.4.1`
3. 测试 UDP`echo 'XYW:0:0:0:XZHY' | nc -u 192.168.4.1 8888`
### 问题:重新编译
**解决**
```bash
# 清理后重新编译
rm -rf build/ install/ log/
./build_arm_control.sh
```
## 📚 文档
- 完整文档:[ARM_CONTROL_README.md](ARM_CONTROL_README.md)
- 快速指南:[QUICKSTART.md](QUICKSTART.md)
- 实现总结:[IMPLEMENTATION_SUMMARY.md](IMPLEMENTATION_SUMMARY.md)
祝使用愉快!🎉

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# arm_control ROS 节点封装总结
## ✅ 完成的工作
### 1. 创建了消息和服务定义包 (`arm_control_msgs`)
**消息类型**
- `TCPPose.msg` - TCP 位姿x, y, z, phi
- `JointState.msg` - 关节状态height, j2-j6
**服务类型**
- `MoveJoints.srv` - 关节空间运动控制
- `MovePose.srv` - 笛卡尔空间运动控制(带逆运动学)
- `GetPose.srv` - 查询当前位姿(正运动学)
- `SetGripper.srv` - 夹爪控制
### 2. 封装了控制节点 (`arm_control.py`)
**核心功能**
- ✅ 关节空间插值运动
- ✅ 笛卡尔空间逆运动学求解
- ✅ 正运动学位姿计算
- ✅ UDP 命令发送(与 ESP32 通信)
- ✅ 状态缓存(平滑运动)
- ✅ 参数化配置
- ✅ 状态发布10Hz
**服务接口**
- `/arm_control/move_joints` - 关节运动
- `/arm_control/move_pose` - 位姿运动
- `/arm_control/get_pose` - 查询位姿
- `/arm_control/set_gripper` - 夹爪控制
**话题发布**
- `/arm_control/joint_states` - 关节状态10Hz
- `/arm_control/tcp_pose` - TCP 位姿10Hz
### 3. 创建了示例客户端 (`arm_control_client.py`)
**演示功能**
- 查询当前位姿
- 完整抓取流程:
1. 移动到物体上方
2. 下降
3. 抓取
4. 提升
5. 移动到目标位置
6. 下降
7. 释放
8. 提升
### 4. 配置和文档
**配置文件**
- `config/arm_control.yaml` - 完整参数配置
**文档**
- `ARM_CONTROL_README.md` - 完整使用文档
- `QUICKSTART.md` - 快速开始指南
**脚本**
- `build_arm_control.sh` - 一键编译脚本
## 📁 文件清单
```
ros2/
├── build_arm_control.sh # 编译脚本 ✨
├── ARM_CONTROL_README.md # 完整文档 ✨
├── QUICKSTART.md # 快速指南 ✨
└── src/
├── arm_control_msgs/ # 消息包 ✨
│ ├── CMakeLists.txt
│ ├── package.xml
│ ├── msg/
│ │ ├── TCPPose.msg
│ │ └── JointState.msg
│ └── srv/
│ ├── MoveJoints.srv
│ ├── MovePose.srv
│ ├── GetPose.srv
│ └── SetGripper.srv
└── udp_teleop/
├── setup.py # 已更新 ✨
├── package.xml # 已更新 ✨
├── udp_teleop/
│ ├── keyboard_control.py # 原有
│ ├── arm_control.py # 新增 ✨
│ └── arm_control_client.py # 新增 ✨
└── config/
├── params.yaml # 原有
└── arm_control.yaml # 新增 ✨
```
## 🚀 快速使用
### 编译
```bash
cd ros2
./build_arm_control.sh
```
### 运行节点
```bash
ros2 run udp_teleop arm_control \
--ros-args --params-file src/udp_teleop/config/arm_control.yaml
```
### 测试服务
```bash
# 查询位姿
ros2 service call /arm_control/get_pose arm_control_msgs/srv/GetPose
# 移动
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -100.0, phi: 45.0, duration: 2.0}"
```
### 运行示例
```bash
ros2 run udp_teleop arm_control_client
```
## 🎯 与原始 udp_control.py 对比
| 特性 | udp_control.py | arm_control 节点 |
|------|---------------|-----------------|
| **接口方式** | 命令行参数 | ROS 服务调用 |
| **状态查询** | 读取 JSON 文件 | 服务调用 + 话题订阅 |
| **多客户端** | ❌ 不支持 | ✅ 支持 |
| **实时监控** | ❌ 无 | ✅ 10Hz 状态发布 |
| **参数配置** | 命令行参数 | YAML 配置文件 |
| **集成度** | 独立工具 | ROS 生态集成 |
| **可编程性** | Shell 脚本 | Python/C++ 客户端 |
## 💡 优势
### 1. **标准化接口**
- 使用 ROS 服务和话题,符合 ROS 生态标准
- 易于与其他 ROS 节点集成(如视觉、规划器)
### 2. **多客户端支持**
- 多个客户端可同时连接
- 适合复杂系统(如视觉 + 手动控制)
### 3. **实时状态监控**
- 10Hz 状态发布
- 可用于可视化、日志记录、故障诊断
### 4. **灵活配置**
- YAML 参数文件
- 运行时参数覆盖
- 无需重新编译
### 5. **易于扩展**
- 添加新服务:只需定义 .srv 文件
- 添加新话题:只需定义 .msg 文件
- 集成其他功能:订阅/发布话题即可
## 🔧 使用场景
### 场景 1视觉抓取
```python
# 视觉节点订阅相机话题,检测物体
# 调用 arm_control 服务控制机械臂
class VisionGraspNode(Node):
def __init__(self):
self.arm_cli = self.create_client(MovePose, 'arm_control/move_pose')
self.sub = self.create_subscription(Image, '/camera/image', self.on_image, 10)
def on_image(self, msg):
# 检测物体
x, y, z = detect_object(msg)
# 控制机械臂抓取
self.move_to(x, y, z, phi=45.0)
```
### 场景 2示教编程
```python
# 记录示教点位
class TeachPendant(Node):
def __init__(self):
self.get_cli = self.create_client(GetPose, 'arm_control/get_pose')
self.move_cli = self.create_client(MovePose, 'arm_control/move_pose')
self.waypoints = []
def record_waypoint(self):
# 记录当前位置
pose = self.get_current_pose()
self.waypoints.append(pose)
def replay(self):
# 重放示教轨迹
for pose in self.waypoints:
self.move_to(pose.x, pose.y, pose.z, pose.phi)
```
### 场景 3轨迹规划
```python
# 使用规划器生成轨迹
class TrajectoryPlanner(Node):
def __init__(self):
self.move_cli = self.create_client(MovePose, 'arm_control/move_pose')
def execute_trajectory(self, waypoints):
# 执行轨迹点序列
for wp in waypoints:
self.move_to(wp.x, wp.y, wp.z, wp.phi, duration=0.5)
```
## 📚 下一步建议
### 1. **视觉集成**
创建视觉抓取节点,结合 `camera_to_base.py` 实现自动抓取
### 2. **GUI 控制面板**
使用 RQt 创建图形界面,实时显示状态和控制
### 3. **轨迹记录与回放**
实现示教编程功能
### 4. **碰撞检测**
添加工作空间限制和简单碰撞检测
### 5. **MoveIt 集成**
创建 URDF 和 MoveIt 配置,使用高级运动规划
## 🎓 学习资源
- ROS 2 服务教程https://docs.ros.org/en/humble/Tutorials/Services.html
- ROS 2 话题教程https://docs.ros.org/en/humble/Tutorials/Topics.html
- 自定义消息https://docs.ros.org/en/humble/Tutorials/Custom-ROS2-Interfaces.html
## ✨ 总结
现在你有了一个完整的 ROS 节点化的机械臂控制系统:
1.**功能完整** - 保留了 udp_control.py 的所有功能
2.**接口标准** - 使用 ROS 服务和话题
3.**易于集成** - 可与其他 ROS 节点无缝配合
4.**文档齐全** - 提供了完整的文档和示例
5.**开箱即用** - 一键编译,快速上手
祝你使用愉快!🎉

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# 机械臂控制 ROS 节点 - 快速开始
## 🚀 快速编译和运行
### 1. 一键编译
```bash
cd ros2
./build_arm_control.sh
```
### 2. 启动节点
```bash
# 方法 A: 使用配置文件(推荐)
ros2 run udp_teleop arm_control \
--ros-args --params-file src/udp_teleop/config/arm_control.yaml
# 方法 B: 使用默认参数
ros2 run udp_teleop arm_control
# 方法 C: 覆盖特定参数
ros2 run udp_teleop arm_control \
--ros-args -p udp_ip:=192.168.233.67
```
### 3. 测试服务
```bash
# 查询当前位姿
ros2 service call /arm_control/get_pose arm_control_msgs/srv/GetPose
# 移动到指定位置
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -100.0, phi: 45.0, duration: 2.0}"
```
### 4. 运行完整示例
```bash
# 在新终端运行示例客户端(包含完整抓取流程)
ros2 run udp_teleop arm_control_client
```
## 📁 文件结构
```
ros2/
├── build_arm_control.sh # 一键编译脚本
├── ARM_CONTROL_README.md # 完整使用文档
├── QUICKSTART.md # 本文件
└── src/
├── arm_control_msgs/ # 消息和服务定义
│ ├── msg/
│ │ ├── TCPPose.msg # TCP 位姿消息
│ │ └── JointState.msg # 关节状态消息
│ └── srv/
│ ├── MoveJoints.srv # 关节运动服务
│ ├── MovePose.srv # 位姿运动服务
│ ├── GetPose.srv # 查询位姿服务
│ └── SetGripper.srv # 夹爪控制服务
└── udp_teleop/
├── udp_teleop/
│ ├── arm_control.py # 控制节点实现
│ └── arm_control_client.py # 示例客户端
└── config/
└── arm_control.yaml # 参数配置
```
## 🎯 常用命令
### 服务调用
```bash
# 1. 关节空间运动
ros2 service call /arm_control/move_joints arm_control_msgs/srv/MoveJoints \
"{height: -100, j2: 10, j3: 20, j4: 30, j5: 81, j6: 30, duration: 2.0}"
# 2. 笛卡尔空间运动
ros2 service call /arm_control/move_pose arm_control_msgs/srv/MovePose \
"{x: 200.0, y: 100.0, z: -100.0, phi: 45.0, duration: 2.0}"
# 3. 查询当前位姿
ros2 service call /arm_control/get_pose arm_control_msgs/srv/GetPose
# 4. 夹爪控制
ros2 service call /arm_control/set_gripper arm_control_msgs/srv/SetGripper \
"{grip: true}"
```
### 话题订阅
```bash
# 查看关节状态10Hz 发布)
ros2 topic echo /arm_control/joint_states
# 查看 TCP 位姿10Hz 发布)
ros2 topic echo /arm_control/tcp_pose
```
### 调试命令
```bash
# 查看所有服务
ros2 service list | grep arm_control
# 查看所有话题
ros2 topic list | grep arm_control
# 查看节点信息
ros2 node info /arm_control
# 查看服务接口定义
ros2 interface show arm_control_msgs/srv/MovePose
```
## 📝 Python 客户端模板
```python
#!/usr/bin/env python3
import rclpy
from rclpy.node import Node
from arm_control_msgs.srv import MovePose, GetPose
class MyController(Node):
def __init__(self):
super().__init__('my_controller')
# 创建服务客户端
self.move_cli = self.create_client(MovePose, 'arm_control/move_pose')
self.get_cli = self.create_client(GetPose, 'arm_control/get_pose')
# 等待服务
self.move_cli.wait_for_service()
self.get_cli.wait_for_service()
def move_to(self, x, y, z, phi, duration=2.0):
"""移动到指定位置"""
req = MovePose.Request()
req.x = x
req.y = y
req.z = z
req.phi = phi
req.duration = duration
future = self.move_cli.call_async(req)
rclpy.spin_until_future_complete(self, future)
return future.result().success
def get_pose(self):
"""查询当前位姿"""
req = GetPose.Request()
future = self.get_cli.call_async(req)
rclpy.spin_until_future_complete(self, future)
return future.result()
def main():
rclpy.init()
controller = MyController()
# 查询位姿
pose = controller.get_pose()
print(f"当前位置: ({pose.x}, {pose.y}, {pose.z})")
# 移动
controller.move_to(200.0, 100.0, -100.0, 45.0)
controller.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()
```
## 🔧 配置修改
编辑 `src/udp_teleop/config/arm_control.yaml`
```yaml
arm_control:
ros__parameters:
# 修改 ESP32 IP
udp_ip: '192.168.4.1'
# 修改运动速度
default_duration: 1.0 # 更快0.5更慢2.0
# 修改关节限位
height_min: -290
height_max: 0
```
修改后重新运行节点即可(无需重新编译)。
## ⚠️ 常见问题
### 编译失败
```bash
# 确保环境激活
conda activate ros2_humble
source install/setup.bash
# 清理后重新编译
rm -rf build/ install/ log/
./build_arm_control.sh
```
### 服务不可用
```bash
# 检查节点是否运行
ros2 node list
# 检查服务是否存在
ros2 service list | grep arm_control
# 查看节点日志
ros2 run udp_teleop arm_control --ros-args --log-level debug
```
### UDP 连接失败
```bash
# 测试 UDP 连接
echo 'XYW:0:0:0:XZHY' | nc -u 192.168.4.1 8888
# 修改 IP 配置
ros2 run udp_teleop arm_control \
--ros-args -p udp_ip:=<你的IP> -p udp_port:=8888
```
## 📚 更多文档
- 完整使用文档:[ARM_CONTROL_README.md](ARM_CONTROL_README.md)
- 原始工具文档:[../tools/README.md](../tools/README.md)
- ROS 2 包文档:[src/udp_teleop/README.md](src/udp_teleop/README.md)
## 🎓 下一步
1. **集成视觉**:创建视觉抓取节点,订阅相机话题,调用 arm_control 服务
2. **添加规划**:使用 MoveIt 或自定义轨迹规划器
3. **多机械臂**:启动多个 arm_control 节点控制多个机械臂
4. **远程控制**:通过 ROS 2 的 DDS 实现跨机器控制

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# 视觉抓取节点使用指南
## 概述
`vision_grasp` 节点基于 `camera_to_base.py` 实现自动抓取和释放功能,将相机坐标系的检测结果转换为机械臂基坐标系,并自动执行抓取流程。
## 功能
### 1. 抓取功能
**输入**:相机坐标系 `(x, y, z)`
**流程**
1. 坐标转换:`(xc, yc, zc) = (x, -y, z)`(图像坐标到相机坐标)
2. 转换到基坐标系
3. 释放夹爪duration=0
4. 移动到目标位置duration=3s
5. 抓取duration=1s
6. 回收到 (200, 0, 当前z)
### 2. 释放功能
**输入**:基坐标系 `(x, y, z)`
**流程**
1. 移动到释放位置
2. 释放夹爪duration=0
3. 回收到 (200, 0, 当前z)
## 编译
```bash
cd ros2
colcon build --packages-select udp_teleop
source install/setup.bash
```
## 运行
### 启动节点
**终端 1**:启动机械臂控制节点
```bash
ros2 run udp_teleop arm_control \
--ros-args --params-file src/udp_teleop/config/arm_control.yaml
```
**终端 2**:启动视觉抓取节点
```bash
ros2 run udp_teleop vision_grasp \
--ros-args --params-file src/udp_teleop/config/vision_grasp.yaml
```
## 使用
### 方法 1发布话题触发抓取
```bash
# 抓取:输入相机坐标
ros2 topic pub --once /vision_grasp/grasp_target geometry_msgs/Point \
"{x: 10.0, y: 5.0, z: 250.0}"
# 释放:输入基坐标
ros2 topic pub --once /vision_grasp/release_target geometry_msgs/Point \
"{x: 100.0, y: 150.0, z: -100.0}"
```
### 方法 2Python 脚本集成
```python
#!/usr/bin/env python3
import rclpy
from rclpy.node import Node
from geometry_msgs.msg import Point
class VisionDetector(Node):
def __init__(self):
super().__init__('vision_detector')
# 创建发布者
self.grasp_pub = self.create_publisher(
Point,
'vision_grasp/grasp_target',
10
)
def detect_and_grasp(self):
# 模拟检测结果(相机坐标系)
camera_x = 10.0 # 相机右侧 10mm
camera_y = 5.0 # 相机下方 5mm
camera_z = 250.0 # 前方 250mm
# 发布抓取目标
msg = Point()
msg.x = camera_x
msg.y = camera_y
msg.z = camera_z
self.grasp_pub.publish(msg)
self.get_logger().info(f'发送抓取目标: ({camera_x}, {camera_y}, {camera_z})')
def main():
rclpy.init()
node = VisionDetector()
# 检测并抓取
node.detect_and_grasp()
node.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()
```
### 方法 3与检测节点集成
```python
#!/usr/bin/env python3
"""完整的视觉检测+抓取示例"""
import rclpy
from rclpy.node import Node
from sensor_msgs.msg import Image
from geometry_msgs.msg import Point
import cv2
from cv_bridge import CvBridge
class VisionPipeline(Node):
def __init__(self):
super().__init__('vision_pipeline')
# 订阅相机图像
self.image_sub = self.create_subscription(
Image,
'/camera/image_raw',
self.on_image,
10
)
# 发布抓取目标
self.grasp_pub = self.create_publisher(
Point,
'vision_grasp/grasp_target',
10
)
self.bridge = CvBridge()
def on_image(self, msg):
# 转换 ROS 图像到 OpenCV
image = self.bridge.imgmsg_to_cv2(msg, 'bgr8')
# 检测物体(示例:使用轮廓检测)
detected = self.detect_object(image)
if detected:
camera_x, camera_y, camera_z = detected
# 发布抓取目标
target = Point()
target.x = camera_x
target.y = camera_y
target.z = camera_z
self.grasp_pub.publish(target)
self.get_logger().info(f'检测到物体,发送抓取指令')
def detect_object(self, image):
"""检测物体并返回相机坐标"""
# TODO: 实现你的检测算法
# 1. 图像处理(阈值、轮廓等)
# 2. 获取像素坐标 (u, v) 和像素宽度
# 3. 使用相似三角形计算深度
# 4. 转换到相机坐标系
# 示例返回值
return (10.0, 5.0, 250.0) # (xc, yc, zc)
def main():
rclpy.init()
node = VisionPipeline()
rclpy.spin(node)
node.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()
```
## 参数配置
编辑 `config/vision_grasp.yaml`
```yaml
vision_grasp:
ros__parameters:
# 相机到 TCP 的变换(如果相机不在 TCP 中心)
cam_tx: 0.0 # X 偏移
cam_ty: 0.0 # Y 偏移(高度)
cam_tz: 0.0 # Z 偏移(前后)
# 回收位置
retract_position_x: 200.0
retract_position_y: 0.0
# 运动时长
grasp_duration: 3.0 # 抓取移动时长
release_duration: 2.0 # 释放移动时长
```
## 坐标系说明
### 相机坐标系
```
Yc (下)
|
|
o-----> Zc (前,水平)
/
/
Xc (右)
```
### 坐标转换
检测结果 `(x, y, z)` 表示:
- `x`: 图像列方向(右为正)
- `y`: 图像行方向(下为正)
- `z`: 深度方向(前为正)
节点会自动转换:
```
(xc, yc, zc) = (x, -y, z)
```
这是因为:
- 图像 Y 向下 → 相机 Y 向下(负号修正方向)
- 然后再转换到基坐标系
## 调试
### 查看节点状态
```bash
# 查看节点列表
ros2 node list
# 查看话题列表
ros2 topic list | grep vision_grasp
# 监听抓取目标
ros2 topic echo /vision_grasp/grasp_target
```
### 测试流程
1. **启动节点**
```bash
# 终端 1
ros2 run udp_teleop arm_control --ros-args --params-file src/udp_teleop/config/arm_control.yaml
# 终端 2
ros2 run udp_teleop vision_grasp --ros-args --params-file src/udp_teleop/config/vision_grasp.yaml
```
2. **发送测试抓取**
```bash
# 终端 3
ros2 topic pub --once /vision_grasp/grasp_target geometry_msgs/Point \
"{x: 0.0, y: 0.0, z: 300.0}"
```
3. **观察日志**
- 终端 2 会显示详细的抓取流程日志
- 确认坐标转换和每一步动作
## 常见问题
### Q1: 坐标转换不正确
**检查**
1. 相机内参是否准确标定
2. 相机到 TCP 的变换参数是否正确
3. 当前 TCP 位姿是否正确
### Q2: 抓取位置偏移
**可能原因**
1. 深度计算不准确
2. 相机安装角度有偏差
3. 坐标系定义理解错误
**解决**
1. 调整 `cam_pitch` 参数(如果相机有俯仰角)
2. 校准相机内参
3. 使用已知位置物体验证
### Q3: 夹爪动作失败
**检查**
1. arm_control 节点是否正常运行
2. UDP 连接是否正常
3. 关节限位是否合理
## 扩展功能
### 添加安全检查
```python
def execute_grasp(self, x: float, y: float, z: float, phi: float):
# 检查目标是否在工作空间内
if not self.is_in_workspace(x, y, z):
self.get_logger().warn(f'目标超出工作空间: ({x}, {y}, {z})')
return
# 执行抓取...
```
### 添加碰撞检测
```python
def is_path_safe(self, start, end):
# 检查路径是否安全
# TODO: 实现碰撞检测逻辑
return True
```
### 多物体抓取
```python
# 订阅物体列表
self.objects_sub = self.create_subscription(
PointArray, # 自定义消息类型
'vision_grasp/object_list',
self.handle_objects,
10
)
def handle_objects(self, msg):
for obj in msg.points:
self.execute_grasp(obj.x, obj.y, obj.z, self.current_phi)
# 等待完成...
```
## 相关文件
- 节点实现:`udp_teleop/vision_grasp.py`
- 配置文件:`udp_teleop/config/vision_grasp.yaml`
- 坐标变换工具:`tools/camera_to_base.py`
- 机械臂控制:`udp_teleop/arm_control.py`
## 下一步
1. 集成物体检测算法YOLO、轮廓检测等
2. 添加深度估计(相似三角形、双目视觉等)
3. 优化抓取策略(多物体排序、路径规划等)
4. 添加可视化RViz 显示检测结果和机械臂状态)

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@@ -0,0 +1,286 @@
# 视觉抓取节点 - 完成总结
## ✅ 完成的工作
### 1. 创建了视觉抓取 ROS 节点 (`vision_grasp.py`)
**功能**
- ✅ 抓取功能:输入相机坐标 → 自动转换 → 执行抓取流程
- ✅ 释放功能:输入基坐标 → 移动 → 释放物体
- ✅ 坐标变换:集成 `camera_to_base.py` 的完整变换逻辑
- ✅ 自动化流程:释放夹爪 → 移动 → 抓取 → 回收
### 2. 抓取流程
```
输入相机坐标 (x, y, z)
转换: (xc, yc, zc) = (x, -y, z)
变换到基坐标系
1. Release 夹爪 (duration=0)
2. 移动到目标 (duration=3s)
3. Grip 夹爪 (duration=1s)
4. 回收到 (200, 0, 当前z)
```
### 3. 释放流程
```
输入基坐标 (x, y, z)
1. 移动到释放位置
2. Release 夹爪 (duration=0)
3. 回收到 (200, 0, 当前z)
```
## 📁 创建的文件
```
ros2/
├── src/udp_teleop/
│ ├── udp_teleop/
│ │ └── vision_grasp.py ✨ 视觉抓取节点
│ └── config/
│ └── vision_grasp.yaml ✨ 参数配置
├── test_vision_grasp.py ✨ 测试脚本
└── VISION_GRASP_README.md ✨ 完整文档
```
## 🚀 快速使用
### 启动节点
**终端 1**arm_control 节点
```bash
cd ros2
source install/setup.bash
ros2 run udp_teleop arm_control \
--ros-args --params-file src/udp_teleop/config/arm_control.yaml
```
**终端 2**vision_grasp 节点
```bash
cd ros2
source install/setup.bash
ros2 run udp_teleop vision_grasp \
--ros-args --params-file src/udp_teleop/config/vision_grasp.yaml
```
**终端 3**:测试
```bash
cd ros2
source install/setup.bash
# 测试抓取(相机正前方 300mm
python test_vision_grasp.py grasp 0 0 300
# 测试抓取(相机右侧 50mm前方 300mm
python test_vision_grasp.py grasp 50 0 300
# 测试释放(基坐标)
python test_vision_grasp.py release 100 150 -100
```
### 或使用话题发布
```bash
# 抓取
ros2 topic pub --once /vision_grasp/grasp_target geometry_msgs/Point \
"{x: 0.0, y: 0.0, z: 300.0}"
# 释放
ros2 topic pub --once /vision_grasp/release_target geometry_msgs/Point \
"{x: 100.0, y: 150.0, z: -100.0}"
```
## 🎯 关键特性
### 1. 自动坐标转换
- **输入**:相机坐标系 `(x, y, z)`
- **自动转换**`(xc, yc, zc) = (x, -y, z)`(图像坐标修正)
- **变换到基坐标系**:使用当前 TCP 位姿进行完整变换
### 2. 参数化配置
```yaml
vision_grasp:
ros__parameters:
# 相机到 TCP 的变换
cam_tx: 0.0
cam_ty: 0.0
cam_tz: 0.0
# 回收位置
retract_position_x: 200.0
retract_position_y: 0.0
# 运动时长
grasp_duration: 3.0
release_duration: 2.0
```
### 3. 完整日志
节点会输出详细的流程日志:
```
============================================================
开始抓取流程
============================================================
1. 释放夹爪
2. 移动到目标位置: (323.5, 229.6, -108.6)
3. 抓取物体
4. 移动到回收位置: (200.0, 0.0, -108.6)
============================================================
✓ 抓取完成!
============================================================
```
## 🔗 集成示例
### Python 脚本集成
```python
#!/usr/bin/env python3
import rclpy
from rclpy.node import Node
from geometry_msgs.msg import Point
class MyDetector(Node):
def __init__(self):
super().__init__('my_detector')
self.grasp_pub = self.create_publisher(
Point, 'vision_grasp/grasp_target', 10)
def on_detection(self, camera_x, camera_y, camera_z):
"""检测到物体后触发抓取"""
msg = Point()
msg.x = camera_x
msg.y = camera_y
msg.z = camera_z
self.grasp_pub.publish(msg)
def main():
rclpy.init()
node = MyDetector()
# 模拟检测结果
node.on_detection(10.0, 5.0, 250.0)
rclpy.spin(node)
node.destroy_node()
rclpy.shutdown()
```
## 📊 话题接口
| 话题 | 类型 | 说明 |
|------|------|------|
| `/vision_grasp/grasp_target` | geometry_msgs/Point | 抓取目标(相机坐标) |
| `/vision_grasp/release_target` | geometry_msgs/Point | 释放目标(基坐标) |
## 🎓 下一步
### 1. 集成物体检测
```python
# 订阅相机图像
self.image_sub = self.create_subscription(
Image, '/camera/image_raw', self.on_image, 10)
def on_image(self, msg):
# 检测物体
camera_x, camera_y, camera_z = detect_object(msg)
# 触发抓取
self.publish_grasp_target(camera_x, camera_y, camera_z)
```
### 2. 添加深度估计
使用 `tools/vision_transform.py` 中的相似三角形方法:
```python
from tools.vision_transform import compute_depth_from_size
# 从检测获得像素宽度
pixel_width = 100 # px
real_width = 50 # mm
focal_length = 500 # px
depth = compute_depth_from_size(pixel_width, real_width, focal_length)
```
### 3. 多物体抓取
```python
# 创建队列
self.grasp_queue = []
def on_multiple_detections(self, detections):
for det in detections:
self.grasp_queue.append(det)
# 逐个抓取
while self.grasp_queue:
target = self.grasp_queue.pop(0)
self.publish_grasp_target(target.x, target.y, target.z)
# 等待完成...
```
## 🐛 故障排查
### Q1: 坐标转换不正确
**检查**
1. TCP 位姿是否正确(`ros2 service call /arm_control/get_pose`
2. 相机到 TCP 的变换参数(`cam_tx/ty/tz`, `cam_roll/pitch/yaw`
3. 坐标系方向理解是否正确
### Q2: 抓取位置偏移
**解决**
1. 校准相机内参
2. 验证深度计算准确性
3. 调整 `cam_pitch`(如果相机有俯仰角)
### Q3: 服务调用超时
**检查**
1. arm_control 节点是否运行
2. UDP 连接是否正常
3. 机械臂是否在合理位置
## 📚 相关文档
- **完整文档**`VISION_GRASP_README.md`
- **坐标变换**`tools/camera_to_base.py`
- **机械臂控制**`ARM_CONTROL_README.md`
- **视觉变换**`docs/vision_calibration_horizontal.md`
## 🎉 总结
现在你有了一个完整的视觉抓取系统:
1.**独立的机械臂控制节点** - `arm_control`
2.**自动化抓取节点** - `vision_grasp`
3.**完整的坐标变换** - 相机 → 基坐标系
4.**参数化配置** - 灵活调整参数
5.**测试工具** - 快速验证功能
6.**完整文档** - 使用指南和示例
只需要:
1. 添加物体检测算法
2. 连接相机获取图像
3. 发布检测结果到 `/vision_grasp/grasp_target`
系统就会自动完成抓取!

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@@ -0,0 +1,25 @@
cmake_minimum_required(VERSION 3.10)
project(arm_control_msgs)
if(CMAKE_COMPILER_IS_GNUCXX OR CMAKE_CXX_COMPILER_ID MATCHES "Clang")
add_compile_options(-Wall -Wextra -Wpedantic)
endif()
# find dependencies
find_package(ament_cmake REQUIRED)
find_package(rosidl_default_generators REQUIRED)
find_package(std_msgs REQUIRED)
# Generate messages and services
rosidl_generate_interfaces(${PROJECT_NAME}
"msg/TCPPose.msg"
"msg/JointState.msg"
"srv/MoveJoints.srv"
"srv/MovePose.srv"
"srv/GetPose.srv"
"srv/SetGripper.srv"
DEPENDENCIES std_msgs
)
ament_export_dependencies(rosidl_default_runtime)
ament_package()

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@@ -0,0 +1,8 @@
# 关节状态消息
std_msgs/Header header
int32 height # 高度 (mm)
int32 j2 # 关节 2 角度 (度)
int32 j3 # 关节 3 角度 (度)
int32 j4 # 关节 4 角度 (度)
int32 j5 # 关节 5 角度 (度)
int32 j6 # 关节 6 角度 (度)

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@@ -0,0 +1,6 @@
# TCP 位姿消息
std_msgs/Header header
float64 x # X 坐标 (mm)
float64 y # Y 坐标 (mm)
float64 z # Z 坐标 (mm)
float64 phi # 偏航角 (度)

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@@ -0,0 +1,22 @@
<?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>arm_control_msgs</name>
<version>0.0.1</version>
<description>Message and service definitions for arm control</description>
<maintainer email="fallensigh@gmail.com">fallensigh</maintainer>
<license>MIT</license>
<buildtool_depend>ament_cmake</buildtool_depend>
<buildtool_depend>rosidl_default_generators</buildtool_depend>
<depend>std_msgs</depend>
<exec_depend>rosidl_default_runtime</exec_depend>
<member_of_group>rosidl_interface_packages</member_of_group>
<export>
<build_type>ament_cmake</build_type>
</export>
</package>

View File

@@ -0,0 +1,14 @@
# 查询当前位姿服务
---
bool success # 是否成功
string message # 返回信息
float64 x # 当前 X 坐标 (mm)
float64 y # 当前 Y 坐标 (mm)
float64 z # 当前 Z 坐标 (mm)
float64 phi # 当前偏航角 (度)
int32 height # 当前高度 (mm)
int32 j2 # 当前 J2 角度 (度)
int32 j3 # 当前 J3 角度 (度)
int32 j4 # 当前 J4 角度 (度)
int32 j5 # 当前 J5 角度 (度)
int32 j6 # 当前 J6 角度 (度)

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@@ -0,0 +1,11 @@
# 关节空间运动服务
int32 height # 目标高度 (mm)
int32 j2 # 目标 J2 角度 (度)
int32 j3 # 目标 J3 角度 (度)
int32 j4 # 目标 J4 角度 (度)
int32 j5 # 目标 J5 角度 (度)
int32 j6 # 目标 J6 角度 (度)
float64 duration # 运动时长 (秒0 表示使用默认值)
---
bool success # 是否成功
string message # 返回信息

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@@ -0,0 +1,18 @@
# 笛卡尔空间运动服务
float64 x # 目标 X 坐标 (mm)
float64 y # 目标 Y 坐标 (mm)
float64 z # 目标 Z 坐标 (mm)
float64 phi # 目标偏航角 (度)
bool elbow_up # 是否使用肘部向上解
uint8 gripper_state # 夹爪状态: 0=保持, 1=打开, 2=闭合
bool grip # 是否抓取
bool release # 是否释放
float64 duration # 运动时长 (秒0 表示使用默认值)
# 夹爪状态常量
uint8 GRIPPER_KEEP = 0
uint8 GRIPPER_OPEN = 1
uint8 GRIPPER_CLOSED = 2
---
bool success # 是否成功
string message # 返回信息

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@@ -0,0 +1,12 @@
# 夹爪控制服务
uint8 gripper_state # 夹爪状态: 0=保持, 1=打开, 2=闭合
bool grip # 是否抓取
bool release # 是否释放
# 夹爪状态常量
uint8 GRIPPER_KEEP = 0
uint8 GRIPPER_OPEN = 1
uint8 GRIPPER_CLOSED = 2
---
bool success # 是否成功
string message # 返回信息

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@@ -0,0 +1,38 @@
# 机械臂控制节点参数配置
arm_control:
ros__parameters:
# UDP 通信配置
udp_ip: '192.168.4.1'
udp_port: 8888
# 机械臂几何参数 (mm)
l1: 125.0 # J2-J3 连杆长度
l2: 125.0 # J3-J4 连杆长度
x4: 110.0 # J4-TCP 水平偏移
z4: 80.0 # J4-TCP 垂直偏移
# 关节限位 (mm 或 度)
height_min: -290
height_max: 0
j2_min: -110
j2_max: 115
j3_min: -120
j3_max: 145
j4_min: -90
j4_max: 130
joint_min: -180 # J5/J6 通用限位
joint_max: 180
# 零点偏移 (度)
zero_j2: 3
zero_j3: 7
zero_j4: 25
# 运动参数
default_duration: 3.0 # 默认运动时长 (秒)
default_rate: 100.0 # 插值频率 (Hz)
use_state_cache: true # 是否使用状态缓存
# 状态发布频率
publish_rate: 10.0 # Hz

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@@ -0,0 +1,21 @@
# 视觉抓取节点参数配置
vision_grasp:
ros__parameters:
# 相机到 TCP 的变换参数
cam_tx: 0.0 # X 平移 (mm)
cam_ty: 0.0 # Y 平移 (mm)
cam_tz: 0.0 # Z 平移 (mm)
cam_roll: 0.0 # 绕 X 轴旋转 (度)
cam_pitch: 0.0 # 绕 Y 轴旋转 (度)
cam_yaw: 0.0 # 绕 Z 轴旋转 (度)
# 抓取参数
approach_height_offset: 50.0 # 接近高度偏移 (mm)
retract_position_x: 200.0 # 回收位置 X (mm)
retract_position_y: 0.0 # 回收位置 Y (mm)
# 运动时长
grasp_duration: 3.0 # 抓取移动时长 (秒)
release_duration: 2.0 # 释放移动时长 (秒)
gripper_duration: 1.0 # 夹爪动作时长 (秒)

View File

@@ -3,9 +3,13 @@
<package format="3">
<name>udp_teleop</name>
<version>0.0.0</version>
<description>TODO: Package description</description>
<description>UDP teleoperation and arm control for CRAIC robot</description>
<maintainer email="fallensigh@gmail.com">fallensigh</maintainer>
<license>TODO: License declaration</license>
<license>MIT</license>
<depend>rclpy</depend>
<depend>std_msgs</depend>
<depend>arm_control_msgs</depend>
<test_depend>ament_copyright</test_depend>
<test_depend>ament_flake8</test_depend>

View File

@@ -29,7 +29,9 @@ setup(
},
entry_points={
'console_scripts': [
'keyboard_control = udp_teleop.keyboard_control:main'
'keyboard_control = udp_teleop.keyboard_control:main',
'arm_control = udp_teleop.arm_control:main',
'vision_grasp = udp_teleop.vision_grasp:main'
],
},
)

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@@ -0,0 +1,743 @@
#!/usr/bin/env python3
"""机械臂控制 ROS 节点(独立版本)
完全独立,不依赖 udp_control.py
包含所有必要的运动学和控制代码
"""
import json
import math
import socket
import time
from dataclasses import dataclass
from pathlib import Path
from typing import Optional, List
import rclpy
from rclpy.node import Node
# 导入自定义消息
from arm_control_msgs.srv import (
MoveJoints,
MovePose,
GetPose,
SetGripper
)
from arm_control_msgs.msg import (
JointState,
TCPPose
)
# ============================================================================
# 常量定义
# ============================================================================
DEFAULT_UDP_IP = "192.168.4.1"
DEFAULT_UDP_PORT = 8888
DEFAULT_HEIGHT_MIN = -290
DEFAULT_HEIGHT_MAX = 0
DEFAULT_JOINT_MIN = -180
DEFAULT_JOINT_MAX = 180
DEFAULT_J2_MIN = -110
DEFAULT_J2_MAX = 115
DEFAULT_J3_MIN = -120
DEFAULT_J3_MAX = 145
DEFAULT_J4_MIN = -90
DEFAULT_J4_MAX = 130
J5_OPEN = 81
J5_CLOSED = -100
DEFAULT_FIXED_J5 = J5_OPEN
GRIP_ANGLE = -5
RELEASE_ANGLE = 80
DEFAULT_FIXED_J6 = RELEASE_ANGLE
DEFAULT_ZERO_J2 = 3
DEFAULT_ZERO_J3 = 7
DEFAULT_ZERO_J4 = 25
DEFAULT_L1 = 125.0
DEFAULT_L2 = 125.0
DEFAULT_X4 = 110.0
DEFAULT_Z4 = 80.0
DEFAULT_INTERP_DURATION = 1.0
DEFAULT_INTERP_RATE = 20.0
STATE_FILE = Path.home() / ".ros" / "udp_control_state.json"
# ============================================================================
# 数据类定义
# ============================================================================
class ArmControlError(ValueError):
"""机械臂控制错误"""
pass
@dataclass(frozen=True)
class ArmGeometry:
"""机械臂几何参数"""
l1: float
l2: float
x4: float
z4: float
@dataclass(frozen=True)
class ArmLimits:
"""关节限位"""
height_min: int = DEFAULT_HEIGHT_MIN
height_max: int = DEFAULT_HEIGHT_MAX
joint_min: int = DEFAULT_JOINT_MIN
joint_max: int = DEFAULT_JOINT_MAX
j2_min: int = DEFAULT_J2_MIN
j2_max: int = DEFAULT_J2_MAX
j3_min: int = DEFAULT_J3_MIN
j3_max: int = DEFAULT_J3_MAX
j4_min: int = DEFAULT_J4_MIN
j4_max: int = DEFAULT_J4_MAX
@dataclass(frozen=True)
class ArmZeroOffsets:
"""零点偏移"""
j2: int = DEFAULT_ZERO_J2
j3: int = DEFAULT_ZERO_J3
j4: int = DEFAULT_ZERO_J4
@dataclass(frozen=True)
class ArmJointState:
"""关节状态"""
height: int
j2: int
j3: int
j4: int
j5: int = DEFAULT_FIXED_J5
j6: int = DEFAULT_FIXED_J6
def to_udp_message(self) -> bytes:
"""转换为 UDP 消息"""
return (
f"JXB:{self.height}:{self.j2}:{self.j3}:{self.j4}:"
f"{self.j5}:{self.j6}:0:0:EZHY\n"
).encode("utf-8")
@dataclass(frozen=True)
class ArmPose:
"""TCP 位姿"""
x: float
y: float
z: float
phi_deg: float
@dataclass(frozen=True)
class ArmMathState:
"""数学坐标系的关节状态"""
d1: float
theta2_deg: float
theta3_deg: float
theta4_deg: float
# ============================================================================
# 运动学函数
# ============================================================================
def clamp_int(value: float, lower: int, upper: int, name: str) -> int:
"""限幅并转换为整数"""
rounded = int(round(value))
if rounded < lower or rounded > upper:
raise ArmControlError(f"{name}={rounded} 超出范围 [{lower}, {upper}]")
return rounded
def normalize_angle_deg(angle_deg: float) -> float:
"""角度归一化到 [-180, 180)"""
normalized = (angle_deg + 180.0) % 360.0 - 180.0
if normalized == -180.0 and angle_deg > 0:
return 180.0
return normalized
def forward_kinematics(geometry: ArmGeometry, state: ArmMathState) -> ArmPose:
"""正运动学:关节角度 → TCP 位姿"""
theta2 = math.radians(state.theta2_deg)
theta3 = math.radians(state.theta3_deg)
theta4 = math.radians(state.theta4_deg)
phi = theta2 + theta3 + theta4
j4_center_x = (
geometry.l1 * math.cos(theta2) +
geometry.l2 * math.cos(theta2 + theta3)
)
j4_center_y = (
geometry.l1 * math.sin(theta2) +
geometry.l2 * math.sin(theta2 + theta3)
)
x = j4_center_x + geometry.x4 * math.cos(phi)
y = j4_center_y + geometry.x4 * math.sin(phi)
z = state.d1 - geometry.z4
return ArmPose(x=x, y=y, z=z, phi_deg=math.degrees(phi))
def inverse_kinematics(
geometry: ArmGeometry,
pose: ArmPose,
limits: ArmLimits,
elbow_up: bool,
j5: int,
j6: int,
) -> ArmMathState:
"""逆运动学TCP 位姿 → 关节角度"""
# 计算 J4 中心位置
phi = math.radians(pose.phi_deg)
j4_x = pose.x - geometry.x4 * math.cos(phi)
j4_y = pose.y - geometry.x4 * math.sin(phi)
j4_z = pose.z + geometry.z4
d1 = j4_z
# 计算平面距离
r2 = j4_x * j4_x + j4_y * j4_y
if r2 < 1e-9:
raise ArmControlError("目标点过于接近奇异点")
# 计算 theta3
denom = 2.0 * geometry.l1 * geometry.l2
if abs(denom) < 1e-9:
raise ArmControlError("几何参数无效")
c3 = (r2 - geometry.l1 * geometry.l1 - geometry.l2 * geometry.l2) / denom
if c3 < -1.0 - 1e-9 or c3 > 1.0 + 1e-9:
reach = math.sqrt(r2)
raise ArmControlError(f"目标超出工作空间,距离={reach:.3f}mm")
c3 = max(-1.0, min(1.0, c3))
s3_abs = math.sqrt(max(0.0, 1.0 - c3 * c3))
s3 = -s3_abs if elbow_up else s3_abs
theta3 = math.atan2(s3, c3)
theta2 = math.atan2(j4_y, j4_x) - math.atan2(
geometry.l2 * s3,
geometry.l1 + geometry.l2 * c3,
)
theta4 = phi - theta2 - theta3
return ArmMathState(
d1=d1,
theta2_deg=normalize_angle_deg(math.degrees(theta2)),
theta3_deg=normalize_angle_deg(math.degrees(theta3)),
theta4_deg=normalize_angle_deg(math.degrees(theta4)),
)
def command_to_math_state(
command_state: ArmJointState,
zero_offsets: ArmZeroOffsets,
) -> ArmMathState:
"""命令状态 → 数学状态"""
return ArmMathState(
d1=command_state.height,
theta2_deg=command_state.j2 - zero_offsets.j2,
theta3_deg=command_state.j3 - zero_offsets.j3,
theta4_deg=command_state.j4 - zero_offsets.j4,
)
def math_to_command_state(
math_state: ArmMathState,
zero_offsets: ArmZeroOffsets,
limits: ArmLimits,
j5: int,
j6: int,
) -> ArmJointState:
"""数学状态 → 命令状态"""
return ArmJointState(
height=clamp_int(
round(math_state.d1),
limits.height_min,
limits.height_max,
"height",
),
j2=clamp_int(
math_state.theta2_deg + zero_offsets.j2,
limits.j2_min,
limits.j2_max,
"J2",
),
j3=clamp_int(
math_state.theta3_deg + zero_offsets.j3,
limits.j3_min,
limits.j3_max,
"J3",
),
j4=clamp_int(
math_state.theta4_deg + zero_offsets.j4,
limits.j4_min,
limits.j4_max,
"J4",
),
j5=clamp_int(j5, limits.joint_min, limits.joint_max, "J5"),
j6=clamp_int(j6, limits.joint_min, limits.joint_max, "J6"),
)
def interpolate_command_states(
start: ArmJointState,
end: ArmJointState,
steps: int,
) -> List[ArmJointState]:
"""关节空间插值"""
if steps <= 1:
return [end]
states = []
for step_index in range(1, steps + 1):
t = step_index / steps
states.append(
ArmJointState(
height=int(round(start.height + (end.height - start.height) * t)),
j2=int(round(start.j2 + (end.j2 - start.j2) * t)),
j3=int(round(start.j3 + (end.j3 - start.j3) * t)),
j4=int(round(start.j4 + (end.j4 - start.j4) * t)),
j5=int(round(start.j5 + (end.j5 - start.j5) * t)),
j6=int(round(start.j6 + (end.j6 - start.j6) * t)),
)
)
return states
# ============================================================================
# ROS 节点
# ============================================================================
class ArmControlNode(Node):
"""机械臂控制 ROS 节点"""
def __init__(self):
super().__init__('arm_control')
# 声明参数
self.declare_parameters(
namespace='',
parameters=[
('udp_ip', DEFAULT_UDP_IP),
('udp_port', DEFAULT_UDP_PORT),
('l1', DEFAULT_L1),
('l2', DEFAULT_L2),
('x4', DEFAULT_X4),
('z4', DEFAULT_Z4),
('height_min', DEFAULT_HEIGHT_MIN),
('height_max', DEFAULT_HEIGHT_MAX),
('j2_min', DEFAULT_J2_MIN),
('j2_max', DEFAULT_J2_MAX),
('j3_min', DEFAULT_J3_MIN),
('j3_max', DEFAULT_J3_MAX),
('j4_min', DEFAULT_J4_MIN),
('j4_max', DEFAULT_J4_MAX),
('joint_min', DEFAULT_JOINT_MIN),
('joint_max', DEFAULT_JOINT_MAX),
('zero_j2', DEFAULT_ZERO_J2),
('zero_j3', DEFAULT_ZERO_J3),
('zero_j4', DEFAULT_ZERO_J4),
('default_duration', DEFAULT_INTERP_DURATION),
('default_rate', DEFAULT_INTERP_RATE),
('use_state_cache', True),
('publish_rate', 10.0),
]
)
# 获取参数
self.udp_ip = self.get_parameter('udp_ip').value
self.udp_port = self.get_parameter('udp_port').value
self.publish_rate = self.get_parameter('publish_rate').value
# 机械臂几何参数
self.geometry = ArmGeometry(
l1=self.get_parameter('l1').value,
l2=self.get_parameter('l2').value,
x4=self.get_parameter('x4').value,
z4=self.get_parameter('z4').value,
)
# 关节限位
self.limits = ArmLimits(
height_min=self.get_parameter('height_min').value,
height_max=self.get_parameter('height_max').value,
j2_min=self.get_parameter('j2_min').value,
j2_max=self.get_parameter('j2_max').value,
j3_min=self.get_parameter('j3_min').value,
j3_max=self.get_parameter('j3_max').value,
j4_min=self.get_parameter('j4_min').value,
j4_max=self.get_parameter('j4_max').value,
joint_min=self.get_parameter('joint_min').value,
joint_max=self.get_parameter('joint_max').value,
)
# 零点偏移
self.zero_offsets = ArmZeroOffsets(
j2=self.get_parameter('zero_j2').value,
j3=self.get_parameter('zero_j3').value,
j4=self.get_parameter('zero_j4').value,
)
# 默认插值参数
self.default_duration = self.get_parameter('default_duration').value
self.default_rate = self.get_parameter('default_rate').value
self.use_state_cache = self.get_parameter('use_state_cache').value
# 当前状态
self.current_state: Optional[ArmJointState] = None
self.load_state()
# UDP socket
self.udp_socket = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
# 创建服务
self.srv_move_joints = self.create_service(
MoveJoints,
'arm_control/move_joints',
self.handle_move_joints
)
self.srv_move_pose = self.create_service(
MovePose,
'arm_control/move_pose',
self.handle_move_pose
)
self.srv_get_pose = self.create_service(
GetPose,
'arm_control/get_pose',
self.handle_get_pose
)
self.srv_set_gripper = self.create_service(
SetGripper,
'arm_control/set_gripper',
self.handle_set_gripper
)
# 创建发布者
self.pub_joint_states = self.create_publisher(
JointState,
'arm_control/joint_states',
10
)
self.pub_tcp_pose = self.create_publisher(
TCPPose,
'arm_control/tcp_pose',
10
)
# 创建定时器发布状态
self.timer = self.create_timer(
1.0 / self.publish_rate,
self.publish_state
)
self.get_logger().info(f'机械臂控制节点已启动')
self.get_logger().info(f'UDP 目标: {self.udp_ip}:{self.udp_port}')
def load_state(self):
"""从缓存加载状态"""
if not self.use_state_cache or not STATE_FILE.exists():
self.current_state = ArmJointState(
height=0,
j2=self.zero_offsets.j2,
j3=self.zero_offsets.j3,
j4=self.zero_offsets.j4,
j5=DEFAULT_FIXED_J5,
j6=DEFAULT_FIXED_J6,
)
return
try:
data = json.loads(STATE_FILE.read_text())
self.current_state = ArmJointState(
height=data['height'],
j2=data['j2'],
j3=data['j3'],
j4=data['j4'],
j5=data.get('j5', DEFAULT_FIXED_J5),
j6=data.get('j6', DEFAULT_FIXED_J6),
)
self.get_logger().info(f'从缓存加载状态')
except Exception as e:
self.get_logger().warn(f'加载状态失败: {e},使用默认状态')
self.current_state = ArmJointState(
height=0,
j2=self.zero_offsets.j2,
j3=self.zero_offsets.j3,
j4=self.zero_offsets.j4,
j5=DEFAULT_FIXED_J5,
j6=DEFAULT_FIXED_J6,
)
def save_state(self):
"""保存状态到缓存"""
if not self.use_state_cache or self.current_state is None:
return
try:
STATE_FILE.parent.mkdir(parents=True, exist_ok=True)
data = {
'height': self.current_state.height,
'j2': self.current_state.j2,
'j3': self.current_state.j3,
'j4': self.current_state.j4,
'j5': self.current_state.j5,
'j6': self.current_state.j6,
}
STATE_FILE.write_text(json.dumps(data, indent=2))
except Exception as e:
self.get_logger().warn(f'保存状态失败: {e}')
def send_udp_commands(
self,
states: List[ArmJointState],
duration: float
) -> bool:
"""发送 UDP 命令序列"""
if not states:
return True
delay = duration / len(states) if len(states) > 1 and duration > 0.0 else 0.0
try:
for i, state in enumerate(states):
msg = state.to_udp_message()
self.udp_socket.sendto(msg, (self.udp_ip, self.udp_port))
if delay > 0.0 and i < len(states) - 1:
time.sleep(delay)
self.current_state = states[-1]
self.save_state()
return True
except Exception as e:
self.get_logger().error(f'发送 UDP 命令失败: {e}')
return False
def handle_move_joints(self, request, response):
"""处理关节空间运动服务"""
try:
target_state = ArmJointState(
height=clamp_int(request.height, self.limits.height_min, self.limits.height_max, 'height'),
j2=clamp_int(request.j2, self.limits.j2_min, self.limits.j2_max, 'j2'),
j3=clamp_int(request.j3, self.limits.j3_min, self.limits.j3_max, 'j3'),
j4=clamp_int(request.j4, self.limits.j4_min, self.limits.j4_max, 'j4'),
j5=clamp_int(request.j5, self.limits.joint_min, self.limits.joint_max, 'j5'),
j6=clamp_int(request.j6, self.limits.joint_min, self.limits.joint_max, 'j6'),
)
duration = request.duration if request.duration > 0 else self.default_duration
steps = max(1, int(math.ceil(duration * self.default_rate)))
path = interpolate_command_states(self.current_state, target_state, steps)
success = self.send_udp_commands(path, duration)
response.success = success
response.message = "运动完成" if success else "运动失败"
self.get_logger().info(f'关节运动 -> {response.message}')
except Exception as e:
response.success = False
response.message = f'错误: {str(e)}'
self.get_logger().error(f'关节运动失败: {e}')
return response
def handle_move_pose(self, request, response):
"""处理笛卡尔空间运动服务"""
try:
target_pose = ArmPose(
x=request.x,
y=request.y,
z=request.z,
phi_deg=request.phi
)
# 解析夹爪状态
if request.gripper_state == SetGripper.Request.GRIPPER_OPEN:
j5 = J5_OPEN
elif request.gripper_state == SetGripper.Request.GRIPPER_CLOSED:
j5 = J5_CLOSED
else:
j5 = self.current_state.j5
if request.grip:
j6 = GRIP_ANGLE
elif request.release:
j6 = RELEASE_ANGLE
else:
j6 = self.current_state.j6
# 逆运动学
math_state = inverse_kinematics(
geometry=self.geometry,
pose=target_pose,
limits=self.limits,
elbow_up=request.elbow_up,
j5=j5,
j6=j6,
)
# 转换为命令状态
target_state = math_to_command_state(
math_state,
self.zero_offsets,
self.limits,
j5=j5,
j6=j6,
)
duration = request.duration if request.duration > 0 else self.default_duration
steps = max(1, int(math.ceil(duration * self.default_rate)))
path = interpolate_command_states(self.current_state, target_state, steps)
success = self.send_udp_commands(path, duration)
response.success = success
response.message = "运动完成" if success else "运动失败"
self.get_logger().info(
f'位姿运动: ({request.x:.1f}, {request.y:.1f}, {request.z:.1f}, {request.phi:.1f}) '
f'-> {response.message}'
)
except Exception as e:
response.success = False
response.message = f'错误: {str(e)}'
self.get_logger().error(f'位姿运动失败: {e}')
return response
def handle_get_pose(self, request, response):
"""处理查询位姿服务"""
try:
if self.current_state is None:
response.success = False
response.message = "当前状态未初始化"
return response
math_state = command_to_math_state(self.current_state, self.zero_offsets)
pose = forward_kinematics(self.geometry, math_state)
response.success = True
response.x = pose.x
response.y = pose.y
response.z = pose.z
response.phi = pose.phi_deg
response.height = self.current_state.height
response.j2 = self.current_state.j2
response.j3 = self.current_state.j3
response.j4 = self.current_state.j4
response.j5 = self.current_state.j5
response.j6 = self.current_state.j6
except Exception as e:
response.success = False
response.message = f'错误: {str(e)}'
self.get_logger().error(f'查询位姿失败: {e}')
return response
def handle_set_gripper(self, request, response):
"""处理夹爪控制服务"""
try:
if request.gripper_state == SetGripper.Request.GRIPPER_OPEN:
j5 = J5_OPEN
elif request.gripper_state == SetGripper.Request.GRIPPER_CLOSED:
j5 = J5_CLOSED
else:
j5 = self.current_state.j5
if request.grip:
j6 = GRIP_ANGLE
elif request.release:
j6 = RELEASE_ANGLE
else:
j6 = self.current_state.j6
target_state = ArmJointState(
height=self.current_state.height,
j2=self.current_state.j2,
j3=self.current_state.j3,
j4=self.current_state.j4,
j5=j5,
j6=j6,
)
success = self.send_udp_commands([target_state], 0.0)
response.success = success
response.message = "夹爪控制完成" if success else "夹爪控制失败"
self.get_logger().info(f'夹爪控制: j5={j5}, j6={j6} -> {response.message}')
except Exception as e:
response.success = False
response.message = f'错误: {str(e)}'
self.get_logger().error(f'夹爪控制失败: {e}')
return response
def publish_state(self):
"""定时发布状态"""
if self.current_state is None:
return
try:
# 发布关节状态
joint_msg = JointState()
joint_msg.header.stamp = self.get_clock().now().to_msg()
joint_msg.height = self.current_state.height
joint_msg.j2 = self.current_state.j2
joint_msg.j3 = self.current_state.j3
joint_msg.j4 = self.current_state.j4
joint_msg.j5 = self.current_state.j5
joint_msg.j6 = self.current_state.j6
self.pub_joint_states.publish(joint_msg)
# 计算并发布 TCP 位姿
math_state = command_to_math_state(self.current_state, self.zero_offsets)
pose = forward_kinematics(self.geometry, math_state)
pose_msg = TCPPose()
pose_msg.header.stamp = self.get_clock().now().to_msg()
pose_msg.x = pose.x
pose_msg.y = pose.y
pose_msg.z = pose.z
pose_msg.phi = pose.phi_deg
self.pub_tcp_pose.publish(pose_msg)
except Exception as e:
self.get_logger().error(f'发布状态失败: {e}')
def destroy_node(self):
"""节点销毁时的清理"""
self.udp_socket.close()
super().destroy_node()
def main(args=None):
rclpy.init(args=args)
node = ArmControlNode()
try:
rclpy.spin(node)
except KeyboardInterrupt:
pass
finally:
node.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()

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#!/usr/bin/env python3
"""机械臂控制客户端示例
演示如何调用机械臂控制服务
"""
import rclpy
from rclpy.node import Node
from arm_control_msgs.srv import MoveJoints, MovePose, GetPose, SetGripper
class ArmControlClient(Node):
"""机械臂控制客户端"""
def __init__(self):
super().__init__('arm_control_client')
# 创建服务客户端
self.cli_move_joints = self.create_client(MoveJoints, 'arm_control/move_joints')
self.cli_move_pose = self.create_client(MovePose, 'arm_control/move_pose')
self.cli_get_pose = self.create_client(GetPose, 'arm_control/get_pose')
self.cli_set_gripper = self.create_client(SetGripper, 'arm_control/set_gripper')
# 等待服务可用
self.get_logger().info('等待服务...')
self.cli_move_joints.wait_for_service()
self.cli_move_pose.wait_for_service()
self.cli_get_pose.wait_for_service()
self.cli_set_gripper.wait_for_service()
self.get_logger().info('服务已连接')
def get_current_pose(self):
"""查询当前位姿"""
req = GetPose.Request()
future = self.cli_get_pose.call_async(req)
rclpy.spin_until_future_complete(self, future)
if future.result().success:
result = future.result()
self.get_logger().info(
f'当前位姿: x={result.x:.1f}, y={result.y:.1f}, '
f'z={result.z:.1f}, phi={result.phi:.1f}°'
)
self.get_logger().info(
f'关节角度: height={result.height}, j2={result.j2}, '
f'j3={result.j3}, j4={result.j4}, j5={result.j5}, j6={result.j6}'
)
return result
else:
self.get_logger().error(f'查询失败: {future.result().message}')
return None
def move_to_joints(self, height, j2, j3, j4, j5=81, j6=30, duration=2.0):
"""关节空间运动"""
req = MoveJoints.Request()
req.height = height
req.j2 = j2
req.j3 = j3
req.j4 = j4
req.j5 = j5
req.j6 = j6
req.duration = duration
self.get_logger().info(f'关节运动: height={height}, j2={j2}, j3={j3}, j4={j4}')
future = self.cli_move_joints.call_async(req)
rclpy.spin_until_future_complete(self, future)
if future.result().success:
self.get_logger().info('运动完成')
return True
else:
self.get_logger().error(f'运动失败: {future.result().message}')
return False
def move_to_pose(self, x, y, z, phi, duration=2.0, grip=False, release=False):
"""笛卡尔空间运动"""
req = MovePose.Request()
req.x = x
req.y = y
req.z = z
req.phi = phi
req.duration = duration
req.grip = grip
req.release = release
req.gripper_state = MovePose.Request.GRIPPER_KEEP
req.elbow_up = False
self.get_logger().info(f'位姿运动: ({x:.1f}, {y:.1f}, {z:.1f}), phi={phi:.1f}°')
future = self.cli_move_pose.call_async(req)
rclpy.spin_until_future_complete(self, future)
if future.result().success:
self.get_logger().info('运动完成')
return True
else:
self.get_logger().error(f'运动失败: {future.result().message}')
return False
def set_gripper(self, grip=False, release=False):
"""夹爪控制"""
req = SetGripper.Request()
req.grip = grip
req.release = release
req.gripper_state = SetGripper.Request.GRIPPER_KEEP
action = "抓取" if grip else ("释放" if release else "保持")
self.get_logger().info(f'夹爪控制: {action}')
future = self.cli_set_gripper.call_async(req)
rclpy.spin_until_future_complete(self, future)
if future.result().success:
self.get_logger().info('夹爪控制完成')
return True
else:
self.get_logger().error(f'夹爪控制失败: {future.result().message}')
return False
def demo_sequence(client):
"""演示抓取流程"""
print("\n" + "="*60)
print("演示序列:查询 → 移动 → 抓取")
print("="*60 + "\n")
# 1. 查询当前位姿
print("1. 查询当前位姿...")
client.get_current_pose()
# 2. 移动到上方
print("\n2. 移动到物体上方...")
client.move_to_pose(x=200.0, y=100.0, z=-50.0, phi=45.0, duration=2.0, release=True)
# 3. 下降到抓取位置
print("\n3. 下降到抓取位置...")
client.move_to_pose(x=200.0, y=100.0, z=-150.0, phi=45.0, duration=1.0, release=True)
# 4. 抓取
print("\n4. 执行抓取...")
client.set_gripper(grip=True)
# 5. 提升
print("\n5. 提升物体...")
client.move_to_pose(x=200.0, y=100.0, z=-50.0, phi=45.0, duration=1.0, grip=True)
# 6. 移动到目标位置
print("\n6. 移动到目标位置...")
client.move_to_pose(x=100.0, y=200.0, z=-50.0, phi=90.0, duration=2.0, grip=True)
# 7. 下降
print("\n7. 下降...")
client.move_to_pose(x=100.0, y=200.0, z=-150.0, phi=90.0, duration=1.0, grip=True)
# 8. 释放
print("\n8. 释放物体...")
client.set_gripper(release=True)
# 9. 提升
print("\n9. 提升...")
client.move_to_pose(x=100.0, y=200.0, z=-50.0, phi=90.0, duration=1.0, release=True)
print("\n" + "="*60)
print("演示完成!")
print("="*60 + "\n")
def main():
rclpy.init()
client = ArmControlClient()
try:
# 运行演示序列
demo_sequence(client)
except KeyboardInterrupt:
pass
finally:
client.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()

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#!/usr/bin/env python3
"""视觉抓取 ROS 节点
基于相机坐标系到基坐标系的变换,实现自动抓取和释放功能。
功能:
1. 抓取服务:输入相机坐标 (x, y, z),自动转换并执行抓取
2. 释放服务:输入基坐标系位置,移动并释放物体
"""
import math
from typing import Tuple
import numpy as np
import rclpy
from rclpy.node import Node
from arm_control_msgs.srv import MovePose, GetPose, SetGripper
from std_srvs.srv import Trigger
from geometry_msgs.msg import Point
# ============================================================================
# 坐标变换函数(从 camera_to_base.py 复制)
# ============================================================================
def euler_to_rotation_matrix(roll_deg: float, pitch_deg: float, yaw_deg: float) -> np.ndarray:
"""欧拉角转旋转矩阵ZYX顺序"""
roll = math.radians(roll_deg)
pitch = math.radians(pitch_deg)
yaw = math.radians(yaw_deg)
Rx = np.array([
[1, 0, 0],
[0, math.cos(roll), -math.sin(roll)],
[0, math.sin(roll), math.cos(roll)]
])
Ry = np.array([
[math.cos(pitch), 0, math.sin(pitch)],
[0, 1, 0],
[-math.sin(pitch), 0, math.cos(pitch)]
])
Rz = np.array([
[math.cos(yaw), -math.sin(yaw), 0],
[math.sin(yaw), math.cos(yaw), 0],
[0, 0, 1]
])
return Rz @ Ry @ Rx
def camera_to_tcp(
xc: float, yc: float, zc: float,
tx: float = 0.0, ty: float = 0.0, tz: float = 0.0,
roll: float = 0.0, pitch: float = 0.0, yaw: float = 0.0
) -> Tuple[float, float, float]:
"""相机坐标系 → TCP 坐标系"""
R = euler_to_rotation_matrix(roll, pitch, yaw)
T = np.array([tx, ty, tz])
P_cam = np.array([xc, yc, zc])
P_tcp = R @ P_cam + T
return float(P_tcp[0]), float(P_tcp[1]), float(P_tcp[2])
def tcp_to_base(
xt: float, yt: float, zt: float,
tcp_x: float, tcp_y: float, tcp_z: float, tcp_phi_deg: float
) -> Tuple[float, float, float]:
"""TCP 坐标系 → 机械臂基坐标系(水平相机版本)"""
phi = math.radians(tcp_phi_deg)
R_tcp_to_base = np.array([
[-math.sin(phi), 0, math.cos(phi)],
[ math.cos(phi), 0, math.sin(phi)],
[0, -1, 0]
])
P_tcp = np.array([xt, yt, zt])
P_base_relative = R_tcp_to_base @ P_tcp
P_base = P_base_relative + np.array([tcp_x, tcp_y, tcp_z])
return float(P_base[0]), float(P_base[1]), float(P_base[2])
def camera_to_base(
xc: float, yc: float, zc: float,
tcp_x: float, tcp_y: float, tcp_z: float, tcp_phi_deg: float,
cam_tx: float = 0.0, cam_ty: float = 0.0, cam_tz: float = 0.0,
cam_roll: float = 0.0, cam_pitch: float = 0.0, cam_yaw: float = 0.0
) -> Tuple[float, float, float]:
"""完整变换:相机坐标系 → 基坐标系"""
xt, yt, zt = camera_to_tcp(xc, yc, zc, cam_tx, cam_ty, cam_tz,
cam_roll, cam_pitch, cam_yaw)
xb, yb, zb = tcp_to_base(xt, yt, zt, tcp_x, tcp_y, tcp_z, tcp_phi_deg)
return xb, yb, zb
# ============================================================================
# 自定义服务定义
# ============================================================================
# 由于没有预定义服务,我们使用简化的接口
# 实际使用时可以创建自定义 .srv 文件
# ============================================================================
# 视觉抓取节点
# ============================================================================
class VisionGraspNode(Node):
"""视觉抓取 ROS 节点"""
def __init__(self):
super().__init__('vision_grasp')
# 声明参数
self.declare_parameters(
namespace='',
parameters=[
# 相机到 TCP 的变换参数
('cam_tx', 0.0),
('cam_ty', 0.0),
('cam_tz', 0.0),
('cam_roll', 0.0),
('cam_pitch', 0.0),
('cam_yaw', 0.0),
# 抓取参数
('approach_height_offset', 50.0), # 接近高度偏移 (mm)
('retract_position_x', 200.0), # 回收位置 X
('retract_position_y', 0.0), # 回收位置 Y
('grasp_duration', 3.0), # 抓取移动时长 (秒)
('release_duration', 2.0), # 释放移动时长 (秒)
('gripper_duration', 1.0), # 夹爪动作时长 (秒)
]
)
# 获取参数
self.cam_tx = self.get_parameter('cam_tx').value
self.cam_ty = self.get_parameter('cam_ty').value
self.cam_tz = self.get_parameter('cam_tz').value
self.cam_roll = self.get_parameter('cam_roll').value
self.cam_pitch = self.get_parameter('cam_pitch').value
self.cam_yaw = self.get_parameter('cam_yaw').value
self.approach_offset = self.get_parameter('approach_height_offset').value
self.retract_x = self.get_parameter('retract_position_x').value
self.retract_y = self.get_parameter('retract_position_y').value
self.grasp_duration = self.get_parameter('grasp_duration').value
self.release_duration = self.get_parameter('release_duration').value
self.gripper_duration = self.get_parameter('gripper_duration').value
# 创建服务客户端(连接到 arm_control 节点)
self.move_cli = self.create_client(MovePose, 'arm_control/move_pose')
self.get_pose_cli = self.create_client(GetPose, 'arm_control/get_pose')
self.gripper_cli = self.create_client(SetGripper, 'arm_control/set_gripper')
# 等待服务可用
self.get_logger().info('等待 arm_control 服务...')
self.move_cli.wait_for_service(timeout_sec=5.0)
self.get_pose_cli.wait_for_service(timeout_sec=5.0)
self.gripper_cli.wait_for_service(timeout_sec=5.0)
self.get_logger().info('arm_control 服务已连接')
# 创建订阅者:接收检测结果
self.grasp_sub = self.create_subscription(
Point,
'vision_grasp/grasp_target',
self.handle_grasp_target,
10
)
self.release_sub = self.create_subscription(
Point,
'vision_grasp/release_target',
self.handle_release_target,
10
)
self.get_logger().info('视觉抓取节点已启动')
self.get_logger().info('订阅话题:')
self.get_logger().info(' - /vision_grasp/grasp_target (geometry_msgs/Point)')
self.get_logger().info(' - /vision_grasp/release_target (geometry_msgs/Point)')
def get_current_tcp_pose(self) -> Tuple[float, float, float, float]:
"""查询当前 TCP 位姿"""
req = GetPose.Request()
future = self.get_pose_cli.call_async(req)
# 等待结果(不阻塞其他回调)
import time
start_time = time.time()
timeout = 5.0
while not future.done():
if time.time() - start_time > timeout:
raise RuntimeError("获取 TCP 位姿超时")
time.sleep(0.01)
result = future.result()
if not result.success:
raise RuntimeError(f"获取 TCP 位姿失败: {result.message}")
return result.x, result.y, result.z, result.phi
def move_to(self, x: float, y: float, z: float, phi: float,
duration: float, grip: bool = False, release: bool = False) -> bool:
"""移动到指定位置"""
req = MovePose.Request()
req.x = x
req.y = y
req.z = z
req.phi = phi
req.duration = duration
req.grip = grip
req.release = release
req.gripper_state = MovePose.Request.GRIPPER_KEEP
req.elbow_up = False
future = self.move_cli.call_async(req)
# 等待结果
import time
start_time = time.time()
timeout = duration + 5.0
while not future.done():
if time.time() - start_time > timeout:
self.get_logger().error("移动超时")
return False
time.sleep(0.01)
result = future.result()
if result is None:
self.get_logger().error("移动失败:无响应")
return False
return result.success
def set_gripper(self, grip: bool = False, release: bool = False) -> bool:
"""控制夹爪"""
req = SetGripper.Request()
req.grip = grip
req.release = release
req.gripper_state = SetGripper.Request.GRIPPER_KEEP
future = self.gripper_cli.call_async(req)
# 等待结果
import time
start_time = time.time()
timeout = 3.0
while not future.done():
if time.time() - start_time > timeout:
self.get_logger().error("夹爪控制超时")
return False
time.sleep(0.01)
result = future.result()
if result is None:
self.get_logger().error("夹爪控制失败:无响应")
return False
return result.success
def handle_grasp_target(self, msg: Point):
"""处理抓取目标"""
self.get_logger().info(f'收到抓取目标: 相机坐标 ({msg.x:.1f}, {msg.y:.1f}, {msg.z:.1f})')
# 在单独的线程中执行抓取,避免阻塞回调
import threading
thread = threading.Thread(
target=self._execute_grasp_thread,
args=(msg.x, msg.y, msg.z)
)
thread.start()
def _execute_grasp_thread(self, x: float, y: float, z: float):
"""在独立线程中执行抓取流程"""
try:
# 转换坐标:(x, y, z) -> (xc, yc, zc) = (x, -y, z)
xc = x
yc = -y
zc = z
self.get_logger().info(f'转换后相机坐标: ({xc:.1f}, {yc:.1f}, {zc:.1f})')
# 获取当前 TCP 位姿
tcp_x, tcp_y, tcp_z, tcp_phi = self.get_current_tcp_pose()
self.get_logger().info(f'当前 TCP: ({tcp_x:.1f}, {tcp_y:.1f}, {tcp_z:.1f}), phi={tcp_phi:.1f}°')
# 坐标变换
target_x, target_y, target_z = camera_to_base(
xc, yc, zc,
tcp_x, tcp_y, tcp_z, tcp_phi,
self.cam_tx, self.cam_ty, self.cam_tz,
self.cam_roll, self.cam_pitch, self.cam_yaw
)
self.get_logger().info(f'目标基坐标: ({target_x:.1f}, {target_y:.1f}, {target_z:.1f})')
# 执行抓取流程
self.execute_grasp(target_x, target_y, target_z, tcp_phi)
except Exception as e:
self.get_logger().error(f'抓取失败: {e}')
def handle_release_target(self, msg: Point):
"""处理释放目标"""
self.get_logger().info(f'收到释放目标: 基坐标 ({msg.x:.1f}, {msg.y:.1f}, {msg.z:.1f})')
# 在单独的线程中执行释放,避免阻塞回调
import threading
thread = threading.Thread(
target=self._execute_release_thread,
args=(msg.x, msg.y, msg.z)
)
thread.start()
def _execute_release_thread(self, x: float, y: float, z: float):
"""在独立线程中执行释放流程"""
try:
# 获取当前 TCP 位姿(用于获取 phi
_, _, _, tcp_phi = self.get_current_tcp_pose()
# 执行释放流程
self.execute_release(x, y, z, tcp_phi)
except Exception as e:
self.get_logger().error(f'释放失败: {e}')
def execute_grasp(self, x: float, y: float, z: float, phi: float):
"""执行抓取流程
1. release 夹爪 (duration=0)
2. 移动到目标位置 (duration=3)
3. grip 夹爪 (duration=1)
4. 移动到回收位置 (200, 0, 当前z)
"""
self.get_logger().info('=' * 60)
self.get_logger().info('开始抓取流程')
self.get_logger().info('=' * 60)
# 步骤 1: 释放夹爪
self.get_logger().info('1. 释放夹爪')
if not self.set_gripper(release=True):
self.get_logger().error('释放夹爪失败')
return
# 步骤 2: 移动到目标位置
self.get_logger().info(f'2. 移动到目标位置: ({x:.1f}, {y:.1f}, {z:.1f})')
if not self.move_to(x, y, z, phi, self.grasp_duration, release=True):
self.get_logger().error('移动到目标位置失败')
return
# 步骤 3: 抓取
self.get_logger().info('3. 抓取物体')
if not self.move_to(x, y, z, phi, self.gripper_duration, grip=True):
self.get_logger().error('抓取失败')
return
# 步骤 4: 移动到回收位置
self.get_logger().info(f'4. 移动到回收位置: ({self.retract_x:.1f}, {self.retract_y:.1f}, {z:.1f})')
if not self.move_to(self.retract_x, self.retract_y, z, phi, self.grasp_duration, grip=True):
self.get_logger().error('移动到回收位置失败')
return
self.get_logger().info('=' * 60)
self.get_logger().info('✓ 抓取完成!')
self.get_logger().info('=' * 60)
def execute_release(self, x: float, y: float, z: float, phi: float):
"""执行释放流程
1. 移动到指定位置
2. release 夹爪 (duration=0)
3. 回收到 (200, 0, 当前z)
"""
self.get_logger().info('=' * 60)
self.get_logger().info('开始释放流程')
self.get_logger().info('=' * 60)
# 步骤 1: 移动到释放位置
self.get_logger().info(f'1. 移动到释放位置: ({x:.1f}, {y:.1f}, {z:.1f})')
if not self.move_to(x, y, z, phi, self.release_duration, grip=True):
self.get_logger().error('移动到释放位置失败')
return
# 步骤 2: 释放夹爪
self.get_logger().info('2. 释放物体')
if not self.set_gripper(release=True):
self.get_logger().error('释放夹爪失败')
return
# 步骤 3: 回收到初始位置
self.get_logger().info(f'3. 回收到初始位置: ({self.retract_x:.1f}, {self.retract_y:.1f}, {z:.1f})')
if not self.move_to(self.retract_x, self.retract_y, z, phi, self.release_duration, release=True):
self.get_logger().error('回收失败')
return
self.get_logger().info('=' * 60)
self.get_logger().info('✓ 释放完成!')
self.get_logger().info('=' * 60)
def main(args=None):
rclpy.init(args=args)
# 使用多线程执行器以支持在回调中调用服务
from rclpy.executors import MultiThreadedExecutor
node = VisionGraspNode()
executor = MultiThreadedExecutor()
executor.add_node(node)
try:
executor.spin()
except KeyboardInterrupt:
pass
finally:
node.destroy_node()
rclpy.shutdown()
if __name__ == '__main__':
main()