基于ROS和MQTT的超声测量系统的设计、实现与评价

2020 IEEE 8th Conference on Systems, Process and Control (ICSPC) Pub Date : 2020-12-11 DOI:10.1109/ICSPC50992.2020.9305802

V. Mahalleh, A. N. Chand, Arif Rahman

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引用次数: 0

摘要

在工业环境中执行检测任务需要高精度的系统。该系统的功能应该能够最大限度地减少操作人员在危险区域的参与。目前，超声波测厚的操作还不能由机器人驾驶员进行监控。当驾驶员强迫机器人测量表面厚度时，一名操作人员应负责通知驾驶员。本文通过机器人操作系统(ROS)和消息队列遥测传输(MQTT)之间的接口，设计和实现了一个可由用户和驾驶员同时可视化和控制的UT测量系统。MQTT是物联网(IoT)数据通信协议之一。ROS和MQTT之间的接口称为ROS-MQTT桥接。此外，我们还利用归一化互相关方法对每个主题的ROS-MQTT桥接信号和客户端信号进行了比较。我们用了两种钢材样品，一种是有涂层的，一种是没有涂层的。结果表明，客户端和ROS-MQTT桥端两个信号之间的厚度数归一化互相关为1。客户端以小于1毫秒的延迟接收厚度数。同样，对于另一个主题，如分配器，也是一样的。这项工作的贡献是开发UT测量系统与其他传感器，如激光雷达传感器和相机来控制机器人的运动。第二个贡献是帮助机器人驾驶员和其他用户从安全区域远程可视化和控制UT测量系统。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Design, Implementation and Evaluation of Ultrasonic Measurement System using ROS and MQTT

Performing inspection tasks in industrial environment require high accuracy systems. Capabilities of this system should have potential to minimize operator involvement in hazardous areas. Currently, operation of ultrasonic thickness (UT) measurement cannot be monitored and controlled by robot pilot. One operator should be responsible to inform pilot while pilot is forcing robot to measure the thickness of surface. This article presents designing and implementation of a UT measurement system that can be visualized and controlled by users and pilot simultaneously through an interface between Robotic Operating System (ROS) and Message Queue Telemetry Transport (MQTT). MQTT is one of the data communication protocols for Internet of Things (IoT). The interface between ROS and MQTT is called ROS-MQTT bridge. Moreover, we make a comparison between ROS-MQTT bridge and client signal for each topic by using normalized cross correlation method. We used two samples of steel, with and without coating. The results show that the normalized cross-correlation of 1 for thickness numbers between two signals in client and ROS-MQTT bridge sides. The client side received thickness number with less than 1 millisecond delay. Also, it is same for another topic such as dispenser. The contribution of this work is to develop UT measurement system with other sensors such as LiDAR sensors and camera to control robot motion. The second contribution is to assist robot pilot and other users to visualize and control the UT measurement system remotely from safe area.

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来源期刊

2020 IEEE 8th Conference on Systems, Process and Control (ICSPC)

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