Automatic control system of auxiliary transportation traffic light based on UWB precise positioning
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摘要: 针对当前辅助运输系统缺少有效的控制策略,车辆在路口盲区候车无序、错车困难,易发生碰撞事故,导致运输效率低的问题,设计了一种基于UWB精确定位的辅助运输交通灯自动控制系统。该系统确定了UWB定位基站在典型路口处的分布要求,设置了位置信息和行驶状态2个控制参数、多种放行机制和区间管控策略,规定了岔口的排序原则和优先级,具有自动控制、手动控制和定时切换3种控制模式。首先UWB定位基站扫描车辆定位卡数据,逻辑控制器实时读取定位基站的车辆数据信息并求解车辆的位置信息和行驶状态,控制交通灯执行控制指令,指挥运输车辆有序通行。逻辑控制器与上位机通过环网连接,上位机可下发控制指令远程变灯,逻辑控制器实时地将井下车辆的行驶数据、异常驾驶行为、交通灯状态等多种信息上传至上位机矿井车辆调度系统,实现就地控制与远程辅控相结合。在模拟巷道对该系统进行测试,结果表明:逻辑控制器代码运行正常,系统的逻辑响应时间<200 ms,交通灯状态切换的响应时间<1 s,弯道报警器能正确执行报警指令。大海则煤矿使用无轨车辆执行井下运输任务,在录车辆约140辆,运输线路不固定且运输任务繁重,重要路口流量大。该系统在环境复杂的大海则煤矿的应用结果表明,路口信息配置灵活,能够高度适配现场各个形式的路口,满足具体的路口管控需求;通过调整控制门限,系统能够调整路口控制区域的大小,适应现场运输流量的变化;定位基站采用不同的数据获取策略,降低了定位分站的铺设数量和施工成本;上位机能够实时监测井下车辆的交通调度状态,监控车辆的驾驶行为,实现了交通灯的远程管控。Abstract: The current auxiliary transportation system lacks effective control strategy. The vehicles waiting in the blind area at the intersection are disorderly. And it is difficult for one vehicle to give another the right of way. It is prone to collision accidents, resulting in low transport efficiency. This paper proposes an automatic control system of auxiliary transportation traffic light based on UWB precise positioning. The system determines the distribution requirements of UWB positioning base stations at typical intersections. The system sets two control parameters of position information and driving state, various release mechanisms and interval management and control strategies. The system specifies the sequencing principle and priority of forks. And the system has three control modes of automatic control, manual control and timing switching. Firstly, the UWB positioning base station scans the data of the vehicle positioning card. The logic controller reads the vehicle data information of the positioning base station in real time and solves the position information and the driving state of the vehicle. The logic controller controls the traffic light to execute the control command and directs the transportation vehicles to pass in an orderly manner. The logic controller is connected with an upper computer through a ring network. The upper computer can issue a control instruction to remotely change the light. And the logic controller uploads various information such as driving data, abnormal driving behaviors, traffic light states of underground vehicles to a mine vehicle dispatching system of the upper computer in real time. Therefore, the combination of local control and remote auxiliary control is realized. The system is tested in a simulated roadway. The result shows that the logic controller code operates normally. The logic response time of the system is<200 ms. The response time of the traffic light state switching is<1 s. And the curve alarm can correctly execute the alarm command. Dahaize Coal Mine uses trackless vehicles to carry out underground transportation tasks. There are about 140 recorded vehicles. The transportation lines are not fixed and the transportation tasks are intensive. The traffic at important intersections is large. The application results of the system in the complex environment of Dahaize Coal Mine show that the intersection information configuration is flexible. The system can highly adapt to various forms of intersections on-site, and meet the specific needs of intersection management and control. By adjusting the control threshold, the system can adjust the size of the intersection control area to adapt to the change of on-site transportation flow. The positioning base station adopts different data acquisition strategies, which reduces the laying quantity and construction cost of the positioning sub station. The upper computer can monitor the traffic scheduling status of underground vehicles in real time, monitor the driving behavior of vehicles, and realize the remote control of traffic lights.
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图 8 典型路口定位基站配置
Figure 8. Positioning base station configurations of typical regular intersections
图 15 模拟巷道交通灯自动控制系统布置
Figure 15. Layout of traffic light automatic control system of simulated roadway
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