UAV terrain following technology application in the mining subsidence monitoring research

doi:10.13474/j.cnki.11-2246.2021.0153

Abstract

Abstract: This study aims at the problem that the monitoring accuracy of the same aerial survey aircraft varies greatly due to the topographic relief when the traditional UAV conducts subsidence monitoring in mining area. In this paper, the influence of terrain change on the resolution, photo overlap and monitoring accuracy of the shooting image was analyzed. The TOF sensor was installed on the UAV, and the PID controller was coded to maintain the same height and stable flight relative to the ground, thus realizing the UAV terrain following monitoring. The results show that the terrain fluctuation will reduce the monitoring accuracy of the traditional UAV, but the method proposed in this paper can improve its accuracy, so that the UAV can follow the aerial survey and ensure the monitoring accuracy. Meanwhile, in mining areas with complex terrain, the average precision of traditional UAV for subsidence monitoring is 65.73 mm, making the average precision of UAV with terrain following technology for subsidence monitoring reach 46.59 mm, and greatly improving the detection accuracy of UAV. Compared with the observation line data in the field, the results can predict the subsidence trend accurately, but can not accurately capture the subtle changes of the surface. Thus, the obtained subsidence scope can comprehensively and extensively reflect the area affected by the subsidence which caused by the advance of the working face. Therefore, the research results can provide reference for mining subsidence monitoring.

Key words: mining subsidence, UAV, terrain following, time of flight sensor, photogrammetry

CLC Number:

YANG Xuting, YAO Wanqiang, ZHENG Junliang, MA Bolin, MA Xiaohui. UAV terrain following technology application in the mining subsidence monitoring research[J]. Bulletin of Surveying and Mapping, 2021, 0(5): 111-115.

References

[1] 邓喀中, 姚宁, 卢正, 等. D-InSAR监测开采沉陷的实验研究[J]. 金属矿山, 2009(12):25-27.
[2] 胡振琪, 王新静, 贺安民. 风积沙区采煤沉陷地裂缝分布特征与发生发育规律[J]. 煤炭学报, 2014, 39(1):11-18.
[3] 阎跃观, 戴华阳, 王忠武, 等. 急倾斜多煤层开采地表沉陷分区与围岩破坏机理——以木城涧煤矿大台井为例[J]. 中国矿业大学学报, 2013, 42(4):547-553.
[4] 王利民, 刘佳, 杨玲波, 等. 基于无人机影像的农情遥感监测应用[J]. 农业工程学报, 2013, 29(18):136-145.
[5] 刘军, 王鹤, 王秋玲, 等. 无人机遥感技术在露天矿边坡测绘中的应用[J]. 红外与激光工程, 2016, 45(S1):111-114.
[6] 张启元. 无人机航测技术在青藏高原地质灾害调查中的应用[J]. 青海大学学报(自然科学版), 2015, 33(2):67-72.
[7] 盛业华, 闫志刚, 宋金铃. 矿山地表塌陷区的数字近景摄影测量监测技术[J]. 中国矿业大学学报, 2003,32(4):411-415.
[8] ZHOU D W, QI L Z, ZHANG D M, et al. Unmanned aerial vehicle (UAV) photogrammetry technology for dynamic mining subsidence monitoring and parameter inversion:a case study in China[J]. IEEE Access, 2020, 8:16372-16386.
[9] STUPAR D I, ROŠER J, VULIĆ M. Investigation of unmanned aerial vehicles-based photogrammetry for large mine subsidence monitoring[J]. Minerals, 2020, 10(2):196.
[10] 张永年, 李秀丽. 地形起伏对无人机低空航测影响分析——以东桥镇、龙海市为例[J]. 测绘与空间地理信息, 2013, 36(3):176-178.
[11] 张衡, 李骁, 叶朋飞. 顾及地形起伏的无人机影像覆盖分析方法[J]. 测绘通报, 2020(1):102-106.
[12] 胡筱敏. 单辐射结合可编程计算器在航空像片上求样点[J]. 林业资源管理, 1987(1):46-48.
[13] 王峥羽, 王文成, 李德鑫, 等. 基于光流法地形跟随的矿区复杂地形无人机摄影测量[J]. 金属矿山, 2019, 48(7):167-171.
[14] 李秀丽.基于Google地图数据的可视化无人机航线规划研究[J].测绘通报,2014(1):74-76.
[15] 雍歧卫, 喻言家, 陈雁, 等. 地面管道无人机巡查起伏地形跟随方法[J]. 重庆理工大学学报(自然科学), 2017, 31(8):158-162.
[16] 赵小勇, 杨恒辉. 一种新的地形跟随飞行方法与关键技术研究[J]. 计算机测量与控制, 2012, 20(7):1983-1985.