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基于农机空间轨迹的作业面积的缓冲区算法
引用本文:刘 卉,孟志军,王 培,魏学礼,韩 宇.基于农机空间轨迹的作业面积的缓冲区算法[J].农业工程学报,2015,31(7):180-184.
作者姓名:刘 卉  孟志军  王 培  魏学礼  韩 宇
作者单位:1. 首都师范大学信息工程学院,北京 100048;,2. 国家农业智能装备工程技术研究中心,北京 100097;,2. 国家农业智能装备工程技术研究中心,北京 100097;,2. 国家农业智能装备工程技术研究中心,北京 100097;,2. 国家农业智能装备工程技术研究中心,北京 100097;
基金项目:国家"863"高技术研究发展计划项目(2013AA040401,2013AA102308,2012AA101905),北京市教委面上项目(KM201410028016),农业部"948"计划项目(2011-G32)
摘    要:农机规模化管理与市场化作业服务需要准确、实时、便捷的农机作业面积测量方法。该研究基于农机空间运行轨迹,设计了作业面积测量的矢量缓冲区算法和栅格缓冲区算法,并通过农机满幅作业和重叠作业对比试验,检验了上述2种缓冲区算法与距离测量算法分别在R1K(real time kinematic,实时动态差分)、亚米级和单点定位3种不同GNSS(global navigation satellite system,全球导航卫星系统)定位精度条件下的测量相对误差。试验结果表明:当农机具备自动导航满幅作业条件时,距离测量算法在任何定位精度下均能获得较高精度测量结果;缓冲区算法仅在差分定位时测量精度较高。当农机无导航重叠作业时,距离测量算法的误差会随着作业重叠率的增加而显著增大,而缓冲区算法不受作业重叠的影响,测量精度稳定。目前国内仍普遍采用人工操控的农机作业方式,重叠作业不可避免,缓冲区测量算法能够提供更加准确的作业面积测量结果。

关 键 词:农业机械  算法  全球定位系统  全球导航卫星系统(GNSS)  作业面积测量  缓冲区算法  轨迹
收稿时间:2014/10/29 0:00:00
修稿时间:2015/3/19 0:00:00

Buffer algorithms for operation area measurement based on global navigation satellite system trajectories of agricultural machinery
Liu Hui,Meng Zhijun,Wang Pei,Wei Xueli and Han Yu.Buffer algorithms for operation area measurement based on global navigation satellite system trajectories of agricultural machinery[J].Transactions of the Chinese Society of Agricultural Engineering,2015,31(7):180-184.
Authors:Liu Hui  Meng Zhijun  Wang Pei  Wei Xueli and Han Yu
Institution:1. Information Engineering College, Capital Normal University, Beijing 100048, China;,2. National Research Center of Intelligent Equipment for Agriculture, Beijing 100097, China;,2. National Research Center of Intelligent Equipment for Agriculture, Beijing 100097, China;,2. National Research Center of Intelligent Equipment for Agriculture, Beijing 100097, China; and 2. National Research Center of Intelligent Equipment for Agriculture, Beijing 100097, China;
Abstract:Abstract: The rapid development of modern agriculture in China has put forward higher requirements for agricultural machinery operation. In order to meet the requirement of agricultural machinery scale management and market service, operation area should be measured by using a kind of accurate, real-time and convenient method. The GNSS (global navigation satellite system) receiver installed in agricultural machinery can provide operation trajectory data in real time. The paper reports a vector buffer algorithm and a raster buffer algorithm for operation area measurement based on GNSS trajectories of agricultural machinery. The vector buffer algorithm calculates the area of operation buffer polygon which is generated by intersecting and merging the part line buffers based on trajectory segments using data analysis method of the GIS (geographic information system). The raster buffer algorithm calculates the area of entire operation buffer which is covered by a certain number of unit grids with known area value. At present operation area is measured by using the conventional distance algorithm based on the product of swath width and distance of trajectory segments. The tests of full-width operations and overlap operations were carried out to compare area measurement accuracy of these two buffer algorithms with the distance algorithm in three different GNSS positioning accuracies of RTK (real time kinematic), decimeter-level and single-point. Full-width operation was implemented in the control of automatic navigation system for agricultural machinery. Overlap operation was achieved by setting up different overlapping rates of 5%, 10%, 15%, 20% and 25%. The results showed that in the full-width operation tests the distance algorithm had higher area measurement precision in any GNSS positioning accuracy, and the mean of relative error was 0.72%. Compared with the distance algorithm, the two buffer algorithms precisely measured operation area only in differential GNSS positioning accuracy. Using RTK GNSS positioning, the relative errors of the vector buffer algorithm and the raster buffer algorithm were 0.31% and 0.18%, respectively. Using decimeter-level GNSS positioning, the relative errors of the two buffer algorithms were 2.43% and 1.44%, respectively. However, in overlap operation tests the relative error of the distance algorithm increased significantly with the increasing of overlapping rate in any GNSS positioning accuracy. Area measurement precisions of the buffer algorithms were not affected by the overlaps. The relative errors of the vector buffer algorithm in GNSS positioning accuracies of RTK, decimeter-level and single-point were 0.48%, 3.13% and 5.52%, respectively. The relative errors of the raster buffer algorithm in GNSS positioning accuracies of RTK, decimeter-level and single-point were 0.11%, 2.77% and 5.33%, respectively. In China it cannot avoid the operation overlaps while agricultural machineries are controlled by drivers, and therefore the buffer algorithm can provide more accurate and convenient method for operation area measurement.
Keywords:agricultural machinery  algorithms  geographic information system  global navigation satellite system  operation area measurement  buffer algorithm  trajectory
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