GPS在高速铁路精密控制网复测中的应用研究
|
摘要
高速铁路作为当代铁路科学技术的一项重大成就,给我国铁路运输注入了新活力,代表着铁路建设运输的发展方向。高速铁路的生命力在于体现在其高速度、高密度、高舒适性和高安全方面。而要实现快速、舒适和安全,就需要高平顺和稳定的线路,这就要求严格控制线下结构各类变形误差。在铺设无砟轨道前,线下建筑的变形及各类测量误差满足规范设计要求,高精度的测量成果是高速铁路施工质量的重要保证。
高速铁路从勘测设计、施工到运营维护过程中要经过较长时间,受到外界条件的影响,会造成各级控制点的移动,进而会不同程度地影响到线下工程的施工与运营养护维修观测工作。因此,在高速铁路建设过程中,必须对各级控制点进行周期性复测。
论文主要研究成果包括以下方面:
(1)高速铁路的特点是带状走向,其施工控制测量工作沿着一条或几条投影带范围内进行。若利用国家统一的3°或6°带高斯平面直角坐标系,经过两次归算,其成果大多满足不了投影变形要求。针对高速铁路对控制网的高精度要求,《高速铁路工程测量规范》中明确规定:高速铁路工程测量平面控制网应采用工程独立坐标系,在对应的线路轨面设计高程面上坐标系统的长度变形值不宜大于10mm/km。为了保证工程测量的质量和精度,可以选择合适的参考面或采用任意独立高斯坐标投影平面直角坐标系来减小投影变形;
(2)如何选择合适的高级控制点作为起算数据将直接影响到复测控制网整体精度,影响到复测网与原测网的成果比较分析,进而影响到整个复测控制点的稳定性分析。论文采用单位权方差假设检验法、附合路线坐标闭合差检验法、约束平差分析法(检查点法)、尺度参数分析法、实测基线比较法五种不同的起点兼容性分析方法对复测控制网内已知高级控制点进行兼容性分析,判定基准点(起算点)的精度是否合格;
(3)获得复测成果后,对复测成果与原测成果进行分析,比较两期或多期的平面直角坐标差值,合理建立数据处理数学模型,用最优方法估计位移值并进行显著性检验,综合野外标石外观检视评判控制点的稳定性;并运用洞外GPS控制点复测误差对隧道横向贯通误差的影响进行预计。
As a major achievement of railway science and technology, Modern high-speedrailway has injected new vitality into China’s railway transport and represented thedevelopment direction of transportation and railway construction. The vitality ofhigh-speed railway is reflected in its high speed, high density, high comfort and highsafety. To achieve high-speed, comfort and security, we need smooth and stable highlinewhich requires strict control of the line structure of various types of distortionerror. In the pre-laying track ballastless, deformation of line construction and all kindsof measurement errors must meet the design specification requirements.High-precision measurement outcomes are an important quality assurance ofhigh-speed railway construction.
High-speed railway from the survey design, construction and operation tomaintenance will go through a long period of time. By the impact of externalconditions, will result in the movement at all levels of the control points, and then willbe affected in varying degrees to the line construction and operation of engineering onMaintenance observations.
The main research productions are listed below:
(1) The characteristic of High-speed railway measurement is like of ribbon, theconstruction was done in one or several strips. For the high precision control ofHigh-speed rail network, some provisions in specifications for survey engineering ofHigh-speed railway clearly states: horizontal control network of high speed railproject measurement should use independent system. The system coordinate length ofdeformation should not be greater than 10mm/km in the corresponding designedelevation surface.The use of national unity 3°or 6°Gaussian plane rectangularcoordinate system mostly cannot meet those requirements after two imputed inHigh-speed railway network for the project and the retest. In order to ensure projectquality and accuracy of measurement, we can choose a suitable reference surface or using any of independent Gaussian coordinate projection plane rectangular coordinatesystem to reduce the projection distortion;
(2) How to choose a high-level control points as the initial data will directlyaffect the overall accuracy of the retest control network and the retest of the originalsurvey grid network and the results of comparative analysis, thereby affect the entireretest stability analysis of control points. Paper uses five different methods such as theunit weight variance hypothesis testing, the comparison method of actual baseline,constraint adjustment method (direct analytic method of adjustment result)andannexed traverse coordinate misclosure testing method to analyses the stability of theknown high-level control points in retest control network and determines the referencepoint (starting point) compatibility.
(3) Access to retest results, the author should analyses the retest and the originaltest results and compare two or more the difference between the plane rectangularcoordinates and establish a reasonable mathematical model of a data processing toevaluate the stability of the control points by means of the significance test of optimalmethod to estimate displacement and mark stone appearance in the view field.
高速铁路从勘测设计、施工到运营维护过程中要经过较长时间,受到外界条件的影响,会造成各级控制点的移动,进而会不同程度地影响到线下工程的施工与运营养护维修观测工作。因此,在高速铁路建设过程中,必须对各级控制点进行周期性复测。
论文主要研究成果包括以下方面:
(1)高速铁路的特点是带状走向,其施工控制测量工作沿着一条或几条投影带范围内进行。若利用国家统一的3°或6°带高斯平面直角坐标系,经过两次归算,其成果大多满足不了投影变形要求。针对高速铁路对控制网的高精度要求,《高速铁路工程测量规范》中明确规定:高速铁路工程测量平面控制网应采用工程独立坐标系,在对应的线路轨面设计高程面上坐标系统的长度变形值不宜大于10mm/km。为了保证工程测量的质量和精度,可以选择合适的参考面或采用任意独立高斯坐标投影平面直角坐标系来减小投影变形;
(2)如何选择合适的高级控制点作为起算数据将直接影响到复测控制网整体精度,影响到复测网与原测网的成果比较分析,进而影响到整个复测控制点的稳定性分析。论文采用单位权方差假设检验法、附合路线坐标闭合差检验法、约束平差分析法(检查点法)、尺度参数分析法、实测基线比较法五种不同的起点兼容性分析方法对复测控制网内已知高级控制点进行兼容性分析,判定基准点(起算点)的精度是否合格;
(3)获得复测成果后,对复测成果与原测成果进行分析,比较两期或多期的平面直角坐标差值,合理建立数据处理数学模型,用最优方法估计位移值并进行显著性检验,综合野外标石外观检视评判控制点的稳定性;并运用洞外GPS控制点复测误差对隧道横向贯通误差的影响进行预计。
As a major achievement of railway science and technology, Modern high-speedrailway has injected new vitality into China’s railway transport and represented thedevelopment direction of transportation and railway construction. The vitality ofhigh-speed railway is reflected in its high speed, high density, high comfort and highsafety. To achieve high-speed, comfort and security, we need smooth and stable highlinewhich requires strict control of the line structure of various types of distortionerror. In the pre-laying track ballastless, deformation of line construction and all kindsof measurement errors must meet the design specification requirements.High-precision measurement outcomes are an important quality assurance ofhigh-speed railway construction.
High-speed railway from the survey design, construction and operation tomaintenance will go through a long period of time. By the impact of externalconditions, will result in the movement at all levels of the control points, and then willbe affected in varying degrees to the line construction and operation of engineering onMaintenance observations.
The main research productions are listed below:
(1) The characteristic of High-speed railway measurement is like of ribbon, theconstruction was done in one or several strips. For the high precision control ofHigh-speed rail network, some provisions in specifications for survey engineering ofHigh-speed railway clearly states: horizontal control network of high speed railproject measurement should use independent system. The system coordinate length ofdeformation should not be greater than 10mm/km in the corresponding designedelevation surface.The use of national unity 3°or 6°Gaussian plane rectangularcoordinate system mostly cannot meet those requirements after two imputed inHigh-speed railway network for the project and the retest. In order to ensure projectquality and accuracy of measurement, we can choose a suitable reference surface or using any of independent Gaussian coordinate projection plane rectangular coordinatesystem to reduce the projection distortion;
(2) How to choose a high-level control points as the initial data will directlyaffect the overall accuracy of the retest control network and the retest of the originalsurvey grid network and the results of comparative analysis, thereby affect the entireretest stability analysis of control points. Paper uses five different methods such as theunit weight variance hypothesis testing, the comparison method of actual baseline,constraint adjustment method (direct analytic method of adjustment result)andannexed traverse coordinate misclosure testing method to analyses the stability of theknown high-level control points in retest control network and determines the referencepoint (starting point) compatibility.
(3) Access to retest results, the author should analyses the retest and the originaltest results and compare two or more the difference between the plane rectangularcoordinates and establish a reasonable mathematical model of a data processing toevaluate the stability of the control points by means of the significance test of optimalmethod to estimate displacement and mark stone appearance in the view field.
引文
[1]岑敏仪.高速铁路精密测量理论及测绘新技术应用国际学术研讨会论文集[C].成都:西南交通大学出版社,2010.11-15.
[2]朱颖.客运专线无砟轨道铁路工程测量技术[M].北京:中国铁道出版社,2008.5.
[3]杜锐,王解先.隧道贯通测量精密数据处理[J].工程勘察,2009,(07):72-75.
[4]刘爽.中国高速铁路发展之路[EB/OL].人民网.[2010-10-26].http://ccnews.people.com.cn/GB/142063/13051488.html.
[5]李明军.基于某高速铁路精密工程测量若干问题研究[D].长春:吉林大学,2009.
[6]刘权威,夏志朴.大型施工控制网复测周期的优化[J].测绘通报,1994,(04):15-17.
[7]芮东升,赵陆青.德国高速铁路轨道技术[J].铁路标准设计,2006,(增刊):144-146.
[8]王普.高速铁路建设发展概况研究[J].郑铁科技通讯,2006,(04).
[9]武汉大学测绘学院测量平差学科组编著.误差理论与测量平差基础[M].武汉:武汉大学出版社,2003.
[10]中铁二院工程集团有限公司.TB10601-2009,J962-2009高速铁路工程测量规范[S].北京:中国铁道出版社,2010.
[11]孔祥元,梅是义.控制测量学(下册)[M].武汉:武汉大学出版社,2002.2.
[12]金玉山.具有抵偿高程面的任意带坐标系设计原理与方法[J].铁道勘察,2005,(04):25-28.
[13]卢建康,刘华.高速铁路精密工程测量技术体系的建立及特点[J].铁道标准设计,2010(增刊1): 70-73.
[14]王铁生,张冰,赵仲荣.地铁高精度GPS控制网及其起算点兼容性分析[J].华北水利水电学院学报,2002,25(02):8-10.
[15]刘烈昭,等.GPS网平差精度、可靠性与置信度的评定.GPS测地研究与应用文集[C],北京:测绘出版社,1992.
[16]张英翔等.京沪高速铁路CPⅡ控制网复测技术研究[J].地理空间信息,2008,06(03) :112-114.
[17]尚云东.基于统计参数的隧道贯通测量误差预计分析[J].桥隧机械&施工技术,2008,(04):72-74.
[18]张正禄,张松林,伍志刚等.20~50km超长隧道(洞)横向贯通误差允许值研究[J],测绘学报,2004,33(01):83-88.
[19]张正禄等.工程测量学[M].武汉:武汉大学出版社,2005.10.
[20]中国有色金属工业协会主编.工程测量规范(GB50026-2007)[S].北京:中国计划出版社,2008.
[21]武汉测绘科技大学《测量学》编写组编.测量学(第三版)[M].北京:测绘出版社,2003.
[22]李征航,黄劲松编著.GPS测量与数据处理[M].武汉:武汉大学出版社,2005.
[23]潘正风,杨正尧,程效军,成枢,王腾军编著.数字化测图原理与方法[M].武汉:武汉大学出版社,2004.
[24]徐绍铨.GPS测量原理及运用[M].武汉:武汉大学出版社,2003.
[25]李明峰,冯宝红,刘三枝.GPS定位技术及其应用[M].北京:国防工业出版社,2007.
[26]张永彬,高刚毅.GPS三维联合平差[J].矿山测量,2003,(1):15-17.
[27]张瑞,姚宜斌,梁静,王品,刘强.GPS网平差程序设计[J].全球定位系统,2009,(2):54-58.
[28]彭先进.测量控制网的优化设计[M].武汉:武汉测绘科技大学出版社,1991.
[29]李辉.高精度GPS控制网的优化设计研究[D].北京:北京交通大学,2009.
[30]匡翠林.高精度GPS水准算法研究及其应用[D].长沙:中南大学,2004.
[31]佩尔策主编,张正禄编译.现代工程测量控制网的理论和应用[M].北京:测绘出版.1989.
[33]中华人民共和国国家质量监督检验检疫总局.全球定位系统(GPS)测量规范(GB/T18314-2009)[S].北京:中国标准出版社,2009.
[34]地球科学与测量工程学院.实用GPS数据处理教程[M].武汉:武汉测绘科技大学.
[35]顾利亚,岑敏仪.施工控制网的优化设计[J].西南交通大学学报,1997,32(2):160-164.
[36]中国人民共和国铁道部.TB10054-2010铁路工程卫星定位测量规范[S].北京:中国铁道出版社,2010.
[37]中国人民共和国铁道部.新建铁路工程测量规范(TB10101)[S].北京:中国铁道出版社,2009.
[38]中国铁建二十三局集团有限公司.新建兰渝铁路引入重庆枢纽站前代建Ⅰ标工程简介.[EB/OL].中国铁建二十三局集团有限公司网站.[2008-04-22].
[39]王铁生,等.城市高精度GPS控制网的复测与网形优化[J].测绘学院学报,2004,21(2):102-104.
[40]傅晓明,沈云中.工程GPS网平差起算点坐标的误差分析[J].测绘通报,2002,(9):54-56.
[41]邢继红.GPS网起始数据的误差分析[J].地理空间信息,2008,4(4):13-15.
[42]赵长胜.GPS控制网设计与数据处理[M].北京:科学教育出版社,2001.
[43]梅熙.GPS技术建立客运专线平面控制网若干问题[J].科学技术通讯,2005,(128):14-19.
[44]张方仁,于正林.平差基准点稳定性分析与判别[J].测绘通报,1994(5):35-41.
[45]董世清,李志成. GPS测量控制网起算点的兼容性分析[J].四川测绘,2003,26(4):169-172.
[46]肖华.GPS网起算点坐标的兼容性问题分析及其处理[J].湖南水利水电,2003,(5):15-16.
[47]傅晓明.工程GPS网平差起算点坐标的误差分析[J].工程勘察,2004,(2):54-56.
[48]张兵,赵瑞.GPS控制网起算点兼容性分析方法研究与实践[J].测绘科学,2010,35(5):65-67.
[49]宋铁群.GPS起算点坐标的兼容性分析[J].测绘与空间地理信息,2009,32(3):63-66.
[50]章淑君,靳永滨.检核GPS测量控制网起算点精度的方法及其探讨[J].四川测绘,2005,28(2):60-63.
[51]王岩,岳建平,周保兴,葛世超.工程控制网点位稳定性分析方法的研究[J].测绘通报,2004,(8):12-14.
[52]苏京平.控制网的稳定性分析[J].城市勘测,2000,(4):14-16.
[53]马海志.工程施工平面控制网稳定性分析探讨[J].城市勘测,2007,(2):60-63.
[54]吴大江.浅谈施工测量首级控制网的稳定性检验[J].矿山测量,2009,(4):13-14.
[55]卢献健,任超.GPS数据处理科研软件与商业软件对比分析[J].全球定位系统,2007,(5):29-32.
[56] Jay Gao.Integration of GPS with Remote Sensing and GIS: Reality and Prospect[J].Photogram metric Engineering & Remote Sensing 68_2002.447-453.
[57] Yang Y.Robust Estimation of Geodetic Datum Transformation. Journal of Geodesy,1999,73:268-274
[58] Sung-Pil Hong,Kyung Min Kim,Kyungsik Lee and Bum Hwan Park.A pragmatic algorithmfor the train-set routing:The case of Korea high-speed railway[J] . Omega,2009(3):637-645.
[59] Lu baixiang,Cen Minyi.A problem in the application of the Error Ellipsoid[J].SurverReview,1993,239-243.
[60] MILE Vivo,GRENDIG lothar.Germany.Rail Track Data Base Of German Rail-The Future orAutomated Maintenance [R],INGEO 2004 and FIG Region Central And Eastern EuropeanConference On Engineering Surveying Bratislava, Washiongton,D.C,2002.
[2]朱颖.客运专线无砟轨道铁路工程测量技术[M].北京:中国铁道出版社,2008.5.
[3]杜锐,王解先.隧道贯通测量精密数据处理[J].工程勘察,2009,(07):72-75.
[4]刘爽.中国高速铁路发展之路[EB/OL].人民网.[2010-10-26].http://ccnews.people.com.cn/GB/142063/13051488.html.
[5]李明军.基于某高速铁路精密工程测量若干问题研究[D].长春:吉林大学,2009.
[6]刘权威,夏志朴.大型施工控制网复测周期的优化[J].测绘通报,1994,(04):15-17.
[7]芮东升,赵陆青.德国高速铁路轨道技术[J].铁路标准设计,2006,(增刊):144-146.
[8]王普.高速铁路建设发展概况研究[J].郑铁科技通讯,2006,(04).
[9]武汉大学测绘学院测量平差学科组编著.误差理论与测量平差基础[M].武汉:武汉大学出版社,2003.
[10]中铁二院工程集团有限公司.TB10601-2009,J962-2009高速铁路工程测量规范[S].北京:中国铁道出版社,2010.
[11]孔祥元,梅是义.控制测量学(下册)[M].武汉:武汉大学出版社,2002.2.
[12]金玉山.具有抵偿高程面的任意带坐标系设计原理与方法[J].铁道勘察,2005,(04):25-28.
[13]卢建康,刘华.高速铁路精密工程测量技术体系的建立及特点[J].铁道标准设计,2010(增刊1): 70-73.
[14]王铁生,张冰,赵仲荣.地铁高精度GPS控制网及其起算点兼容性分析[J].华北水利水电学院学报,2002,25(02):8-10.
[15]刘烈昭,等.GPS网平差精度、可靠性与置信度的评定.GPS测地研究与应用文集[C],北京:测绘出版社,1992.
[16]张英翔等.京沪高速铁路CPⅡ控制网复测技术研究[J].地理空间信息,2008,06(03) :112-114.
[17]尚云东.基于统计参数的隧道贯通测量误差预计分析[J].桥隧机械&施工技术,2008,(04):72-74.
[18]张正禄,张松林,伍志刚等.20~50km超长隧道(洞)横向贯通误差允许值研究[J],测绘学报,2004,33(01):83-88.
[19]张正禄等.工程测量学[M].武汉:武汉大学出版社,2005.10.
[20]中国有色金属工业协会主编.工程测量规范(GB50026-2007)[S].北京:中国计划出版社,2008.
[21]武汉测绘科技大学《测量学》编写组编.测量学(第三版)[M].北京:测绘出版社,2003.
[22]李征航,黄劲松编著.GPS测量与数据处理[M].武汉:武汉大学出版社,2005.
[23]潘正风,杨正尧,程效军,成枢,王腾军编著.数字化测图原理与方法[M].武汉:武汉大学出版社,2004.
[24]徐绍铨.GPS测量原理及运用[M].武汉:武汉大学出版社,2003.
[25]李明峰,冯宝红,刘三枝.GPS定位技术及其应用[M].北京:国防工业出版社,2007.
[26]张永彬,高刚毅.GPS三维联合平差[J].矿山测量,2003,(1):15-17.
[27]张瑞,姚宜斌,梁静,王品,刘强.GPS网平差程序设计[J].全球定位系统,2009,(2):54-58.
[28]彭先进.测量控制网的优化设计[M].武汉:武汉测绘科技大学出版社,1991.
[29]李辉.高精度GPS控制网的优化设计研究[D].北京:北京交通大学,2009.
[30]匡翠林.高精度GPS水准算法研究及其应用[D].长沙:中南大学,2004.
[31]佩尔策主编,张正禄编译.现代工程测量控制网的理论和应用[M].北京:测绘出版.1989.
[33]中华人民共和国国家质量监督检验检疫总局.全球定位系统(GPS)测量规范(GB/T18314-2009)[S].北京:中国标准出版社,2009.
[34]地球科学与测量工程学院.实用GPS数据处理教程[M].武汉:武汉测绘科技大学.
[35]顾利亚,岑敏仪.施工控制网的优化设计[J].西南交通大学学报,1997,32(2):160-164.
[36]中国人民共和国铁道部.TB10054-2010铁路工程卫星定位测量规范[S].北京:中国铁道出版社,2010.
[37]中国人民共和国铁道部.新建铁路工程测量规范(TB10101)[S].北京:中国铁道出版社,2009.
[38]中国铁建二十三局集团有限公司.新建兰渝铁路引入重庆枢纽站前代建Ⅰ标工程简介.[EB/OL].中国铁建二十三局集团有限公司网站.[2008-04-22].
[39]王铁生,等.城市高精度GPS控制网的复测与网形优化[J].测绘学院学报,2004,21(2):102-104.
[40]傅晓明,沈云中.工程GPS网平差起算点坐标的误差分析[J].测绘通报,2002,(9):54-56.
[41]邢继红.GPS网起始数据的误差分析[J].地理空间信息,2008,4(4):13-15.
[42]赵长胜.GPS控制网设计与数据处理[M].北京:科学教育出版社,2001.
[43]梅熙.GPS技术建立客运专线平面控制网若干问题[J].科学技术通讯,2005,(128):14-19.
[44]张方仁,于正林.平差基准点稳定性分析与判别[J].测绘通报,1994(5):35-41.
[45]董世清,李志成. GPS测量控制网起算点的兼容性分析[J].四川测绘,2003,26(4):169-172.
[46]肖华.GPS网起算点坐标的兼容性问题分析及其处理[J].湖南水利水电,2003,(5):15-16.
[47]傅晓明.工程GPS网平差起算点坐标的误差分析[J].工程勘察,2004,(2):54-56.
[48]张兵,赵瑞.GPS控制网起算点兼容性分析方法研究与实践[J].测绘科学,2010,35(5):65-67.
[49]宋铁群.GPS起算点坐标的兼容性分析[J].测绘与空间地理信息,2009,32(3):63-66.
[50]章淑君,靳永滨.检核GPS测量控制网起算点精度的方法及其探讨[J].四川测绘,2005,28(2):60-63.
[51]王岩,岳建平,周保兴,葛世超.工程控制网点位稳定性分析方法的研究[J].测绘通报,2004,(8):12-14.
[52]苏京平.控制网的稳定性分析[J].城市勘测,2000,(4):14-16.
[53]马海志.工程施工平面控制网稳定性分析探讨[J].城市勘测,2007,(2):60-63.
[54]吴大江.浅谈施工测量首级控制网的稳定性检验[J].矿山测量,2009,(4):13-14.
[55]卢献健,任超.GPS数据处理科研软件与商业软件对比分析[J].全球定位系统,2007,(5):29-32.
[56] Jay Gao.Integration of GPS with Remote Sensing and GIS: Reality and Prospect[J].Photogram metric Engineering & Remote Sensing 68_2002.447-453.
[57] Yang Y.Robust Estimation of Geodetic Datum Transformation. Journal of Geodesy,1999,73:268-274
[58] Sung-Pil Hong,Kyung Min Kim,Kyungsik Lee and Bum Hwan Park.A pragmatic algorithmfor the train-set routing:The case of Korea high-speed railway[J] . Omega,2009(3):637-645.
[59] Lu baixiang,Cen Minyi.A problem in the application of the Error Ellipsoid[J].SurverReview,1993,239-243.
[60] MILE Vivo,GRENDIG lothar.Germany.Rail Track Data Base Of German Rail-The Future orAutomated Maintenance [R],INGEO 2004 and FIG Region Central And Eastern EuropeanConference On Engineering Surveying Bratislava, Washiongton,D.C,2002.