Differential Code Bias Estimation and Accuracy Analysis Based on Dual-Frequency GPS Observations
-
摘要: 接收机仪器偏差中的码偏差是影响电离层中电子总含量求解精度的重要因素,若忽略仪器的码偏差对电离层的影响,将会给电子含量的求解带来9~30 TECU偏差,因此对接收机码偏差的精确求解至关重要.本文基于6个欧洲站6天的GPS双频观测数据,在最小二乘的基础下,联合4阶球谐函数模型估算接收机中的差分码偏差,将求解的结果与CODE分析中心电离层产品所给出的结果进行对比分析,并对接收机差分码偏差估算的结果进行精度的评定,结果表明:文中估算方法所得的结果与CODE分析中心中电离层产品给出的结果基本一致,且估算的精度较高,因此,该方法对差分码偏差的提取具有一定的有效性.
-
关键词:
- 电离层 /
- 差分码偏差 /
- 电子总含量(TEC) /
- 最小二乘
Abstract: The code bias in the receiver instrument deviation is an important factor affecting the accuracy of the total electron content in the ionosphere. If the effect of the code bias of the instrument on the ionosphere is ignored, the 9~30 TECU deviation can be brought to the solution of the electron content, so the exact solution of the machine code deviation is crucial. This paper uses 6-day GPS dual-frequency observation data and joints spherical harmonic model to estimate the differential code bias in the receiver on the basis of least squares. The results are compared and analyzed with the solution given by the CODE analysis center ionosphere product,at the same time,this paper also evaluats the accuracy of receiver differential code bias estimation. The results show that the results obtained by the estimation method in the paper are basically consistent with the results given by the ionosphere products in the CODE analysis center, and the estimated accuracy is quite high, therefore, this method has certain validity for the extraction of differential code bias.-
Key words:
- Ionosphere /
- differential code bias /
- total electron content (TEC) /
- least squares
-
[1] 王宁波.GNSS差分码偏差处理方法及全球广播电离层模型研究[J].测绘学报,2017,46(8):1069-1069. [2] 宋小勇,杨志强,焦文海,等.GPS接收机码间偏差(DCB)的确定[J].大地测量与地球动力学,2009, 29(1):127-131. [3] 周东旭,袁运斌,李子申,等.GPS接收机仪器偏差的长期变化特性分析[J].大地测量与地球动力学,2011,31(5):114-118. [4] 吕志伟,郝金明,曾志林,等.利用GPS观测资料确定接收机差分码偏差的算法[J].全球定位系统,2010,35(2):14-17. [5] 张健,欧吉坤.GPS仪器偏差的求解方法及其对电子总量的影响[J].测绘工程,2003,12(3):24-25. [6] 袁运斌.基于GPS的电离层监测及延迟改正理论与方法的研究[D].武汉:中国科学院测量与地球物理研究所,2002. [7] 王军.GNSS区域电离层TEC监测及应用[D].北京:中国测绘科学研究院,2008. [8] 安家春,王泽民,屈小川,等.基于单站的硬件延迟求解方法[J].大地测量与地球动力学,2010,30(2):86-90. [9] 吕志伟,郝金明,曾志林,等.利用GPS观测资料确定接收机差分码偏差的算法[J].全球定位系统,2010,35(2):14-17. [10] ]张宝成,袁运斌,欧吉坤.GPS接收机仪器偏差的短期时变特征提取与建模[J].地球物理学报,2016,59(1):101-115. [11] 李昕,郭际明,周吕,等.一种精确估计区域北斗接收机硬件延迟的方法[J].测绘学报,2016, 45(8):929-934. [12] 岳鑫鑫,宋迎春,崔先强,等.基于球谐函数建模的单站接收机硬件延迟算法[J].测绘工程,2016,25(5):16-19. [13] 曾添,隋立芬,肖国锐,等.BDS卫星端DCB不同表达对单点定位精度的影响[J].测绘科学技术学报,2016,33(4):362-367. [14] 张小红,唐龙.COSMIC低轨卫星GPS接收机差分码偏差估计[J].地球物理学报,2014,57(2):377-383. [15] 刘明. 量子力学中球谐函数递推公式新探[J]. 湖北:第二师范学院学报, 2003, 20(5):12-15. -
点击查看大图
计量
- 文章访问数: 461
- HTML全文浏览量: 61
- PDF下载量: 116
- 被引次数: 0
下载:
