地球电离层研究毕业论文外文翻译.docx

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1、第一篇 中英文互译外文原文Recently, according to the requirements of some important GPS research subjects in the fields of Geodesy, Geophysics, Space-Physics and navigation in China, we studied systematically how to correcting the effects of the ionosphere on GPS, with high-precision and accuracy. As the parts o

2、f the main contributions, the research projects focus mainly on how to improve GPS surveying by reducing ionospheric delay for dual/single frequency kinematic/static users: high accuracy correction of ionospheric delay for single/dual frequency GPS users on the earth and in space, China WAAS ionosph

3、eric modeling and the theory and method of monitoring of ionosphere using GPS. The main contents of this Ph.D paper consist of two parts:Fisrt part-the outline of research background and the systematic introduction and summarization of the previous research results of this work. Second part-the main

4、 contribution and research results of this paper are focused on as follows:(1) How to use the measurements of a dual frequency GPS receiver to determine the ionospheric delay correction model for single frequency GPS of a local range;(2) How to separate the instrumental biases with the ionospheric d

5、elays in GPS observation;(3) How to establish a large range grid ionosphere model and use the GPS data of Chinese crust movement observation network to investigate the change law of ionospheric TEC of China area; (4) How to improve the effectiveness of correcting ionospheric delays for WAASs users u

6、nder adverse conditions.(5) How to establish the basic theory and the corresponding framework of monitoring the stochastic ionospheric disturbance using GPS(6) How to improve the modelling ability of ionospheric delay according to its diurnal, seasonal, annual variations based on GPS;(7) How to meet

7、 the demand of correcting the ionospheric delay of high-precision orbit determination for low-earth satellite using a single frequency GPS receiver1Extracting (local) ionospheric information from GPS data with high-precision The factors are systematically described and analyzed which limit the preci

8、sion of using GPS data to extract ionospheric delays. The precision of determining ionospheric delay using GPS is improved based on the further research of the related models and methods. The main achievements of this work include the some aspects as follows:(1) Based on a simple model with constant

9、 number of parameters, which consists of a set of trigonometric series functions, a generalized ionospheric model is constructed whose parameters can be adjusted. Due to the property of selecting the different parameters according to the change law of ionospheric delay, the new model has better avai

10、lability in the field of the related theoretic research and engineering application. The experimental results show that the model can indicate the characteristic of ionospheric actions, improves further the modeling ability of local ionosphere and may be used to correct efficiently ionospheric delay

11、 of the single frequency GPS uses serviced by DGPS. (2) Different calculating schemes are designed which are used to analyze in detail the characteristics of the effect from instrumental bias (IB) in GPS observations on determining ionospheric delays. IB is different from noise in GPS observations.

12、The experimental results show that the effect of IB is much larger than that of the noise on estimating ionospheic delay, and IB can cause ionospheric delay measurements to include systematic errors of the order of several meters. Therefore, one must significantly take notice of IB and remove its ne

13、gative effect, and should not casually consider IB as part of noise whenever GPS data are used to fit ionospheric model or to directly calculate ionospheric delay.(3) Stability of IB is studied with a refined method for separating it from ionospheric delay using multi-day GPS phase-smoothed code dat

14、a. The experimental results show that, by using averaging of noise with phase-smoothed code observation，the effect of noise on separating IB from ION can be efficiently reduced, and satellite bias plus receiver bias are relatively stable and may be used to predict the IBs of the next session or even

15、 that of the next several days.(4) A new algorithm about static real time determination of ionospheric delay is presented on the basis of the predicted values of IB and the technique of real time averaging of noise and weighted-adjustment of dual P-code and carrier phase measurements. The preliminar

16、y results show that the new method, which is by post-processing phase-smoothed code data to calculate the IB and then with them to predict and to correct the IB of data needed to remove its effects in real time in the next observation periods, has relatively better accuracy and effectiveness in esti

17、mating ionospheric delay. It is very obvious that the scheme can relatively decrease the number of unknown parameters, can efficiently reduce the main negative effect from instrumental bias, and can be easily used to directly and precisely determine ionospheric delay with dual-frequency GPS data. He

18、nce, the method may be considered as an available scheme to determine ionospheric delays for WAAS and many other large range GPS application systems.2 A method of constructing large range (regional and global) high-precision grid ionospheric modelthe Different Area for Different Stations (DADS) and

19、its application in ChinaBased on the systematic and further research of the principle and methods of establishing grid ionospheric model (GIM), a new method of establishing a GIM - Different Areas for Different Stations (DADS) is investigated which is advantageous for considering the local character

20、s of ionosphere, avoiding the effects of the geometrical construction of GPS reference network on estimating the external precision of the GIM, and improving the precision of calculating model parameters. The above results are used to make a preliminary estimation of the latent precision that can be

21、 obtained by establishing a large range high precision grid ionospheric model based on the Chinese crust movement observation network, and to investigate the possibility that the GIM provides high-precision ionospheric correction, and to identify the relevant problems which need to be solved for the

22、 planned GPS Wide area Augmentation System (WAAS) of China.3 A method of efficiently correcting ionospheric delays for WAASs users under typical adverse conditions the Absolute Plus Relative Scheme (APR-I)The commonly used WAASs DIDC received by single frequency GPS receivers can usually provide the

23、 effective correction of the ionospheric delays for the users under normal conditions and in the fields of calm ionosphere. However, the ionospheric delays cannot be efficiently accounted for during those periods when the WAAS cannot broadcast the DIDC values to users, or when the receivers cannot r

24、eceive the DIDCs for whatever reason. The ionospheric delay corrections will be less well known in cases when the variations of the ionospheric delays may be very large due to ionospheric disturbances. The above difficulties cannot be avoided to be encountered and must be solved for the WAAS.For thi

25、s, a new ionospheric delay correction scheme for single frequency GPS datathe APR-I scheme is proposed which can efficiently address the above problems. 1) The theoretic basis of constructing the APR-I Scheme The WAAS can provide high-precision absolute ionospheric delay estimates when it operates p

26、roperly. Meanwhile, a single frequency GPS receiver serviced by the WAAS can efficiently determine the relative variation of the ionospheric delays between two arbitrary epochs even under adverse conditions if without considering observation noises. 2) On the APR-I SchemeBased on a robust recurrence

27、 procedure and an efficient combination approach between absolute ionospheric delays and ionospheric relative changes, the APR-I scheme is present which is an new method of correcting ionospheric delay for single frequency GPS user. The formula of estimating the precision of the APR-I scheme is give

28、n. An implementation approach of the APR-I scheme is analyzed as well.The experimental results discussed above show that the APR-I scheme not only retains the characteristic of high accuracy of the DIDC from the WAAS under normal ionospheric and reception conditions, but also has relatively better c

29、orrection effectiveness under different abnormal conditions. The implementation of this method need not change the present basic ionospheric delay correction algorithm of the WAAS. In addition, the APR-I method does not impose new demands on receiver hardware, and only requires a few improvements to

30、 receiver software. Hence it can be easily used by single frequency GPS users.4 A new theory of monitoring the random signal Auto-Covariance Estimation of Variable Samples(ACEVS) and its application in using GPS to monitor the random ionosphere A new approach for monitoring ionospheric delays is fou

31、nd and developed, based on the characteristic of time series observation of GPS, an investigation of the statistical properties of the estimated auto-covariance of the random ionospheric delay when changing the number of samples in the time series, the development of the related basic theory and the

32、 corresponding framework scheme, and the further research of using GPS and the above research results to study ionosphere.The concrete work is as follows:1) Studied the Auto-Covariance Estimation of Variable Samples (ACEVS) From a general mathematical aspect, the basic model of ACEVS is established.

33、 The theoretic and approximate solution formulas for ACEVS are derived based on the improvement of theory of white noise and then a test raw of the state of a random signal is established based on ACEVS;2) Verified and modeled the possibility of using ACEVS to test the change of state of stochastic

34、delaysThe possibility of using ACEVS to monitor ionosphere is verified in terms of theory. Also it is found that the statistical property of ACEVS is sensitive to the change of the random ionospheric delay, on the basis of modeling the characteristics of ACEVS using a dual frequency GPS receiver. Th

35、e application conditions of using ACEVS to monitor the variation of TEC extracted by GPS data are preliminarily discussed and analyzed as well.3) Established a preliminary framework scheme of using GPS to monitor the disturbance of random ionospheric delay.According to ACVES and all other results of

36、 the above and the characteristic of the time series observations of GPS, a preliminary framework scheme for monitoring the disturbance of random ionospheric delay using GPS is established. Although this method is proposed for real time monitoring, it can be easily applied to post-processing of GPS

37、data. The framework scheme based on ACVES can be used to design many practical schemes for monitoring ionosphere variation using a (static or kinematic) dual frequency GPS receiver. 5 A new method of modelling ionospheric delay using GPS data Ionospheric Eclipse Factor Method (IEFM) The Ionospheric

38、Eclipse Factor (IEF) and its influence factor (IFF) of Ionospheric Pierce Point (IPP) is present and a simple method of calculating the IEF is also given. By combining the IEF and IFF with the local time t of IPP, a new method of modelling ionospheric delay using GPS data Ionospheric Eclipse Factor

39、Method (IEFM) is developed. The IEF and its IFF can efficiently combine the different ionospheric models for different seasons according to the diurnal, seasonal and annual variations of ionosphere. The preliminary experimental results show that the correction accuracy of the ionospheric delay model

40、ed by IEFM is very close to that of using the ionosphere- free observation to correct directly the ionospheric delay, that is, the precision of using IEFM to model ionospheric delay for single GPS users seems to has a breakthrough improvement and be similar to that of using the corresponding dual fr

41、equency GPS data to correct directly the ionospheric delays. The IEFM also suits to model the ionospheric delays for a kinematic basedsingle GPS receiver embeded in low-earth satellite with high rapid due to its good ability in distinguishing the daytime and nighttime of the earth ionosphere for an

42、IPP.6 A new strategy of correcting ionospheric delay for high-precision orbit determination for low-earth satellite using a single frequency GPS receiver -the APR-II scheme, i.e., Space-based APR scheme Analyzed the shortcomings of using the previous methods to divide with high accuracy the earth io

43、nosphere into different layers. Used GPS data to model global ionospheric TEC. Established a high precision grid ionospheric model. Discussed the possibility of finding out some local areas whose ionospheric construction and action have relatively better obvious law with respect to the other areas o

44、n a global scale. Designed a scheme for combining GPS-grounded data with GPS-spaced data to divide efficiently the ionosphere into some layers. Given the corresponding formula of estimating the precision of the scheme. The preliminary precision estimation and the experimental results show the possib

45、ility and property of the above idea of dividing ionosphere into different layers according to application requirement and its implementation scheme. Based on the above research, the APR-II scheme is presented which is a new and combined method of correcting the ionospheric delays of high-precision

46、orbit determination for low-earth satellite using a single frequency GPS receiver. The preliminary experimental results based on two different sets of GPS-grounded data show that the APR-II scheme can provide the effective ionospheric delay correction for high-precision orbit determination for low-e

47、arth satellite.中文翻译根据当前大地测量、地球物理、空间物理和导航等领域的科学研究和工程应用中的若干重要GPS科研项目的需要，近年来，我们系统研究了电离层延迟的高精度模拟和改正方法。本文报告的内容，是我们研究工作的部分贡献，主要涉及基于GPS的电离层监测及延迟的高精度改正的理论与方法的研究：如何通过修正静、动态单、双频用户的电离层延迟影响，进一步改善GPS 测量的精度和可靠性；增强型GPS广域差分系统的电离层模拟及利用GPS监测电离层的理论和方法等方面。本文主要包括两方面的内容：一、研究背景的一般性描述及相关基础研究的系统总结和介绍,主要涉及：地球电离层研究意义, 地球电离层探测

48、技术与相关理论研究的内容,现代大地测量中电离层问题的由来、严重性与新课题, 地球电离层的基本特性及其对电波传播的影响，GPS定位的基本理论与方法，电离层延迟对GPS测量的影响，GPS的电离层延迟改正的基本方法，基于GPS的电离层研究的基本原理与方法等。进而论述了解决GPS的电离层延迟影响的重要性和切入点。二、具体研究工作的系统报告，主要集中在以下几方面: 研究如何利用单台双频GPS接收机的观测信息确定电离层延迟改正模型，为小范围的单频用户服务；研究如何实时分离GPS观测中的仪器偏差与电离层延迟；研究如何建立较大区域的电离层格网模型，进而初步设想利用中国地壳运动观测网络深入研究我国领域的电离层的

49、电子浓度变化规律；研究单频用户在不利条件下，如何更好地利用电离层延迟改正信息；研究利用GPS监测随机电离层扰动的基本理论和框架方案；研究如何综合顾及电离层的周日、季节和年变化，进一步提高利用GPS模拟电离层延迟的能力；研究如何实现星载单频GPS低轨卫星的精密测轨中的电离层延迟改正要求。1. (局部)电离层延迟的高精度提取系统论述和分析了影响利用GPS观测精确提取电离层延迟信息的各类因素。通过对有关模型和方法问题的深入研究，进一步提高了利用GPS提取电离层延迟信息的精度。主要包括：（1）将参数固定的三角级数函数电离层模型，扩展为更适用于理论研究和实际应用的参数可调型广义形式，实现了根据电离层延迟时空变化特征，选择不同的特征参数模拟电离层延迟的影响。试算结果表明，它能较好地反映电离层活动特性，提高了局部电离层延迟模拟能力，适用于DGPS系统修正其服务区域内的单频GPS用户的电离层延迟。（2）设计了几种不同的计算方案，用于分析仪器