Regional Ionospheric TEC Gradients Estimation Using a Single GNSS Receiver

This paper presents an algorithm to estimate regional ionospheric total electron content (TEC) and TEC gradients. In this study, the ionospheric vertical TEC (VTEC) at an ionosphere piercing point (IPP) in a local area is represented by contributions from

PDF / 417,168 Bytes
11 Pages / 439.37 x 666.142 pts Page_size
84 Downloads / 198 Views

DOWNLOAD

REPORT

Regional Ionospheric TEC Gradients Estimation Using a Single GNSS Receiver Cheng Wang, Jiexian Wang and Yu Morton

Abstract This paper presents an algorithm to estimate regional ionospheric total electron content (TEC) and TEC gradients. In this study, the ionospheric vertical TEC (VTEC) at an ionosphere piercing point (IPP) in a local area is represented by contributions from the VTEC at other IPPs in the local area and spatial gradients of TEC along both latitudinal and longitudinal directions. By differencing the TEC between each pair of observable IPPs, linear equations of local TEC gradients can be established if only first order and second order TEC spatial derivatives in the TEC representation are retained. The TEC gradients obtained from these linear equations are then combined with VTEC of observable IPPs to generate regional TEC maps. The algorithm is tested using a single GNSS receiver located on the campus of Tongji University over a 24-h period. The TEC values obtained from the algorithm are compared with that from the polynomial-based regional ionospheric TEC model constructed using data from 13 stations in Yangtze River Delta area and also with estimations generated from the IGS global ionosphere maps (GIM). The results show that the average difference between TEC values generated from a single receiver using the TEC gradient-based algorithm and from 13 stations using the polynomial-based regional TEC model is around 1 TECU, and the standard deviation of the differences is about 1.5 TECU. Also, the average difference between TEC values calculated from the proposed TEC algorithm and from GIM is about 0.5 TECU, and the standard deviation of the differences is nearly 1.6 TECU. The results demonstrate that the proposed TEC gradient-based method has the potential to produce accurate regional TEC maps for precise positioning and for ionospheric monitoring using measurements from only a single receiver. The algorithm can be

C. Wang (&) J. Wang College of Surveying and Geo-Informatics, Tongji University, Shanghai 200092, China e-mail: [email protected] C. Wang Y. Morton Department of Electrical and Computer Engineering, Miami University, Oxford, USA e-mail: [email protected]

J. Sun et al. (eds.), China Satellite Navigation Conference (CSNC) 2014 Proceedings: Volume II, Lecture Notes in Electrical Engineering 304, DOI: 10.1007/978-3-642-54743-0_30, Springer-Verlag Berlin Heidelberg 2014

363

364

C. Wang et al.

easily modified to incorporate other multi-GNSS measurements such as GLONASS, Beidou System and Galileo to further improve precision. Keywords Ionosphere

Total electron content Gradient Model

30.1 Introduction Ionosphere TEC is an important parameter for both satellite navigation and scientific studies of the ionosphere and space weather. TEC determines the first order ionosphere induced range error, which is a dominant error source in GNSS generated navigation solutions. Existing models such as the Klobuchar model [1], the International Reference Ionosphere (IRI) model [2], the Ben

Data Loading...

Regional Ionospheric TEC Gradients Estimation Using a Single GNSS Receiver

Recommend Documents

A multi-frequency and multi-GNSS method for the retrieval of the ionospheric TEC and intraday variability of receiver DC

A local Multivariate Polynomial Regression approach for ionospheric delay estimation of single-frequency NavIC receiver

Modelling and forecasting of ionospheric TEC irregularities over a low latitude GNSS station

Impact of Ionospheric Correction on Single-Frequency GNSS Positioning

Design and Realization of a GNSS Receiver Test Equipment

Investigation of ionospheric TEC anomalies caused by space weather conditions

Low latitude ionospheric response to March 2015 geomagnetic storm using multi-instrument TEC observations over India

Feasibility Analysis of Baseband Architecture for Multi-constellation GNSS Receiver

GNSS scale determination using calibrated receiver and Galileo satellite antenna patterns

Fine-Scale Surface Normal Estimation Using a Single NIR Image

Test Results of HiSGR: A Novel GNSS/INS Ultra Tight Coupled Spaceborne Receiver

Using GNSS radio occultation data to derive critical frequencies of the ionospheric sporadic E layer in real time