Optimising the Integration of Terrain Referenced Navigation with INS and GPS

Paul D Groves; Robin J Handley; Andrew R Runnalls

doi:10.1017/S0373463305003462

Abstract

The benefits of integrated INS/GPS systems are well known. However, the knowledge required to jam GPS is becoming public and the hardware to achieve this is basic. When GPS data are unavailable and a low grade INS is used, navigation accuracy quickly degrades to an unacceptable level. The addition of one or more terrain referenced navigation (TRN) systems to an integrated INS/GPS navigation system enables the INS to be calibrated during GPS outages, increasing the robustness of the overall navigation solution. TRN techniques are compared and integration architectures are reviewed. For the initial studies of INS/GPS/TRN integration, radar altimeter based terrain contour navigation (TCN) with a batch processing algorithm is used in conjunction with a centralised integration filter. Four different approaches for using these TCN fixes to calibrate the INS are compared. These are a best fix method, a weighted fix method using a probabilistic data association filter (PDAF) and single and multi-hypothesis versions of the Iterative Gaussian Mixture Approximation of the Posterior (IGMAP) method. Simulation results are presented showing that the single hypothesis IGMAP technique offers the best balance between accuracy, robustness and processing efficiency.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Soler, Tomás 2006. GPS/GNSS current bibliography. GPS Solutions, Vol. 10, Issue. 3, p. 229.

Manzar, M.A. Cheema, T.A. Jalil, A. and Qureshi, I.M. 2008. New image matching technique based on hyper-vectorisation of grey level sliced binary images. IET Image Processing, Vol. 2, Issue. 6, p. 337.

Manzar, A. Cheema, T. A. and Qureshi, I. M. 2009. New scale invariant template matching technique using hyper space image representation. Pattern Analysis and Applications, Vol. 12, Issue. 3, p. 201.

MANZAR, Muhammad Anwaar CHEEMA, Tanweer Ahmad JALIL, Abdul and QURESHI, Ijaz Mansoor 2009. Visual Aerial Navigation through Adaptive Prediction and Hyper-Space Image Matching. IEICE Transactions on Information and Systems, Vol. E92-D, Issue. 2, p. 283.

Meduna, Deborah K. Rock, Stephen M. and McEwen, Robert S. 2010. Closed-loop terrain relative navigation for AUVs with non-inertial grade navigation sensors. p. 1.

Liu, Ying and Wu, Meiping 2010. Intelligent geomagnetic matching method. p. 494.

Shen, Xuesong Lu, Ming and Chen, Wu 2011. Tunnel-Boring Machine Positioning during Microtunneling Operations through Integrating Automated Data Collection with Real-Time Computing. Journal of Construction Engineering and Management, Vol. 137, Issue. 1, p. 72.

Li, Ming-ming Lu, Hong-qian Yin, Hang and Huang, Xian-lin 2011. Novel algorithm for geomagnetic navigation. Journal of Central South University, Vol. 18, Issue. 3, p. 791.

Kumari, Pravesh Carter, William E. and Shrestha, Ramesh L. 2011. Adjustment of systematic errors in ALS data through surface matching. Advances in Space Research, Vol. 47, Issue. 10, p. 1851.

Zhang, Yanshun Li, Chunyu Liu, Shanshan Jiang, Ming and Guo, Lei 2014. Locating method of geomagnetic/inertial integrated navigation system by forecasting the geomagnetic matching initial value. p. 235.

Li, Ye Ma, Teng Chen, Pengyun Jiang, Yanqing Wang, Rupeng and Zhang, Qiang 2017. Autonomous underwater vehicle optimal path planning method for seabed terrain matching navigation. Ocean Engineering, Vol. 133, Issue. , p. 107.

Li, Ye Ma, Teng Wang, Rupeng Chen, Pengyun and Zhang, Qiang 2017. Terrain Correlation Correction Method for AUV Seabed Terrain Mapping. Journal of Navigation, Vol. 70, Issue. 5, p. 1062.

Shen, Kai Selezneva, Maria S. Neusypin, Konstantin A. and Proletarsky, Andrey V. 2017. Novel Variable Structure Measurement System with Intelligent Components for Flight Vehicles. Metrology and Measurement Systems, Vol. 24, Issue. 2, p. 347.

Tsibizova, T. Yu. Lukianiva, N.V. and Shashurin, V.D. 2019. Simulation of Experimental Data Based Inertial Navigation Systems Errors Estimation Algorithms. p. 1.

Neusypin, K. A. and Selezneva, M. S. 2019. Aircraft measurement complex design using intelligent technologies. Vol. 2171, Issue. , p. 190014.

Proletarsky, A.V. Neusypin, K.A. and Selezneva, M.S. 2019. Method for Improving Accuracy of INS using Scalar Parametric Identification. p. 1.

Proletarsky, A. V. Neusypin, K. A. and Selezneva, M. S. 2019. Signals prefiltering in the aircraft navigation system. Vol. 2171, Issue. , p. 150006.

Selezneva, M.S. Proletarsky, A.V. Neusypin, K.A. and Lifei, Zhang 2019. Modification of the Federated Kalman Filter Using the Observability Degree Criterion of State Variables. p. 1.

Neusypin, K. A. Selezneva, M. S. Huong, Truong Ngoc and Tsibizova, T. Yu. 2019. Correction of autonomous navigation systems using the Kalman filter. Vol. 2171, Issue. , p. 190013.

Lee, Jungshin Sung, Chang-Ky Oh, Juhyun Han, Kyungjun Lee, Sangwoo and Yu, Myeong-Jong 2020. A Pragmatic Approach to the Design of Advanced Precision Terrain-Aided Navigation for UAVs and Its Verification. Remote Sensing, Vol. 12, Issue. 9, p. 1396.

Download full list

Article contents

Optimising the Integration of Terrain Referenced Navigation with INS and GPS

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Optimising the Integration of Terrain Referenced Navigation with INS and GPS

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests