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Effect of an in-flight vertical accelerometer calibration on landing accuracy after baro-inertial system failure

    Man Nguyen   Affiliation
    ; Vyacheslav Kostiukov   Affiliation
    ; Cap Tran   Affiliation

Abstract

An issue of improving flight safety during landing with an inertial navigation system (INS) and a failed barometric altimeter is considered. In this paper, we propose a specific algorithm for in-flight calibration of the vertical channel of INS. Accordingly, the baro-inertial integration algorithm using a discrete five-state Kalman filter will be performed during a particular flight maneuver before landing. As a result, it is possible to estimate not only the bias of vertical accelerometer but also its scale factor, which is too small to be defined by a usual in-flight calibration algorithm. After applying the proposed algorithm, the flight management system can provide a safe landing with a standalone INS. The algorithm’s performance is assessed by simulating complete mathematical models of aircraft motion and control systems. The impact of calibrated bias and scale factor of vertical accelerometer on the altitude estimation error is provided through an analysis.

Keyword : accelerometer, barometric altimeter, calibration maneuver, baro-inertial failure, Kalman filter, automatic landing

How to Cite
Nguyen, M., Kostiukov, V., & Tran, C. (2020). Effect of an in-flight vertical accelerometer calibration on landing accuracy after baro-inertial system failure . Aviation, 24(2), 80-89. https://doi.org/10.3846/aviation.2020.12424
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Jul 8, 2020
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References

AAIU. (2016). Synoptic report. Serious incident Boeing 757-224, N41140 80 NM Southwest of Dublin, Ireland, 20 October 2013. Air Accident Investigation Unit, Ireland.

Ausman, J. S. (1991). A Kalman filter mechanization for the Baro-inertial vertical channel. Proceedings of the 47th Annual Meeting of the Institute of Navigation, 1, 153–159.

Babich, O. A. (1991). Obrabotka informatsii v navigatsionnykh kompleksakh. Mashinostroenie (in Russian).

BEA. (2012). Final report on the accident on 1st June 2009 to the Airbus A330-203 registered F-GZCP operated by Air France flight AF 447 Rio de Janeiro – Paris. French Civil Aviation Safety Investigation Authority.

Bevermeier, M., Walter, O., Peschke, S., & Haeb-Umbach, R. (2010). Barometric height estimation combined with map-matching in a loosely-coupled Kalman-filter. 7th workshop on positioning, Navigation and Communication (pp. 128–134). Dresden, Germany. https://doi.org/10.1109/WPNC.2010.5650745

Brian, L. S., & Frank L. L. (2003). Aircraft control and simulation (2nd ed.). John Wiley & Sons.

Farrell, J., & Barth, M. (1998). The global positioning system and inertial navigation. McGraw-Hill.

FAA. (2016). Pilot’s handbook of aeronautical knowledge. United States Department of Transportation, Federal Aviation Administration.

Gray, R. A., & Maybeck, P. S. (1995). An integrated GPS/INS/BARO and radar altimeter system for aircraft precision approach landings. Proceedings of IEEE 1995 National Aerospace and Electronics Conference (pp. 161–168). Dayton, OH, USA.

Groves, P. D. (2013). Principles of GNSS, inertial, and multi-sensor integrated navigation systems (2nd ed.). Artech House.

Groves, P. D. (2015). Navigation using inertial sensors [Tutorial]. IEEE Aerospace & Electronics Systems Magazine, 30(2), 42–69. https://doi.org/10.1109/MAES.2014.130191

Jafar, K., Hossein, N., & Sadra, R. (2018). Design and Implementation of GA Filter Algorithm for Baro-inertial altitude error compensation. 18th IIE International Conference on Latest Trends in Engineering and Technology (pp. 78–80). Istanbul, Turkey.

Jeb, B. (2019). Pitot-static system failures. Aviation Safety. https://www.aviationsafetymagazine.com/features/pitot-static-system-failures/

Kim, J. H., & Sukkarieh, S. (2003). A baro-altimeter augmented INS/GPS navigation system for an uninhabited aerial vehicle. Paper presented at the 6th International Symposium on satellite navigation technology including mobile positioning & location services. Melbourne, Australia.

KNKT. (2018). Aircraft accident investigation report. Komite Nasional Keselamatan Transportasi, Republic of Indonesia.

Lawford, J. A., & Nippress, K.R. (1983). Calibration of air-data system and flow direction sensors. AGARD-AG-300. Volume 1.

Luiz, R. M. (2013). The dramatic effect of Pitot-Static system blockages and failures. http://www.luizmonteiro.com/DocumentsPDF/The_Dramatic_Effects_of_Pitot_Static_Blockages.pdf

Mohinder, S. G., Lawrence, R. W., & Angus, P. A. (2007). Global positioning systems, inertial navigation, and integration (2nd ed.). Wiley.

O’Donnel, C. F. (1964). Inertial navigation, analysis and design. McGraw-Hill.

Siouris, G. M. (1993). Aerospace avionics system: a modern synthesis. Academic Press, Inc.

Schmidt, G. T. (2010). INS/GPS technology trends. NATO RTO Lecture Series, RTO-EN-SET. Massachusetts, USA.

Sobolev, V. I. (1994). Syntes kalmanovskikh fil’trov: Ucheb. posobie dlia prakticheskykh zaniatiĭ. Izd-vo MAI (in Russian).

Sokolovi, V. S., Diki, G., & Stan, R. (2014). Adaptive error damping in the vertical channel of the INS/GPS/Baro-altimeter integrated navigation system. Scientific Technical Review, 4(3), 141–150.

Zaporozhets, A. V., & Kostiukov, V. M (1992). Proektirovanie system otobrazheniia informatsii: Ucheb. posobie dlia priborostroitel’nykh spetsial’nosteĭ vuzov. Mashinostroenie (in Russian).