Hostname: page-component-586b7cd67f-vdxz6 Total loading time: 0 Render date: 2024-12-04T09:12:25.761Z Has data issue: false hasContentIssue false

A Study on Geometric and Barometric Altitude Data in Automatic Dependent Surveillance Broadcast (ADS-B) Messages

Published online by Cambridge University Press:  08 May 2019

Busyairah Syd Ali*
Affiliation:
(Aerospace Engineering & Aviation, School of Engineering, RMIT University, Melbourne, Australia)
Nur Asheila Taib
Affiliation:
(Faculty of Computer Science and Information Technology, University of Malaya, Malaysia)
*

Abstract

In Air Traffic Control (ATC), aircraft altitude data is used to keep an aircraft within a specified minimum distance vertically from other aircraft, terrain and obstacles to reduce the risk of collision. Two types of altitude data are downlinked by radar; actual flight level (Mode C) and selected altitude (Mode S). Flight level indicates pressure altitude, also known as barometric altitude used by controllers for aircraft vertical separation. ‘Selected altitude’ presents intent only, and hence cannot be used for separation purposes. The emergence of Global Navigation Satellite Systems (GNSSs) has enabled geometric altitude on board and to the controllers via the Automatic Dependent Surveillance-Broadcast (ADS-B) system. In addition, ADS-B provides quality indicator parameters for both geometric and barometric altitudes. Availability of this information will enhance Air Traffic Management (ATM) safety. For example, incidents due to Altimetry System Error (ASE) may potentially be avoided with this information. This work investigates the use and availability of these parameters and studies the characteristics of geometric and barometric data and other data that complement the use of these altitude data in the ADS-B messages. Findings show that only 8·7% of the altitude deviation is < 245 feet (which is a requirement of the International Civil Aviation Organization (ICAO) to operate in Reduced Vertical Separation Minimum (RVSM) airspace). This work provides an alert/guidance for future ground or airborne applications that may utilise geometric/barometric altitude data from ADS-B, to include safety barriers that can be found or analysed from the ADS-B messages itself to ensure ATM safety.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 2019 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Ali, B. S., Ochieng, W. Y., Schuster, W., Majumdar, A. and Chiew, T. K. (2015). A safety assessment framework for the Automatic Dependent Surveillance Broadcast (ADS-B) system. Safety Science, 78, 91100.10.1016/j.ssci.2015.04.011Google Scholar
Allied Signal Electronic and Avionics System. (1999). Description of Geometric Altitude for the EGPWS. AlliedSignal Inc.Google Scholar
Barhydt, R. and Warren, A. W. (2002). Newly Enacted Intent Changes to ADS-B MASPS:Emphasis on Operations,Compatibility and Integrity. AIAA.Google Scholar
Federal Aviation Administration (FAA). (2009). Pilot's Handbook of Aeronautical Knowledge. Skyhorse Publishing Inc.Google Scholar
Falk, C., Gonzalez, J. and Perez, J. (2010). Using Automatic Dependent Surveillance-Broadcast Data for Monitoring Aircraft Altimetry System Error. Proceedings of the AIAA Guidance, Navigation, and Control Conference.Google Scholar
Fisher, A. B. (2014). The Case for Geometric Altimetry. Honourable Company of Air Pilots.Google Scholar
Field, A. (2013). Discovering statistics using IBM SPSS statistics. SAGE Publications Inc.Google Scholar
Garcia, J. (2014). Analysis of the Geometric Altimetry to Support Aircraft Optimal Trajectories Within The Future 4D Trajectory Management. Air Navigation Research Group, Polytechnic University of Madrid.Google Scholar
Garcia, M. A., Mueller, R., Innis, E. and Veytsman, B. (2012). An Enhanced Altitude Correction Technique For Improvement Of WAM Position Accuracy. 2012 Integrated Communications, Navigation and Surveillance Conference (pp. A4–1). IEEE.10.1109/ICNSurv.2012.6218375Google Scholar
Guo, J. and Jan, S.-S. (2015). Combined use of Doppler observation and DTOA measurement of 1090-MHz ADS-B signals for wide area multilateration. International Technical Meeting (ITM) Conference. Institute of Navigation.Google Scholar
ICAO. (2012). Assessment of ADS-B and Multilateration Surveillance to Support Air Traffic Services. International Civil Aviation Organization. https://store.icao.int/cir-326-assessment-of-ads-b-and-multilateration-surveillance-to-support-air-traffic-services-and-guidelines-for-implementation-english-printed.htmlGoogle Scholar
ICAO. (2011). Operating Procedures and Practices for Regional Monitoring Agencies in Relation to the Use of a 300 m (1 000 ft) Vertical Separation Minimum Between FL 290 and FL 410 Inclusive. International Civil Aviation Organization. www.chinarma.cn/u/cms/www/201405/061414335y8j.pdfGoogle Scholar
Jan, S.-S., Gebre-Egziabher, D., Walter, T. and Enge, P. (2002). Worst-Case Analysis of a 3-Frequency Receiver to Land a General Aviation Airplane. In Proceedings of ION NTM 2002 (pp. 28–30). Institute of Navigation.Google Scholar
Kexi, Z., Jun, Z. and Xuejun, Z. (2010). Research on ADS-B Geometric Height Information for Height Keeping Performance Surveillance. In 2010 3rd International Conference on Advanced Computer Theory and Engineering (ICACTE) (Vol. 2, pp. V2-328). IEEE.10.1109/ICACTE.2010.5579096Google Scholar
Lehtinen, O. (2013). Barometric Assistance Service for Assisted GNSS Receiver. Tampere University of Technology.Google Scholar
Martin, L., Falk, C. and Perez, J. L. (2008). Investigation into the use of Automatic Dependent Surveillance-Broadcast Data for Monitoring Aircraft Altimetry System Error. In AIAA Guidance, Navigation and Control Conference and Exhibit (p. 7146).10.2514/6.2008-7146Google Scholar
Monitoring Agency for Asia Region (MAAR). (2012). Progress on the Use of ADS-B Data to Monitor ASE. International Civil Aviation Organization. https://www.icao.int/APAC/Meetings/2012_FIT_ASIA_RASMAG17/WP11%20MAAR-Progress%20on%20the%20use%20of%20ADS-B%20to%20Monitor%20ASE.pdfGoogle Scholar
Neven, W. H. L., Quilter, T. J., Weedon, R. and Hogendoorn, R. A. (2005). Wide Area Multilateration Report on EATMP TRS 131/04. https://www.eurocontrol.int/sites/default/files/publication/files/surveilllance-report-wide-area-multilateration-200508.pdfGoogle Scholar
Portland State Aerospace Society (2004). A Quick Derivation Relating Altitude to Air Pressure.Google Scholar
RTCA. (2002). Minimum Aviation System Performance Standards for Automatic Dependent Surveillance Broadcast (ADS-B). https://www.researchgate.net/file.PostFileLoader.html?id=5409cac4d5a3f2e81f8b4568&assetKey=AS%3A273593643012096%401442241215893Google Scholar
Silva, S. (2010). A Brief History of RVSM. International Civil Aviation Organization (ICAO). https://www.icao.int/sam/documents/2003/rvsmii/b-bcolamosca-%20rvsm%20background-e.pdfGoogle Scholar
Wiolland, K. (2007). Enhanced Ground Proximity Warning Systems Evolve, Provide Greater Safety. Avionics News. July 2007. http://www.aea.net/avionicsnews/anarchives/egpwsjuly07.pdfGoogle Scholar
Yee, Y. and Yee, E. (2008). A Study Of Barometric Altimeter Errors In High Latitude Regions. Mkey Technologies. https://ams.confex.com/ams/pdfpapers/135583.pdfGoogle Scholar