ADS-B within a multi-aircraft simulation for distributed air-ground traffic management

Automatic dependent surveillance broadcast (ADS-B) is an enabling technology for NASA's distributed air-ground traffic management (DAG-TM) concept. DAG-TM has the goal of significantly increasing capacity within the National Airspace System, while maintaining or improving safety. Under DAG-TM,...

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Hauptverfasser: Barhydt, R., Palmer, M.T., Chung, W.W., Loveness, G.W.
Format: Tagungsbericht
Sprache:eng
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Zusammenfassung:Automatic dependent surveillance broadcast (ADS-B) is an enabling technology for NASA's distributed air-ground traffic management (DAG-TM) concept. DAG-TM has the goal of significantly increasing capacity within the National Airspace System, while maintaining or improving safety. Under DAG-TM, aircraft exchange state and intent information over ADS-B with other aircraft and ground stations. This information supports various surveillance functions including conflict detection and resolution, scheduling, and conformance monitoring. To conduct more rigorous concept feasibility studies, NASA Langley Research Center's PC-based air traffic operations simulation models a 1090 MHz ADS-B communication structure, based on industry standards for message content, range, and reception probability. The current ADS-B model reflects a mature operating environment and message interference effects are limited to Mode S transponder replies and ADS-B squitters. This model was recently evaluated in a joint DAG-TM air/ground coordination experiment with NASA Ames Research Center. Message probability of reception vs. range was lower at higher traffic levels. The highest message collision probability occurred near the meter fix serving as the confluence for two arrival streams. Even the highest traffic level encountered in the experiment was significantly less than the industry standard "LA Basin 2020" scenario. Future studies will account for Mode A and C message interference (a major effect in several industry studies) and will include Mode A and C aircraft in the simulation, thereby increasing the total traffic level. These changes will support ongoing enhancements to separation assurance functions that focus on accommodating longer ADS-B information update intervals.
DOI:10.1109/DASC.2004.1391286