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Evaluation of Integrated Demand Management looking into Strategic & Tactical Flow Management  (2017)
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The motivation behind Integrated Demand Management (IDM) research explores possible improvements to United States National Airspace System (NAS) performance that could be realized through procedural integration of strategic traffic flow management capabilities, such as the Collaborative Trajectory Options Program (CTOP), and tactical capabilities, such as Time Based Flow Management (TBFM). An initial IDM concept for clear weather operations was developed and evaluated for potential benefits, including efficiency, delay reduction, predictability and throughput, and to identify any major issues that might represent a showstopper for a fielded application. Newark Liberty International Airport (EWR) arrival operations provided a use case for concept development. EWR uses miles-in-trail (MIT) metering to regulate demand into TBFM during high volume operations, and short-haul flights are often penalized with excessive, last-minute ground delays when the overhead stream is saturated. IDM addresses this problem by replacing MIT conditioning with CTOP to better manage the demand delivery to the TBFM entry points. A "quasi-real time" high-fidelity simulation that would normally involve participants was conducted using heuristic-based procedures that mimicked operators' behaviors instead. Five total conditions were compared: two baseline conditions with MIT delivery to TBFM entry points using two different TBFM settings; and three IDM conditions: one with airborne speed control using an Required Time of Arrival (RTA) capability, a second without RTA, and a third with no wind forecast errors. Results suggest that the IDM concept can deliver traffic more efficiently by shifting the delays from airborne to ground for both RTA and non-RTA conditions, while maintaining a target throughput rate. The results also suggest that with good predictability of airport capacity, excessive TBFM ground delay can be minimized by applying more strategic CTOP delay, increasing predictability for the airline operators. Overall findings indicate that the implementation of an IDM concept under clear weather conditions can improve NAS system performance. Future IDM research aims to expand the concept to address demand/capacity imbalance due severe weather.
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airborne, airline, Collaborative, CTOP, delay, Flow, ground, management, operators, Option, Program, TBFM, throughput, Time-Based, Trajectory
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Proceedings of the USA & Europe Air Traffic Management Research and Development (ATM2017), Seattle, Washington
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Adobe PDF Icon  Moehlenbrink_etal_ATM_2017.pdf (Download Acrobat Reader Click to download Adobe Acrabat Reader)
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Last Updated: August 15, 2019