Automation of Air Traffic Management Using Fuzzy Logic Algorithm to Integrate Unmanned Aerial Systems into the National Airspace

Unmaned Aircraft Systems (UAS) have been increasing in popularity in personal, commercial, and military applications. The increase of the use of UAS poses a significant risk to general air travel, and will burden an already overburdened Air Traffic Control (ATC) network if the Air Traffic Management (ATM) system does not undergo a revolutionary change. Already there have been many near misses reported in the news with personal hobbyist UAS flying in controlled airspace near airports almost colliding with manned aircraft. The expected increase in the use of UAS over the upcoming years will exacerbate this problem, leading to a catastrophic incident involving substantial damage to property or loss of life. ATC professionals are already overwhelmed with the air traffic that exists today with only manned aircraft. With UAS expected to perform many tasks in the near future, the number of UAS will greatly outnumber the manned aircraft and overwhelm the ATC network in short order to the point where the current system will be rendered extremely dangerous, if not useless. This paper seeks to explore the possibility of using the artificial intelligence concept of fuzzy logic to automate the ATC system in order to handle the increased traffic due to UAS safely and efficiently. Automation would involve an algorithm to perform arbitration between aircraft based on signal input to ATC ground stations from aircraft, as well as signal output from the ATC ground stations to the aircraft. Fuzzy logic would be used to assign weights to the many different variables involved in ATM to find the best solution, which keeps aircraft on schedule while avoiding other aircraft, whether they are manned or unmanned. The fuzzy logic approach would find the weighted values for the available variables by running a simulation of air traffic patterns assigning different weights per simulation run, over many different runs of the simulation, until the best values are found that keep aircraft on schedule and maintain the required separation of aircraft

[1]  Robert F. Mills,et al.  Security analysis of the ADS-B implementation in the next generation air transportation system , 2011, Int. J. Crit. Infrastructure Prot..

[2]  E. Valovage,et al.  Enhanced ADS-B Research , 2006, 2006 ieee/aiaa 25TH Digital Avionics Systems Conference.

[3]  Reece A. Clothier,et al.  Pilotless aircraft: the horseless carriage of the twenty‐first century? , 2008 .

[4]  Cheng-Hsuan Yang,et al.  An Optimized Unmanned Aerial System for Bridge Inspection , 2015 .

[5]  D. Maroney,et al.  Evaluating sensor technology for UAS collision avoidance , 2009, IEEE Aerospace and Electronic Systems Magazine.

[6]  João Batista Camargo,et al.  Guidelines for the Integration of Autonomous UAS into the Global ATM , 2014, J. Intell. Robotic Syst..

[7]  George J. Klir,et al.  Fuzzy sets and fuzzy logic - theory and applications , 1995 .

[8]  Alvaro Vargas-Clara,et al.  Dynamics and Control of a Stop Rotor Unmanned Aerial Vehicle , 2012 .

[9]  Dennis A. Vincenzi,et al.  Privacy, Restriction, and Regulation Involving Federal, State and Local Legislation: More Hurdles for Unmanned Aerial Systems (UAS) Integration? , 2014 .

[10]  H.A. Rediess Infrastructure concept for automated aircraft and air traffic operations , 2004, The 23rd Digital Avionics Systems Conference (IEEE Cat. No.04CH37576).

[11]  Frederick G. Harmon,et al.  UAS Collision Avoidance Algorithm Based on an Aggregate Collision Cone Approach , 2011 .

[12]  Naima Kaabouch,et al.  Flight Testing of an ADS-B-based Miniature 4D Sense and Avoid System for Small UAS , 2011 .

[13]  João Batista Camargo,et al.  An approach to assess the safety of ADS-B based unmanned aerial systems , 2014 .

[14]  O. V. Degtyarev,et al.  Methods and features of mathematical simulation of air traffic management systems , 2012 .

[15]  Chris A. Wargo,et al.  Unmanned Aircraft Systems (UAS) research and future analysis , 2014, 2014 IEEE Aerospace Conference.

[16]  Parimal H. Kopardekar Unmanned Aerial System (UAS) Traffic Management (UTM): Enabling Low-Altitude Airspace and UAS Operations , 2014 .

[17]  John Yen,et al.  Extracting fuzzy rules for system modeling using a hybrid of genetic algorithms and Kalman filter , 1999, Fuzzy Sets Syst..

[18]  Nathan M. Paczan Integrating UAS into NextGen automation systems , 2012 .

[19]  Raffaello D'Andrea,et al.  Guest Editorial Can Drones Deliver? , 2014, IEEE Trans Autom. Sci. Eng..

[20]  Austin L. Smith UAS Collision Avoidance Algorithm That Minimizes the Impact on Route Surveillance , 2012 .

[21]  Terry Autry,et al.  Supercomputers, super efficiency , 2016 .

[22]  Wen-Hua Chen,et al.  Artificial Situation Awareness for Increased Autonomy of Unmanned Aerial Systems in the Terminal Area , 2013, J. Intell. Robotic Syst..

[23]  Mary L. Cummings,et al.  Deconstructing Complexity in Air Traffic Control , 2005 .