• DocumentCode
    2566873
  • Title

    Integration of weather avoidance and traffic separation

  • Author

    Consiglio, Maria C. ; Chamberlain, James P. ; Wilson, Sara R.

  • Author_Institution
    NASA Langley Res. Center, Hampton, VA, USA
  • fYear
    2011
  • fDate
    16-20 Oct. 2011
  • Abstract
    This paper describes a dynamic convective weather avoidance concept that compensates for weather motion uncertainties; the integration of this weather avoidance concept into a prototype 4-D trajectory-based Airborne Separation Assurance System (ASAS) application; and test results from a batch (non-piloted) simulation of the integrated application with high traffic densities and a dynamic convective weather model. The weather model can simulate a number of pseudo-random hazardous weather patterns, such as slow- or fast-moving cells and opening or closing weather gaps, and also allows for modeling of onboard weather radar limitations in range and azimuth. The weather avoidance concept employs nested "core" and "avoid" polygons around convective weather cells, and the simulations assess the effectiveness of various avoid polygon sizes in the presence of different weather patterns, using traffic scenarios representing approximately two times the current traffic density in en-route airspace. Results from the simulation experiment show that the weather avoidance concept is effective over a wide range of weather patterns and cell speeds. Avoid polygons that are only 2-3 miles larger than their core polygons are sufficient to account for weather uncertainties in almost all cases, and traffic separation performance does not appear to degrade with the addition of weather polygon avoidance. Additional "lessons learned" from the batch simulation study are discussed in the paper, along with insights for improving the weather avoidance concept.
  • Keywords
    aerospace simulation; air safety; air traffic control; meteorological radar; motion estimation; ASAS application; batch simulation; dynamic convective weather avoidance; fast-moving cells; high traffic density; nonpiloted simulation; onboard weather radar limitations; prototype 4D trajectory-based airborne separation assurance system; pseudorandom hazardous weather patterns; slow-moving cells; traffic density; traffic separation; weather motion uncertainty compensation; Asynchronous transfer mode; Atmospheric modeling; Generators; Meteorological radar; Meteorology; Trajectory;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Digital Avionics Systems Conference (DASC), 2011 IEEE/AIAA 30th
  • Conference_Location
    Seattle, WA
  • ISSN
    2155-7195
  • Print_ISBN
    978-1-61284-797-9
  • Type

    conf

  • DOI
    10.1109/DASC.2011.6096050
  • Filename
    6096050