Characterization of High Altitude Turbulence for Air Force Platforms

Characterization of High Altitude Turbulence for Air Force Platforms

The Department of Defense (DoD) has an urgent need to both understand and predict the effects of high-altitude (z 10 km) turbulence (HAT) on systems that operate at or propagate through those attitudes. Examples of systems affected by HAT include surveillance aircraft such as the U-2 and the unmanne...

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Bibliographische Detailangaben
Hauptverfasser: Ruggiero, Frank H, Werne, Joe, Mahalov, Alex, Nichols, Basil, Wroblewski, Donald E
Format: Report
Sprache:eng
Schlagworte:
AIR FORCE PLATFORMS
AIRBORNE LASERS
AIRCRAFT
AUTOMATIC PILOTS
COMMUNICATION AND RADIO SYSTEMS
COMMUNICATION SATELLITES
COMPONENT REPORTS
DEPARTMENT OF DEFENSE
DIRECTED ENERGY WEAPONS
DWELL TIME
Fluid Mechanics
GRAVITY WAVES
HIGH ALTITUDE
HIGH FREQUENCY
LASER APPLICATIONS
LASERS
Lasers and Masers
MECHANICAL PROPERTIES
Mechanics
OPTICAL PROPERTIES
OPTICAL TURBULENCE
SURVEILLANCE
SURVEILLANCE AIRCRAFT
SYMPOSIA
TEMPERATURE GRADIENTS
TSAT(TRANSFORMATIONAL COMMUNICATION SATELLITES)
TURBULENCE
UNMANNED GLOBAL HAWK
Unmanned Spacecraft
VELOCITY GRADIENTS
WEAPON SYSTEMS
WIND VELOCITY
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Beschreibung
Zusammenfassung:The Department of Defense (DoD) has an urgent need to both understand and predict the effects of high-altitude (z 10 km) turbulence (HAT) on systems that operate at or propagate through those attitudes. Examples of systems affected by HAT include surveillance aircraft such as the U-2 and the unmanned Global Hawk, developing weapons systems such as the Airborne Laser (ABL), and developing communication systems such as the Transformational Communication Satellites (TSAT). The surveillance aircraft are primarily affected by mechanical turbulence, which is the fluctuation of wind velocity and is usually caused by velocity gradients, flow over terrain, or convection. High frequency gravity waves can affect the aircraft the same way and are caused by the same forcing mechanisms as actual mechanical turbulence and are considered as part of the HAT forecast problem. The effects of mechanical turbulence include upsetting the autopilot, degrading the quality of the surveillance observations, and in the worse case jeopardizing the aircraft itself. Laser-based systems such as the ABL and TSAT are affected by optical turbulence, which is the fluctuation of the index of refraction and is caused by mechanical turbulence in the presence of temperature gradients. For directed-energy weapon systems such as the ABL, optical turbulence causes the laser to wander, spread, and scintillate which will degrade its power, result in increased dwell time to destroy a target, and decrease the effective range. For laser-based communication systems such as TSAT, optical turbulence can result in significant data dropouts. The original document contains color images. All DTIC reproductions will be in black and white. Presented at the DoD High Performance Computer Modernization Program (HPCMP) Users Group Conference (USG)(2007): A Bridge to Future Defense held in Pittsburgh, PA on 18-21 June 2007. Published in Proceedings of the DoD High Performance Computer Modernization Program (HPCMP) Users Group Conference (USG), p28-32, June 2007. Publisher: IEEE Computer Society, Conference Publishing Services (CPS). ISBN 0-7695-3088-5 and ISBN 978-0-7695-3088-8. Sponsored in part by the Air Force Office of Scientific Research. This article is from ADA488707 Proceedings of the HPCMP Users Group Conference 2007. High Performance Computing Modernization Program: A Bridge to Future Defense held 18-21 June 2007 in Pittsburgh, Pennsylvania