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Professional and educational FlightGear users: Difference between revisions
Professional and educational FlightGear users (view source)
Revision as of 21:08, 17 January 2014
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* FlightGear was used to give a 3D visualiziation of a simulation by '''Robert Heffley Engineering'''. The simulation was used to examine the use of a Task-Pilot-Vehicle (TPV) model as a tool for flight simulator math model development.<ref>{{cite web |url=http://pdf.aiaa.org/getfile.cfm?urlX=6%3A7I%276D%26X%5BRW%2CS%20CIP4S%5EQ%3AO%224ZT%27%5FP%20%20%0A&urla=%26%2AR%28%27%230%2AC%0A&urlb=%21%2A%20%20%20%0A&urlc=%21%2A0%20%20%0A&urld=%28%2A%22P%26%22%406CTA%20%20%0A&urle=%28%2A%22H%23%230%22DU1X%20%0A |title=Use of a Task-Pilot-Vehicle (TPV) Model as a Tool for Flight Simulator Math Model Development |date=2-5 August 2010 |author=Heffley R.K. |publisher=American Institute of Aeronautics and Astronautics |acessdate=16 August 2012 }}</ref> | * FlightGear was used to give a 3D visualiziation of a simulation by '''Robert Heffley Engineering'''. The simulation was used to examine the use of a Task-Pilot-Vehicle (TPV) model as a tool for flight simulator math model development.<ref>{{cite web |url=http://pdf.aiaa.org/getfile.cfm?urlX=6%3A7I%276D%26X%5BRW%2CS%20CIP4S%5EQ%3AO%224ZT%27%5FP%20%20%0A&urla=%26%2AR%28%27%230%2AC%0A&urlb=%21%2A%20%20%20%0A&urlc=%21%2A0%20%20%0A&urld=%28%2A%22P%26%22%406CTA%20%20%0A&urle=%28%2A%22H%23%230%22DU1X%20%0A |title=Use of a Task-Pilot-Vehicle (TPV) Model as a Tool for Flight Simulator Math Model Development |date=2-5 August 2010 |author=Heffley R.K. |publisher=American Institute of Aeronautics and Astronautics |acessdate=16 August 2012 }}</ref> | ||
* Dutch roadable autogyro manufacturer '''PAL-V Europe NV''' uses FlightGear to provide the visuals and terrain data for their simulator. The simulator is currently used to prepare the test pilot and evaluate design options, but may be used to train customers in the future.<ref>{{cite web |url=http://pal-v.com/licenses/the-pal-v-simulator/ |title=The PAL-V simulator}}</ref> | * Dutch roadable autogyro manufacturer '''PAL-V Europe NV''' uses FlightGear to provide the visuals and terrain data for their simulator. The simulator is currently used to prepare the test pilot and evaluate design options, but may be used to train customers in the future.<ref>{{cite web |url=http://pal-v.com/licenses/the-pal-v-simulator/ |title=The PAL-V simulator}}</ref> | ||
* The '''Max Planck Institute for Biological Cybernetics''' of Germany uses FlightGear in several simulation environments: | |||
** HeliLab<ref>{{cite web |url=http://www.cyberneum.de/de/forschungseinrichtungen/helilab.html |title=HeliLab (Tiled Display)}}</ref> | |||
** MPI CyberMotion Simulator <ref>{{cite web |url=http://www.cyberneum.de/de/labore-forschung/cmslab.html |title=Der MPI-CyberMotion-Simulator}}</ref> | |||
* The West Virginia based '''Institute for Scientific Research''' used FlightGear to perform simulated flight testing of the avionics and control system of a small autonomous UAV.<ref>{{cite web |url=ftp://ftp.uni-duisburg.de/pub/FlightGear/Docs/AIAA-2005-7083.pdf |title=Simulated Flight Testing of an Autonomous Unmanned Aerial Vehicle Using FlightGear |date=September 2005 |author=Eric F. Sorton, Sonny Hammaker }}</ref> | |||
=== ARINC === | === ARINC === | ||
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=== Endless Runway Project === | === Endless Runway Project === | ||
The '''Endless Runway Project''' is a consortium of aerospace instutes from France, Germany, the Netherlands, Poland and Spain. "The fundamental principle of The Endless Runway is that the aircraft take-off and land on a large circular structure. This will allow for the unique characteristic that the runway can be used in any wind direction, thus making the runway independent of the direction of the wind and therefore also the airport capacity independent of the wind direction."<ref>{{Cite web |url=http://endlessrunway-project.eu/ | The '''Endless Runway Project''' is a consortium of aerospace instutes from France, Germany, the Netherlands, Poland and Spain. "The fundamental principle of The Endless Runway is that the aircraft take-off and land on a large circular structure. This will allow for the unique characteristic that the runway can be used in any wind direction, thus making the runway independent of the direction of the wind and therefore also the airport capacity independent of the wind direction."<ref>{{Cite web |url=http://endlessrunway-project.eu/downloads/d3.2-aircraft-aspects.pdf |title=Aircraft aspects of the Endless Runway |date=30 September 2013 |accessdate=16 January 2014}}</ref> | ||
FlightGear and JSBSim were extensively used to simulate the landing and take-off performance of large aircraft on a circular runway. By using FlightGear, the consortium was able to select the radius, width and curvature of the runway. | FlightGear and JSBSim were extensively used to simulate the landing and take-off performance of large aircraft on a circular runway. By using FlightGear, the consortium was able to select the radius, width and curvature of the runway. | ||
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* The Department of Aircraft and Aeroengine from the Chinese '''Air Force Engineering University''' conducted a study on a new airworthiness compliance verification method based on pilot-aircraft-environment complex system simulation.<ref>{{Cite web |url=http://ac.els-cdn.com/S1000936111604342/1-s2.0-S1000936111604342-main.pdf?_tid=d3518780-834d-11e2-ba1b-00000aab0f26&acdnat=1362238285_cf85b59c1b58215e2a1559b6f42867aa |title=Airworthiness Compliance Verification Method Based on Simulation of Complex System |date=12 January 2012 |author=XU Haojun, LIU Dongliang, XUE Yuan, ZHOU Li, MIN Guilong |publisher=Chinese Journal of Aeronautics}}</ref> | * The Department of Aircraft and Aeroengine from the Chinese '''Air Force Engineering University''' conducted a study on a new airworthiness compliance verification method based on pilot-aircraft-environment complex system simulation.<ref>{{Cite web |url=http://ac.els-cdn.com/S1000936111604342/1-s2.0-S1000936111604342-main.pdf?_tid=d3518780-834d-11e2-ba1b-00000aab0f26&acdnat=1362238285_cf85b59c1b58215e2a1559b6f42867aa |title=Airworthiness Compliance Verification Method Based on Simulation of Complex System |date=12 January 2012 |author=XU Haojun, LIU Dongliang, XUE Yuan, ZHOU Li, MIN Guilong |publisher=Chinese Journal of Aeronautics}}</ref> | ||
* The Malaysian '''Universiti Teknologi Malaysia''' uses FlightGear for several projects.<ref>http://www.youtube.com/user/isfarazi</ref> | * The Malaysian '''Universiti Teknologi Malaysia''' uses FlightGear for several projects.<ref>http://www.youtube.com/user/isfarazi</ref> | ||
* The '''Nanjing University of Aeronautics and Astronautics''' in China made a 3D surface movement simulation system for [http://en.wikipedia.org/wiki/Advanced_Surface_Movement_Guidance_and_Control_System A-SMGCS] with FlightGear. The system displays ADS-B data in FlightGear through the multiplayer system and accurately predicts the aircraft's and/or vehicle's attitude (this is absent in ADS-B).<ref>{{cite web |url=http://pub.chinasciencejournal.com/article/getArticle.action?articleId=31183 |title=3D simulation of A-SMGCS surface movement based on FlightGear |date=16 May 2012 }}</ref> | |||
=== Europe === | === Europe === | ||
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* The '''Czech Technical University in Prague''' is working on a full motion simulator to do research on situation awareness. They're using FlightGear for the visuals. A video of the simulator can be seen [http://www.youtube.com/watch?v=d8SQa9_el8k&feature=autoshare at YouTube]. More info at http://measure.feld.cvut.cz/en/cast | * The '''Czech Technical University in Prague''' is working on a full motion simulator to do research on situation awareness. They're using FlightGear for the visuals. A video of the simulator can be seen [http://www.youtube.com/watch?v=d8SQa9_el8k&feature=autoshare at YouTube]. More info at http://measure.feld.cvut.cz/en/cast | ||
* '''French Aerospace Lab (ONERA)''' and '''University of Toulouse''', France (2004). A thesis student Frédéric Dehais has used FlightGear and developed a cognitive counter-measures experimental environment (p.119 and following) to show the pilot/ATC scheme could be formalized and enhanced to avoid cognitive perturbation. Use of Atlas and Onera Messenger. Over 22 real-life pilots have been testing this environment.<ref>{{fr}} {{cite web |url=http://oatao.univ-toulouse.fr/2137/1/Dehais_2137.pdf |title=Modélisation des conflits dans l’activité de pilotage |first=Frédéric |last=Dehais |publisher=University of Toulouse |date=21 June 2004}}</ref> | * '''French Aerospace Lab (ONERA)''' and '''University of Toulouse''', France (2004). A thesis student Frédéric Dehais has used FlightGear and developed a cognitive counter-measures experimental environment (p.119 and following) to show the pilot/ATC scheme could be formalized and enhanced to avoid cognitive perturbation. Use of Atlas and Onera Messenger. Over 22 real-life pilots have been testing this environment.<ref>{{fr}} {{cite web |url=http://oatao.univ-toulouse.fr/2137/1/Dehais_2137.pdf |title=Modélisation des conflits dans l’activité de pilotage |first=Frédéric |last=Dehais |publisher=University of Toulouse |date=21 June 2004}}</ref> | ||
* '''Pázmány Péter Catholic University''' and the '''Hungarian Academy of Sciences''' developed a collision avoidance system for UAVs using visual detection. The system was simulated with FlightGear serving the visuals.<ref>{{cite web |url=http://www.analogic.sztaki.hu/publications/UAV_Collision_avoidance.pdf |title=Collision avoidance for UAV using visual detection }}</ref> | |||
=== North-America === | === North-America === | ||
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* The '''University of Michigan''' used FlightGear to validate PID autopilot for unmanned aerial vehicles.<ref>{{Cite web |url=http://www-personal.umich.edu/~duncanlm/Miller_Duncan_AIAA_RegionIII_2011_Autolab.pdf | title=Autonomous Vehicle Laboratory for Sense and Avoid Research and Hardware-in-the-Loop Simulations |publisher=American Institute of Aeronautics and Astronautics |author=Duncan Miller |date=2011 |format=pdf}}</ref> | * The '''University of Michigan''' used FlightGear to validate PID autopilot for unmanned aerial vehicles.<ref>{{Cite web |url=http://www-personal.umich.edu/~duncanlm/Miller_Duncan_AIAA_RegionIII_2011_Autolab.pdf | title=Autonomous Vehicle Laboratory for Sense and Avoid Research and Hardware-in-the-Loop Simulations |publisher=American Institute of Aeronautics and Astronautics |author=Duncan Miller |date=2011 |format=pdf}}</ref> | ||
* FlightGear was used by the '''University of Toronto Institute for Aerospace Studies''' to simulate [[UTIAS Ornithopter No.1|their first ornithopter]] (engine powered).<ref>{{Cite web |url=http://www.ornithopter.net/MediaGallery/flightgear_e.html |title=Flying the Ornithopter in FlightGear Flight Simulator |author=Project Ornithopter |date=2006 |format=html }}</ref> In 2010 the team made aviation history when their second ornithopter became the first human-powered ornithopter to make a sustained flight.<ref>{{Cite web |url=http://media.utoronto.ca/media-releases/new-media-technology/human-powered-ornithopter-becomes-first-ever-to-achieve-sustained-flight/ |title=Human-powered ornithopter becomes first ever to achieve sustained flight |publisher=University of Toronto |date=22 September 2010 }}</ref> | * FlightGear was used by the '''University of Toronto Institute for Aerospace Studies''' to simulate [[UTIAS Ornithopter No.1|their first ornithopter]] (engine powered).<ref>{{Cite web |url=http://www.ornithopter.net/MediaGallery/flightgear_e.html |title=Flying the Ornithopter in FlightGear Flight Simulator |author=Project Ornithopter |date=2006 |format=html }}</ref> In 2010 the team made aviation history when their second ornithopter became the first human-powered ornithopter to make a sustained flight.<ref>{{Cite web |url=http://media.utoronto.ca/media-releases/new-media-technology/human-powered-ornithopter-becomes-first-ever-to-achieve-sustained-flight/ |title=Human-powered ornithopter becomes first ever to achieve sustained flight |publisher=University of Toronto |date=22 September 2010 }}</ref> | ||
* '''Purdue University''', Indiana visualized scenarios involving cyber attacks in FlightGear to demonstrate the vulnerabilities of current UAV autopilot systems.<ref>{{cite web |url=http://www.syprisresearch.com/Images/secure-control-systems/AIAA-Infotech_Threats-and-Vulnerabilities-Analysis.pdf |title=Cyber Attack Vulnerabilities Analysis for Unmanned Aerial Vehicles}}</ref> | |||
=== South-America === | === South-America === | ||