Operational and technological directions for Unmanned Aircraft Systems development

Polak, G.

doi:10.5604/01.3001.0011.8327

Artykuł - szczegóły

Tytuł artykułu

Operational and technological directions for Unmanned Aircraft Systems development

Autorzy

Polak G.

Wybrane pełne teksty z tego czasopisma

http://securityanddefence.pl

Identyfikatory

DOI

10.5604/01.3001.0011.8327

Warianty tytułu

Języki publikacji

Abstrakty

Unmanned Aircraft Systems are continuously delivering new and enhanced battlefi eld capabilities to the military sphere. While the demand for unmanned systems remains at a relatively high level, it is expected that a number of operational and technological factors will further influence unmanned program development in the nearest future. The purpose of this paper is to articulate a vision for the continued development of unmanned systems technology across military applications. Th is article establishes a technological and an operational vision for the next 25 years and outlines actions and technologies for military experts and industry to pursue to efficiently align with this vision.

Słowa kluczowe

Unmanned Aerial System Unmanned Aerial Vehicle Autonomy

Wydawca

Akademia Sztuki Wojennej

Czasopismo

Security and Defence Quarterly

Rocznik

2018

Tom

Vol. 18, No. 1

Strony

57--74

Opis fizyczny

Biblogr. 28 poz.

Twórcy

autor

Polak G.

grzegorzpolak@wp.pl

OPTIMUM Tymiński i s-ka

Bibliografia

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2. Duck, E., 2002. Future Missions for Unmanned Aerial Vehicles: Exploring Outside the Box, Aerospace Power Journal.
3. Edder, J., 2006. COTS – based systems enable break-through in unmanned aerial vehicles. [online] Available from: http://www.embedded-control-europe.com/pdf/ basjun06p16. pdf: [Accessed 2 Mar 2018].
4. Joint Tactical Radio System Program Offi ce, 2003. Joint Tactical Radio System (JTRS) Program Status. Rosslyn VA. [online] Available from: http://spacecom.grc.nasa.gov/ icnsconf/docs/2003/11_D2/D2-06A-Harrison.pdf [Accessed 2 Mar 2018].
5. Kuptel, A. and Williams A., 2014. Policy Guidance: Autonomy in Defence Systems, Allied Command Transformation. Norfolk.
6. NATO, 1998. STANAG 4545. NATO Secondary Imagery Format.
7. NATO, 1998. STANAG 7074. Digital Geographic Information Exchange Standard (Version 2.1).
8. NATO, 2001. STANAG 7024. Imagery Air Reconnaissance (Digital Tape Storage).
9. NATO, 2004. STANAG 3809. Digital Terrain Elevation Data Geographic Information Exchange Standard.
10. NATO, 2004. STANAG 7023. Air Reconnaissance Imagery Data Architecture.
11. NATO, 2004. STANAG 7085. Interoperable Data Links for Imaging Systems.
12. NATO, 2007. STANAG 4559. NATO Standard Image Library Interface.
13. NATO, 2009. STANAG 4575. NATO Advanced Data Storage Interface.
14. NATO, 2009. STANAG 4609. NATO Digital Motion Imagery Format (Emerging Standard).
15. NATO, 2010. STANAG 4607. NATO GMTI Data Format (Emerging Standard).
16. NATO, 2010. STANAG 5500. NATO Message Test Formatting System Adat P-3.
17. NATO, 2014. STANAG 4670. Recommended Guidance for the Training of Designated Unmanned Aerial Vehicle Operator (DUO).
18. NATO, 2017. STANAG 4671. UAS Air Worthiness Requirements.
19. Moyer, L. R., 2002. Counter Concealed Targets Technologies, DARPA Special Projects Offi ce, DARPATech. [online] Available from: http://www.darpa.mil/DARPATech2000/Presentations/spo_pdf/4MoyerCCTB&W.pdf [Accessed 2 Mar 2018 ].
20. Office of the Secretary of Defense, 2014. Unmanned Systems Integrated Roadmap 2013 – 2038. Washington D. C.
21. The Joint Air Power Competence Centre, 2010. Strategic Concept of Employment for Unmanned Aircraft Systems in NATO. Th e Joint Air Power Competence Centre, Kalkar.
22. Tom, V., 2002. Advances in SAR for keeping targets at risk, in: Night Operations “No Place to Hide” Conference Proceedings, NDIA. Power Point presentation. [online] Available from: http://www.dtic. mil /ndia/2002nightop/tom.pdf [Accessed 2 Mar 2018].
23. UAS, 2006. UAV Systems: Global Perspective, Yearbook 2006/2007. [online] Available from: http://www.uvs-international.org/pages/UAV%20INFO%20-%20Yearbook%202006. html [Accessed 2 Mar 2018].
24. USAF Scientifi c Advisory Board, Ouick Look Study FY 2025, Persistence at “Near Space” Altitudes, Terms of Reference. [online] Available from: http://www.sab.hq.af.mil/ TORs/2005/NS_TOR%20FINAL.pdf [Accessed 2 Mar 2018].
25. U.S. Air Force, 2005. Th e U.S. Air Force Remotely Piloted Aircraft and Unmanned Aerial Vehicles Strategic Vision. Washington D. C.
26. U.S. Air Force, 2009. United States Air Force Unmanned Aircraft Systems Flight Plan 2009- 2047. Washington D. C.
27. US Military Academy, 2016. Remotely Piloted Innovation. Washington D. C.
28. Zajas, S. (ed.), 2009. Studium przyszłości sił powietrznych: kierunki rozwoju do 2025 roku. AON, Warszawa.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-ecea0a8c-0b07-4ae3-a4ef-2d88bb124f3a