Abstract
Current practices and major trends in unmanned aircraft systems (UAS) for maritime operations are presented along with projections of future UAS maritime applications. First, various aspects of UAS program management, including organization, operator responsibilities, program operation, and overall program costs, are reviewed. Next, maritime aircraft missions and required capabilities are outlined, and current practices for both manned and unmanned aircraft are described. Technological trends relating to UAS are also discussed, focusing on developments relevant to maritime UAS operations. This information provides a background for assessing potential future maritime UAS operations. Trends including miniaturization of sensors and computer systems, high energy density of power sources, and increased subsystem standardization and modularity will have important effects in the future. However, another significant trend is towards increased system autonomy via new command and control frameworks that facilitate integration of UAS into higher level maritime observing systems through new concepts of operation for networked systems and new business models.
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References
J. Bellingham, K. Rajan, Robotics in remote and hostile environments. Science 318, 1098–1102 (2007)
A. Bowden, K. Hurlburt, E. Aloyo, C. Marts, A. Lee, The economic cost of maritime piracy. One Earth Future Working Paper, 2010
Civil Aviation Authority, CAP 722 unmanned aircraft system operations in UK Airspace – Guidance, 2012
Civil Aviation Safety Authority. CASR Part 101. n.d. http://www.casa.gov.au/scripts/nc.dll?WCMS:STANDARD::pc=PC_91039. Accessed 20 Dec 2012
B.T. Clough, Metrics, schmetrics! how the heck do you determine a UAV's, in Performance Metrics for Intelligent Systems (PerMIS) Conference, Gaithersburg, Maryland, USA, 2002
R. Costanza et al., The value of the world's ecosystem services and natural capital. Nature 387, 253–260 (1997)
K. Dalamagkidis, K.P. Valavanis, L.A. Piegl, On Integrating Unmanned Aircraft Systems into the National Airspace System: Issues, Challenges, Operational Restrictions, Certification, and Recommendations (Springer, New York, 2009)
F. del Pozo, A. Dymock, L. Feldt, P. Hebrard, F. Sanfelice di Monteforte, Maritime surveillance in support of CSDP – the wise pen team final report to eda steering board. European Defence Agency, WISE PEN TAM, 2010
DOD, MIL-HDBK-516B Department of Defense Handbook Airworthiness Certification Criteria, Department of Defense, 2005
DOD, FY2009–2034 Unmanned Systems Integrated Roadmap, Office of the Secretary of Defense US DOD, 2009
DOD.a, Unmanned Aircraft Systems Roadmap: 2005–2030, Office of the Secretary of Defense USA DOD, 2005
DOD.a, MIL-HDBK-881 Department of Defense Handbook Workbreakdown Structure, Department of Defense, 2011
DOD.b, The Unmanned Systems Integrated Roadmap FY2011-2036, Office of the Secretary of Defense USA DOD, 2011
DOD.c, DoD UAS Airspace Integration Plan, DOD, 2011
C.E. Nehme, M.L. Cummings, J.W. Crandall, A UAV Mission Hierarchy, Human and Automation Laboratory, Massachusetts Institute of Technology, Cambridge, 2006
EASA, Policy for Unmanned Aerial Vehicle (UAV) Certification, A-NPA, No. 16/2005, Rulemaking Directorate, European Aviation Safety Agency, Köln, 2005
R. Fearing, Micromechanical Flying Insect (2007), http://robotics.eecs.berkeley.edu/~ronf/mfi.html/. Accessed 2012
Flight Insight, ISR Special Report 2009, Flight Insight, 2009
FMOD/DGA, Unmanned Air Vehicle System Airworthiness Requirement (USAR). Version 3.0, FMOD/DGA, 2005
J. Gertler, U.S. Unmanned Aerial Systems, Congressional Research Service, 2012
J. Griner, UAS integration in the NAS project: Project overview. Integrated Communications, Navigation and Surveilance Conference (ICNS), p. 1–22, Herndon, Virginia, USA, 2011
G. Hagan, Glossary Defense Acquisition Acronyms and Terms (Virginia 22060–5565: Defense Acquisition University Press, Fort Belvoir, 2009)
ICAO, ICAO exploratory meeting on UAVs. Working Paper 2, the Sixteenth Meeting of the APANPIRG ATM/AIS/SAR Sub-Group (ATM/AIS/SAR/SG/16). ICAO, 2006
ICAO, Progress report on unmanned aerial vehicle (UAV) work. ICAO AFI Planning and implementation regional group sixteenth meeting (APIRG/16), 2007
ICAO, Unmanned Aircraft Systems (UAS), International Civil Aviation Organization, 2011
IOC/UNESCO, A Blueprint for Ocean and Coastal Sustainability, Paris, 2011
JAUS. Joint Architecture for Unmanned Systems (JAUS). n.d. http://en.wikipedia.org/wiki/JAUS. Accessed 2012
J. Kraska, The law of unmanned naval systems in war and peace. J. Ocean Technol. 5(3), 43–68 2010
P. McGillivary, J. Borges de Sousa, R. Martins, Connecting the dots: networking maritime fleets of autonomous vehicles for science and surveillance, in Marine Technology Reporter, 2012, pp. 33–38
P. McGillivary, Design considerations for launch and recovery of autonomous systems from ships, including Coast Guard icebreakers, in Launch & Recovery, Arlington, 2010
NASA.a. Earth Observations and the Role of UAVs: A Capabilities Assessment, Civil UAV Assessment Team NASA, 2006
NASA.b. Earth Observations and the Role of UAVs: Volume 2, Civil UAV Assessment Team NASA, 2006
NATO, STANAG 4586 Second Edition, Standard Interfaces of UAV Control System (UCS) for NATO UAV Interoperability, NATO Standardization, NATO, 2007
NATO STANAG, NATO STANAG 4671 Unmanned Aerial Vehicle Systems Air Worthiness Requirements, NATO, 2007
NATO STANAG, STANAG 4703 LIGHT UAS AIRWORTHINESS REQUIREMENTS, NATO, 2012
Naval Air Systems Command Public Affairs, First X-47B UCAS Catapult Launch Makes Naval Aviation History. 29 Nov 2012 http://www.navy.mil/submit/display.asp?story_id=70864. Accessed 12 Dec 2012
QineticQ, 2009, http://www.qinetiq.com/what/products/Documents/Zephyr-UAV.pdf. Accessed 2012
S. Robertson, Future Maritime Surveillance. House of Commons, Defence Committee, UK Parliament, 2 Apr 2012
D. Seagle, NATO Joint Capability Group on UAVs, in 2011–2012 UAS Yearbook – UAS: The Global Perspective, 9th edn. 46/216, 2011
Subcommittee on Unmanned Systems, Federal Unmanned Systems: Status, Issues, and Recommendations, 2011
U.S. Navy, Scan Eagle UAV Conducts First Flight On LPD-Class Ship. http://www.defencetalk.com/scan-eagle-uav-conducts-first-flight-on-lpd-class-ship-45890/. Accessed 12 Dec 2012
UAV TASK-FORCE, UAV TASK-FORCE Final Report a Concept for European Regulations for Civil Unmanned Air Vehicles. The Joint JAA/EUROCONTROL initiative on UAVs, 2004
UN, World Drug Report 2011, United Nations Office on Drugs and Crime, United Nations, New York 2011
R. Valerdi, J. Merril, P. Maloney, Cost metrics for unmanned aerial vehicles, in 16th Ligther-Than-Air Systems Technology Conference and Robotic Balloon Systems Conference, American Institute of Aeronautics and Astronautics, 2005
Visiongain, The Airborne ISR Market 2011–2021, Visiongain, 2011
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de Sousa, J.B. et al. (2015). Unmanned Aircraft Systems for Maritime Operations. In: Valavanis, K., Vachtsevanos, G. (eds) Handbook of Unmanned Aerial Vehicles. Springer, Dordrecht. https://doi.org/10.1007/978-90-481-9707-1_75
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DOI: https://doi.org/10.1007/978-90-481-9707-1_75
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