Introduction to UAV Systems. Mohammad H. Sadraey. Читать онлайн. Newlib. NEWLIB.NET

Автор: Mohammad H. Sadraey
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Техническая литература
Год издания: 0
isbn: 9781119802624
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Tam McDonald / Wikimedia Commons / OGL v1.0).

      Right: CBP’s Reaper

      (Source: Gerald L. Nino / Wikimedia Commons / Public Domain)

      The first version of Predator (A) had a piston engine, but the upgraded Predator B, or MQ‐9 Reaper, is equipped with a turboprop engine (with a greater power). Predator B is larger, much heavier, with an improved flight performance (e.g., faster cruise speed, longer range, and longer endurance) than the earlier MQ‐1 Predator.

      There are two groups of Payloads: (1) surveillance imagery sensors, which include a synthetic aperture radar, electro‐optic video, and forward‐looking infrared (FLIR) cameras, (2) weapon payloads, which include four anti‐armor missiles AGM‐114 Hellfire), two laser‐guided bombs (GBU‐12), and 500 lb joint direct attack munition. Other payload options include a laser designator and rangefinder, electronic support and countermeasures, a moving target indicator (MTI), and an airborne signals intelligence payload.

      1.6.3 Features

      Reaper UAV has a single turboprop engine on the rear fuselage, a fixed tricycle landing gear, a high aspect ratio wing, with a V‐tail. It has an aileron for roll control and a ruddervator for longitudinal and directional control. The air vehicle is equipped with UHF and VHF radio relay links, a C‐band line‐of‐sight data link, which has a range of 150 nm, and UHF and Ku‐band satellite data links.

No. Parameter Value (unit)
1 Wingspan 65 ft 7 in
2 Length 36 ft 1 in
3 Maximum takeoff weight 10,494 lb
4 External payload weight 3,000 lb
5 Internal payload weight 800 lb
6 Turboprop engine power 900 hp
7 Maximum speed 260 knots
8 Range 1,200 mi
9 Endurance – fully loaded 14 hours
10 Service ceiling 50,000 ft

      The global unmanned aerial vehicle market is witnessing a strong compounded annual growth, even in 2020 where the COVID‐19 emerged as a global pandemic. By January 2019, at least 60 countries were using or developing over 1,300 various UAVs. Top unmanned aerial systems and air vehicles in the market are Northrop Grumman (US), General Atomics (US), AeroVironment (US), Lockheed Martin (US), Elbit Systems (Israel), Israel Aerospace Industries (Israel), BAE Systems (UK), Parrot (France), Microdrones (Germany), SZ DJI Technology (China), Ehang (China), Yuneec International (China), Textron (US), Saab (Sweden), and Raytheon (US). The overall market is expected to reach $21.8 billion by 2027.

      A number of European countries (France, Italy, Greece, Spain, Switzerland, and Sweden) are collectively developing the next generation of UCAVs (most notably the nEUROn) and the MALE unmanned aircraft. It is interesting to note that, as of March 2020, DJI accounts for around 70% of the world’s consumer UAV market. The dominant US UAV manufacturers include Boeing, Lockheed Martin, Aurora Flight Sciences, General Atomics, Northrop Grumman, and AeroVironment.

      All engineering products share some ethical issues, but the ethical concerns in UAVs are new and not yet regulated. Like other engineering products, there are many ways that UAVs are utilized unlawfully or unethically (e.g., drug trafficking). There are basically two ethical issues in employing UAVs: (1) invasion of privacy and (2) killing innocent individuals (lethal use). For instance, between 2004 to 2010, the US drone program in Pakistan [3] has killed several hundred civilians accidentally.

      According to the US government accountability office, there are still four areas of concern for UAVs in using airspace: (1) the inability to recognize and avoid other aircraft, (2) lack of operational standards, (3) vulnerability in command and control of UAV, and (4) lack of Government regulations necessary to safely facilitate the accelerated integration of UAVs into the national airspace system. Moreover, the utilization of unmanned aerial systems for military applications is currently a contested and debated issue.

      Having a center in ethics‐informed interdisciplinary research and the integration of ethical literacy throughout the UAV curriculum is a valuable step toward removing ethical concerns. It is promising that AIAA has developed a code of ethics, and recommends all aeronautical engineers to observe these codes in designing and developing air vehicles.

      There are concerns about the risks of flying the military UAVs outside war zones. There are reports that US UAVs have repeatedly crashed at civilian airports overseas throughout the world. Among the problems cited in the reports “are pilot error, mechanical failure, software bugs, and poor coordination with civilian air‐traffic controllers. Since an initial report of a crash in January of 2011 at a US base in Djibouti, there have been ‘at least six more Predators and Reapers’ crashes” in the vicinity of civilian airports overseas.

      In 2021, the FAA announced [3] two final rules for unmanned aircraft, which will require Remote Identification (Remote ID) of drones and allow remote operators of small drones to fly over people and at night under certain conditions. This is a major step toward further integrating UAVs into the National Air Space.

      A great many arguments challenge the ethical justifiability of remote weapons