Micro- and Nano-Air Vehicles: State of the Art

Petricca, Luca; Øhlckers, Per; Grinde, Christopher

doi:10.1155/2011/214549

Cited by 112 publications

(85 citation statements)

References 43 publications

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“…All these sensors are required to meet the stringent payload constraints along with ultra-low power requirements set for future ultralight MAVs and NAVs. The current state of the art definition for a sensor requires weight to be less than 2 grams and power consumption of less than 100 mW [6]. Future NAVs will be equipped with navigation and radar systems along with on-board infrared high-definition cameras.…”

Section: Materials and Manufacturing Limitationsmentioning

confidence: 99%

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Nature Inspired Flying Vehicles and Future Challenges in Aerospace

Naqvi

Abbas

Raza

et al. 2015

IJAET

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The challenges of modern urban warfare require high agility flying machines capable of flight in confined dirty, dull and dangerous (D 3 ) environments. Recent technological advancements in the field of aerospace and materials have enabled the exploration of flight regimes and designs similar to those of birds and insects. Flying robots with a size limit of 6 inches in all dimensions are called Micro Air Vehicles (MAVs) [1] and smaller ones with the size constraint of 1 inch are termed Nano Air Vehicles (NAVs). Fixed wing aerial vehicles are generally preferred in this flight regime due to simplistic design but these lack the hovering capability. Rotary wing designs are also being pursued with added hovering capability, but these cannot move faster through the air and their endurance is limited by the size and capacity of on-board batteries. In order to mimic the maneuverability of birds and insects, flapping wing designs are required which could produce lift and thrust efficiently using the same wing planform. Future, advancements in materials, manufacturing technology and miniaturization of electronics will enable design and development of flapping wing robots similar to natural birds and insects with very demanding mission profiles. This paper aims at highlighting the future requirements of urban warfare along with the challenges being faced to pursue flapping wing designs mimicking insects and birds flight.

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Section: Materials and Manufacturing Limitationsmentioning

confidence: 99%

“…NAVs have opened new dimensions in the modern urban warfare operations and are being aggressively pursued by academia and industry. There has been a continuous reduction in size of designed aerial vehicles [6] with the time as shown in Figure 1. …”

Section: Introductionmentioning

confidence: 99%

Nature Inspired Flying Vehicles and Future Challenges in Aerospace

Naqvi

Abbas

Raza

et al. 2015

IJAET

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“…One of the reasons why an ultra-light fixed wing flying robot, weighing less than 20 g, has not been successfully constructed is considered due to increasing viscous force effect in low Reynolds number flow [7]. Second barrier to fixed wing type robot for outdoor flight is considered to be gust influence.…”

Section: Introductionmentioning

confidence: 99%

Aerodynamic Bio-Mimetics of Gliding Dragonflies for Ultra-Light Flying Robot

et al. 2014

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Abstract:A detailed investigation including a low-speed flow study is presented on the development of ultra-light dragonfly mimetic flying robots with a focus on the dragonfly's remarkable gliding capability. It is revealed that the dragonfly's corrugated wing structure and cruciform configuration provide superior flying characteristics for fixed wing robots in low Reynolds number flight. It was also found that the dragonfly configuration has additional merit in its compatibility with propellers or high lift devices. This combination with such classic aero-engineering makes possible robots with broader flight envelope than conventional fixed-wing flying robots.

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“…The new platforms have also undergone a great evolution; since the beginning of the first captive unmanned vehicles, such as kites [19], balloons [20] and zeppelins [21], to the modern drones based on multi-rotors [22], fixed-wing [23] and hybrid platforms (fixed-wing hybrid vertical take-off and landing) [24], without forgetting the nano-drones [25]. Some characteristics of these new platforms, which in many cases make them unique, can be heights of flight below the limits of aerial navigation with a consequent increase in spatial resolution; low flight speed which can reach zero while maintaining a static flight (multi-rotors); the possibility of flight in complex environments, for example, between buildings or even flights for indoor mapping [26]; the addition of durable and lightweight materials such as carbon fiber.…”

mentioning

confidence: 99%

Drones—An Open Access Journal

Aguilera

Rodríguez‐Gonzálvez

2017

Drones

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Since the beginning of aviation, unmanned aerial systems have been a challenge for scientists and engineers. The first automatic airplane developed by the Wright brothers in 1916 and the drone used by the British Royal Navy for gunnery practice in 1933 serve as examples. The possibility of controlling an aircraft without a pilot has been a challenge, both from the civil and military point of view. Nowadays, the proliferation of unmanned aerial systems, popularly known as "drones", is a reality for local policy makers, regulatory bodies, mapping authorities, start-ups and consolidated companies. The number of developed drones has increased threefold from 2005 to present and, additionally, a relevant increase has been observed in the civil/commercial type of platforms, especially in 2012 and 2013 [1]. There are many uses and benefits of drones based on their own pilot system (autonomous or remotely controlled) and sensory to achieve accurate positioning and to acquire a great variety of data. By this binomial, drones are an efficient solution for the observation, inspection, measurement and monitoring of territory; ensuring better spatial, radiometric, spectral and temporal resolutions than any manned aerial vehicle and satellite.Drones have caused an unprecedented impact on society and the economy. According to recent market research [2], the global drones market revenue is worth $6,800 M United States Dollars (USD) as of 2016 and is expected to grow up to $36,900 M USD by 2022. The low-cost of the sensors integrated in aerial platforms of different designs has launched its application and proliferation more than its military origin, offering new applications and leading to more clients in the civil sector. It is in this last sector where more progress by drones is expected. For instance, new developments in robotics, computer vision and geomatic technologies, together with more research and development supported by technological centres and universities, allow the improvement of technology transfer with an important insight into new markets. While it is true that these civil-drones are still far from the systems used in military applications, studies and advances in the development of technology can offer professional systems with new, improved and promising features.In this sense, it is expected that the main advances of drones may occur in the following lines: (1) the emergence of new sensors that allow the improvement of the geometric and radiometric resolution, as well as the spectral range; (2) the evolution of new platforms that improve robustness and increase autonomy; (3) the development of software, from the navigation and communication with the platform to the processing and analysis of the images captured; (4) new applications in emerging sectors: logistics, disaster assistance, security and surveillance, health and marine science, among others.The emergence of new sensors, thanks to advances in microelectronics and nanotechnology [3-5] will be crucial in the coming years. In fact, the evolution of in...

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Micro- and Nano-Air Vehicles: State of the Art

Cited by 112 publications

References 43 publications

Nature Inspired Flying Vehicles and Future Challenges in Aerospace

Nature Inspired Flying Vehicles and Future Challenges in Aerospace

Aerodynamic Bio-Mimetics of Gliding Dragonflies for Ultra-Light Flying Robot

Drones—An Open Access Journal

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