Studio e implementazione di un autopilota su un UAV ad ala fissa

Si riporta inizialmente un’analisi tecnica dell’autopilota Ardupilot, utilizzato con il firmware Arduplane, che predispone la scheda all’utilizzo specifico su velivoli senza pilota ad ala fissa. La parte sostanziale della tesi riguarda invece lo studio delle leggi di controllo implementate su Arduplane e la loro modellazione, assieme ad altre parti del codice, in ambiente Matlab Simulink. Il sistema di controllo creato, chiamato Attitude Flight System, viene verificato con la tecnica del Software In the Loop in un simulatore di volo virtuale modellato anch’esso in Simulink, si utilizza la dinamica di un velivolo UAV di prova e il software FlightGear per l’ambiente grafico. Di fondamentale importanza è la verifica della compatibilità fra il firmware originale e il codice generato a partire dai modelli Simulink, verifica effettuata mediante test di tipo Hardware in the Loop. L’ultima parte della tesi descrive le prove di volo svolte per verificare le prestazioni della scheda su un aeromodello trainer.

Progetto preliminare di un UAV multi-modale

Studio, a livello preliminare, di un sistema a pilotaggio remoto che permetta la sorveglianza e il monitoraggio di zone aeree e marine ad alto rischio e in contemporanea di compiere una raccolta di dati che possa essere inviata in tempo reale ad un utente a terra. Negli ultimi anni si è sviluppato notevolmente il settore dei velivoli a pilotaggio remoto sia ad ala fissa sia ad ala rotante, per la videoripresa e la fotografia aerea a bassa quota, che è utilizzata in molti ambiti tra i quali la fotogrammetria, la geologia e l’archeologia, nonché per studi scientifici e per la sicurezza. Nel presente lavoro di tesi è stata studiata la fattibilità di un UAV capace di effettuare la sua missione, previa pianificazione, in due ambienti completamente diversi fra loro: l’aria e l’acqua. Così facendo si ha la possibilità di acquistare un solo mezzo con costi minori e con un profilo di missione molto più vasto. Lo sviluppo di questo drone, pensato per operazioni di protezione civile, si è articolato in più fasi: anzitutto si è cercato di stabilire quale fosse il suo ambito di utilizzo e quali caratteristiche avrebbe dovuto avere. Successivamente si è iniziato a valutare l’equipaggiamento del velivolo con tutti i sistemi necessari per compiere la sua attività ed infine si è realizzato un disegno CAD semplificato della sua struttura. La seconda parte del lavoro è stata incentrata sullo studio preliminare della stabilità del velivolo sia in configurazione aerea sia in quella marina andando dapprima a calcolare la posizione del baricentro dell’UAV in modo da avere un velivolo aereo staticamente stabile e a simularne il volo. Successivamente si è modificato un modello Simulink di un UAV disponibile in rete, adattandolo opportunamente a questo caso per simulare parte della missione e si è potuto constatare che il velivolo risulta essere stabile; per far questo sono state calcolate diverse derivate aerodinamiche in modo da poter simulare il comportamento dinamico del velivolo. Anche per la configurazione marina sono state calcolate le derivate aerodinamiche più significative ed è stata realizzata una simulazione per valutare la stabilità del ROV, sempre a comandi fissi. In ultima analisi si è studiata una missione tipica che potrebbe effettuare questo UAV multi-modale: per fare ciò si è tracciata in Google Earth una traiettoria cui sono stati aggiunti alcuni modelli CAD nelle fasi principali del volo per far capire come varia la forma del mezzo durante la missione. Lo scenario della missione è in un contesto di disastro ambientale dovuto ad un incidente in una centrale nucleare vicina al mare, caso che ben si presta alla applicazione di questo mezzo a pilotaggio remoto.

A treatise upon the art of flying, by mechanical means, with a full explanation of the natural principles by which birds are enabled to fly : likewise instructions and plans, for making a flying car with wings, in which a man may sit, and, by working a small lever, cause himself to ascend and soar through the air with the facility of a bird... /

Mode of access: Internet.

Flying Spore Trap Airborne Based Surveillance : towards a Biosecure Australia

The main limitations with existing fungal spore traps are that they are stationary and cannot be used in inaccessible or remote areas of Australia. This may result in delayed assessment, possible spread of harmful crop infestations and loss of crop yield and productivity. Fitted with the developed smart spore trap the UAV can fly, detect and monitor spores of plant pathogens in areas which previously were almost impossible to monitor. The technology will allow for earlier detection of emergency plant pests (EPPs) incursions by providing efficient and effective airborne surveillance, helping to protect Australia’s crops, pastures and the environment. The project is led by the Cooperative Research Centre for National Plant Biosecurity, with ARCAA/ QUT, CSIRO and the Queensland Government also providing resources. The prototype airplane was exhibited at the Innovation in Australia event December 7.

Outdoor flight testing of a pole inspection UAV incorporating high-speed vision

We present a pole inspection system for outdoor environments comprising a high-speed camera on a vertical take-off and landing (VTOL) aerial platform. The pole inspection task requires a vehicle to fly close to a structure while maintaining a fixed stand-off distance from it. Typical GPS errors make GPS-based navigation unsuitable for this task however. When flying outdoors a vehicle is also affected by aerodynamics disturbances such as wind gusts, so the onboard controller must be robust to these disturbances in order to maintain the stand-off distance. Two problems must therefor be addressed: fast and accurate state estimation without GPS, and the design of a robust controller. We resolve these problems by a) performing visual + inertial relative state estimation and b) using a robust line tracker and a nested controller design. Our state estimation exploits high-speed camera images (100Hz) and 70Hz IMU data fused in an Extended Kalman Filter (EKF). We demonstrate results from outdoor experiments for pole-relative hovering, and pole circumnavigation where the operator provides only yaw commands. Lastly, we show results for image-based 3D reconstruction and texture mapping of a pole to demonstrate the usefulness for inspection tasks.

Green Falcon and Raptor UAV for remote gas sensing

This report documents showcases my learning experiences and design of Green Falcon Solar Powered UAV. Only responsible aspects will be discussed inside this report. Using solar power that is captured by solar panels it can fly all day and also store power for night flying. Its major advantage lies in the fact that it is simple and versatile, which makes it applicable to a large range of UAVs of different wingspans. Green Falcon UAV is designed as a supporting tool for scientists to get a deeper understanding of gases exchange amongst ground plane and atmosphere

Aerodynamics of delta wings with flaps at hypersonic speeds

Control surface effectiveness is an important parameter for any aeroplane. For a hypersonic aircraft, though the power required to operate the flaps is determined by low speed flying conditions, it is imperative to know the effect of flaps at hypersonic speeds. Hence, studies have been done on this topic by aerodynamicists for over 40 years. In spite of this, only a limited data is available in the literature on this subject. This paper discusses the experimental study of the effect of sweep on the aerodynamic characteristics of thin slab delta wings with flaps at hypersonic speeds. For the purpose of this investigation, a novel special thin six-component balance, which has a thickness of 4mm and can be housed inside wings with 8mm thickness, has been designed. The wings had a sweep of 76degrees, 70degrees and 65degrees, t/c of 0.053 and flaps with 12% of wing area and 12% of wing chord. Testing were done at Mach 8.2, Re number of 2.13 x 10(6) (based on chord), from alpha = -12degrees to 12degrees and flap angle of 20degrees, 30degrees and 40degrees. Separation lengths, measured from Schlieren pictures, clearly show that there is 'no appreciable' effect of sweep on them. Also, using a simple local flow field calculation, the separation has been identified to be transitional in nature. These features of separation reflect in the force data. Because of the small separation length, the flaps (inspite of their small size) were very effective in generating additional C-N, C-M and C-l, which increased with increase in flap angle. In general, the C-N, C-M and X-CP were unaffected by sweep for symmetric flap deflection at positive incidences and asymmetric flap case, For symmetric flap case at negative incidences, only C-N was not influenced by the sweep but C-M decreased and X-CP moved upstream as the sweep is decreased, The wing with lower sweep produces higher CA and lower (L/D)(max) for both symmetric and asymmetric flaps. The rolling moment and adverse yaw increased with decrease in sweep for asymmetric flap deflection. Newtonian theory is shown to be incapable of predicting the effect of sweep on C-l, C-n and on the incremental values of C-N, C-M and C-A. In conclusion, it can be said that a small flap is generally adequate for hypersonic aeroplanes provided they operate at altitudes where transitional and turbulent separation can be expected to occur. This would make the flaps effective and thus enable ample control authority.

Common-mode voltage eliminated three-level inverter using a three-level flying-capacitor inverter and cascaded H-bridge

This paper proposes a new 3 level common mode voltage eliminated inverter using an inverter structure formed by cascading a H-Bridge with a three-level flying capacitor inverter. The three phase space vector polygon formed by this configuration and the polygon formed by the common-mode eliminated states have been discussed. The entire system is simulated in Simulink and the results are experimentally verified. This system has an advantage that if one of devices in the H-Bridge fails, the system can still be operated as a normal 3 level inverter mode at full power. This inverter has many advantages like use of single DC-supply, making it possible for a back to back grid-tied converter application, improved reliability etc.

A Three-Level Common-Mode Voltage Eliminated Inverter With Single DC Supply Using Flying Capacitor Inverter and Cascaded H-Bridge

A three-level common-mode voltage eliminated inverter with single dc supply using flying capacitor inverter and cascaded H-bridge has been proposed in this paper. The three phase space vector polygon formed by this configuration and the polygon formed by the common-mode eliminated states have been discussed. The entire system is simulated in Simulink and the results are experimentally verified. This system has an advantage that if one of devices in the H-bridge fails, the system can still be operated as a normal three-level inverter at full power. This inverter has many other advantages like use of single dc supply, making it possible for a back-to-back grid-tied converter application, improved reliability, etc.

Control de vuelo de un cuadricóptero AR-Drone

[ES]En este TFG se obtendrá un algoritmo de generación de trayectorias para el cuadricóptero AR-Drone capaz de conseguir trazados lo más rápidos posibles teniendo en cuenta la dinámica del modelo y las limitaciones del entorno. Así mismo se propondrá un control primitivo para la detección de obstáculos. Mediante las comunicaciones con el cuadricóptero y el control de los parámetros característicos del medio, se establecerá usando el lenguaje C# los bucles de programación necesarios para discriminar todas las trayectorias desfavorables y obtener una que se adecue a nuestros criterios.

Plataforma de informação e de apoio ao voo de aeronaves não tripuladas (UAV)

Trabalho de projeto de mestrado, Educação (Especialidade de Educação e Tecnologias Digitais), Universidade de Lisboa, Instituto de Educação, 2014

Estrategia de intervención militar de Estados Unidos en Medio Oriente: dinámicas y consecuencias del uso de drones en Yemen y Pakistán entre 2009 a 2013

Este es un estudio sobre la estrategia de guerra estadounidense en Medio Oriente basada en el uso sistemático de drones durante el periodo comprendido entre 2009 y 2013. Se busca explicar de qué manera puede considerarse el uso de este tipo de armamento como una práctica basada en la proyección de poder sin mayor vulnerabilidad. Los casos de Pakistán y Yemen son abordados, ya que evidencian las características de las operaciones selectivas por las que ha abogado el Presidente Obama. El estudio se inscribe dentro del realismo ofensivo, haciendo también referencia a sus limitaciones explicativas. Empero, se afirma que las dinámicas y consecuencias de la utilización de drones son intrínsecas a la necesidad estadounidense de combatir actores no estatales mediante prácticas que garanticen su seguridad y pretensiones hegemónicas a pesar de las implicaciones políticas , legales y sociales en las que puede incurrir.

Adaptation of an commercially available stabilised R/C helicopter to a fully autonomous surveillance UAV

This paper presents the development of an autonomous surveillance UAV that competed in the Ministry of Defence Grand Challenge 2008. In order to focus on higher-level mission control, the UAV is built upon an existing commercially available stabilised R/C helicopter platform. The hardware architecture is developed to allow for non-invasion integration with the existing stabilised platform, and to enable to the distributed processing of closed loop control and mission goals. The resulting control system proved highly successful and was capable of flying within 40knott gusts. The software and safety architectures were key to the success of the research and also hold the potential for use in the development of more complex system comprising of multiple UAVs.

Bio-inspired autonomous visual vertical control of a quadrotor UAV

Near ground maneuvers, such as hover, approach and landing, are key elements of autonomy in unmanned aerial vehicles. Such maneuvers have been tackled conventionally by measuring or estimating the velocity and the height above the ground often using ultrasonic or laser range finders. Near ground maneuvers are naturally mastered by flying birds and insects as objects below may be of interest for food or shelter. These animals perform such maneuvers efficiently using only the available vision and vestibular sensory information. In this paper, the time-to-contact (Tau) theory, which conceptualizes the visual strategy with which many species are believed to approach objects, is presented as a solution for Unmanned Aerial Vehicles (UAV) relative ground distance control. The paper shows how such an approach can be visually guided without knowledge of height and velocity relative to the ground. A control scheme that implements the Tau strategy is developed employing only visual information from a monocular camera and an inertial measurement unit. To achieve reliable visual information at a high rate, a novel filtering system is proposed to complement the control system. The proposed system is implemented on-board an experimental quadrotor UAV and shown not only to successfully land and approach ground, but also to enable the user to choose the dynamic characteristics of the approach. The methods presented in this paper are applicable to both aerial and space autonomous vehicles.