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Machine Vision and Autonomous Integration Into an Unmanned Aircraft SystemVan Horne, Chris 10 1900 (has links)
ITC/USA 2013 Conference Proceedings / The Forty-Ninth Annual International Telemetering Conference and Technical Exhibition / October 21-24, 2013 / Bally's Hotel & Convention Center, Las Vegas, NV / The University of Arizona's Aerial Robotics Club (ARC) sponsors the development of an unmanned aerial vehicle (UAV) able to compete in the annual Association for Unmanned Vehicle Systems International (AUVSI) Seafarer Chapter Student Unmanned Aerial Systems competition. Modern programming frameworks are utilized to develop a robust distributed imagery and telemetry pipeline as a backend for a mission operator user interface. This paper discusses the design changes made for the 2013 AUVSI competition including integrating low-latency first-person view, updates to the distributed task backend, and incremental and asynchronous updates the operator's user interface for real-time data analysis.
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Machine Vision and Autonomous Integration Into an Unmanned Aircraft SystemAlexander, Josh, Blake, Sam, Clasby, Brendan, Shah, Anshul Jatin, Van Horne, Chris, Van Horne, Justin 10 1900 (has links)
The University of Arizona's Aerial Robotics Club (ARC) sponsored two senior design teams to compete in the 2011 AUVSI Student Unmanned Aerial Systems (SUAS) competition. These teams successfully design and built a UAV platform in-house that was capable of autonomous flight, capturing aerial imagery, and filtering for target recognition but required excessive computational hardware and software bugs that limited the systems capability. A new multi-discipline team of undergrads was recruited to completely redesign and optimize the system in an attempt to reach true autonomous real-time target recognition with reasonable COTS hardware.
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Coding-Based System Primitives for Airborne Cloud ComputingLin, Chit-Kwan January 2011 (has links)
The recent proliferation of sensors in inhospitable environments such as disaster or battle zones has not been matched by in situ data processing capabilities due to a lack of computing infrastructure in the field. We envision a solution based on small, low-altitude unmanned aerial vehicles (UAVs) that can deploy elastically-scalable computing infrastructure anywhere, at any time. This airborne compute cloud—essentially, micro-data centers hosted on UAVs—would communicate with terrestrial assets over a bandwidth-constrained wireless network with variable, unpredictable link qualities. Achieving high performance over this ground-to-air mobile radio channel thus requires making full and efficient use of every single transmission opportunity. To this end, this dissertation presents two system primitives that improve throughput and reduce network overhead by using recent distributed coding methods to exploit natural properties of the airborne environment (i.e., antenna beam diversity and anomaly sparsity). We first built and deployed an UAV wireless networking testbed and used it to characterize the ground-to-UAV wireless channel. Our flight experiments revealed that antenna beam diversity from using multiple SISO radios boosts reception range and aggregate throughput. This observation led us to develop our first primitive: ground-to-UAV bulk data transport. We designed and implemented FlowCode, a reliable link layer for uplink data transport that uses network coding to harness antenna beam diversity gains. Via flight experiments, we show that FlowCode can boost reception range and TCP throughput as much as 4.5-fold. Our second primitive permits low-overhead cloud status monitoring. We designed CloudSense, a network switch that compresses cloud status streams in-network via compressive sensing. CloudSense is particularly useful for anomaly detection tasks requiring global relative comparisons (e.g., MapReduce straggler detection) and can achieve up to 16.3-fold compression as well as early detection of the worst anomalies. Our efforts have also shed light on the close relationship between network coding and compressive sensing. Thus, we offer FlowCode and CloudSense not only as first steps toward the airborne compute cloud, but also as exemplars of two classes of applications—approximation intolerant and tolerant—to which network coding and compressive sensing should be judiciously and selectively applied. / Engineering and Applied Sciences
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Communication-aware planning aid for single-operator multi-UAV teams in urban environmentsChristmann, Hans Claus 21 September 2015 (has links)
With the achievement of autonomous flight for small unmanned aircraft, currently
ongoing research is expanding the capabilities of systems utilizing such
vehicles for various tasks. This allows shifting the research focus from the
individual systems to task execution benefits resulting from interaction and
collaboration of several aircraft.
Given that some available high-fidelity simulations do not yet support
multi-vehicle scenarios, the presented work introduces a framework which allows
several individual single-vehicle simulations to be combined into a larger
multi-vehicle scenario with little to no special requirements towards the
single-vehicle systems. The created multi-vehicle system offers real-time
software-in-the-loop simulations of swarms of vehicles across multiple hosts and
enables a single operator to command and control a swarm of unmanned aircraft
beyond line-of-sight in geometrically correct two-dimensional cluttered
environments through a multi-hop network of data-relaying intermediaries.
This dissertation presents the main aspects of the developed system: the
underlying software framework and application programming interface, the
utilized inter- and intra-system communication architecture, the graphical user
interface, and implemented algorithms and operator aid heuristics to support the
management and placement of the vehicles. The effectiveness of the aid
heuristics is validated through a human subject study which showed that the
provided operator support systems significantly improve the operators'
performance in a simulated first responder scenario.
The presented software is released under the Apache License 2.0 and, where
non-open-source parts are used, software packages with free academic licenses
have been chosen--resulting in a framework that is completely free for academic
research.
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Evaluating SLAM algorithms for Autonomous HelicoptersSkoglund, Martin January 2008 (has links)
Navigation with unmanned aerial vehicles (UAVs) requires good knowledge of the current position and other states. A UAV navigation system often uses GPS and inertial sensors in a state estimation solution. If the GPS signal is lost or corrupted state estimation must still be possible and this is where simultaneous localization and mapping (SLAM) provides a solution. SLAM considers the problem of incrementally building a consistent map of a previously unknown environment and simultaneously localize itself within this map, thus a solution does not require position from the GPS receiver. This thesis presents a visual feature based SLAM solution using a low resolution video camera, a low-cost inertial measurement unit (IMU) and a barometric pressure sensor. State estimation in made with a extended information filter (EIF) where sparseness in the information matrix is enforced with an approximation. An implementation is evaluated on real flight data and compared to a EKF-SLAM solution. Results show that both solutions provide similar estimates but the EIF is over-confident. The sparse structure is exploited, possibly not fully, making the solution nearly linear in time and storage requirements are linear in the number of features which enables evaluation for a longer period of time.
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Artificial neural networks to updrafts localization and forecasting / Terminių srautų aptikimas ir prognozavimas taikant dirbtinius neuronų tinklusSuzdalev, Ivan 08 March 2013 (has links)
The dissertation examines the thermal flow detection and prediction prob-lems during an autonomous aircraft flight. The main research object is the thermal flows and artificial neural networks. Thermal flows are a very im-portant source for improving autonomous aircraft flight parameters, such as flight time and duration.
The primary aim of the dissertation is to create methodologies and algorithms to detect, identify and to successfully predict the parameters the thermal flows. The application are of the methods and algorithms developed is autonomous aircraft control system synthesis, research on mesoscale meteorological phenomena and synthesis of computing systems using biological models.
The following objectives are carried out: thermal flow sensing using aircraft navigational parameters measurement data, thermal flow simulation modeling and data input necessary for modeling.
The dissertation consists of an introduction, four chapters, conclusions, bibliography, and list of author publications on the topic as well as three annexes.
The introductory chapter discusses the research problem and the relevance of the research described in the thesis, formulates the goal and objectives, describes the research methodology, scientific novelty, the practical significance of the results, hypotheses. In the end of the introduction a list of author's publications on the topic and the structure of the dissertation are presented.
The first section provides a review of previous... [to full text] / Disertacijoje nagrinėjamos terminių srautų paieškos ir prognozavimo autonominio orlaivio skrydžio metu problemos. Pagrindinis tyrimų objektas yra terminių srautų aparatinis aptikimas ir prognozavimas. Terminiai srautai yra labai svarbus autonominio orlaivio skrydžio charakteristikų, kaip antai skrydžio laikas ir trukmė, gerinimo šaltinis.
Pagrindinis disertacijos tikslas – sukurti metodikas ir algoritmus, leidžiančius aptikti terminį srautą, nustatyti bei sėkmingai prognozuoti jo parametrus. Sukurtų metodų ir algoritmų taikymo sritis – autonominių orlaivių valdymo sistemų sintezė, meteorologiniai mezomastelinių meteorologinių reiškinių tyrimai, biologinius skaičiavimo modelius naudojančių sistemų sintezė.
Darbe sprendžiami keli uždaviniai: terminio srauto aptikimas naudojant orlaivio navigacinių parametrų matavimo duomenis, terminio srauto modeliavimas bei modeliui reikalingų duomenų pateikimas.
Disertaciją sudaro įvadas, keturi skyriai, rezultatų apibendrinimas, naudotos literatūros ir autoriaus publikacijų disertacijos tema sąrašai ir tris priedai.
Įvadiniame skyriuje aptariama tiriamoji problema, darbo aktualumas, aprašomas tyrimų objektas, formuluojamas darbo tikslas bei uždaviniai, aprašoma tyrimų metodika, darbo mokslinis naujumas, darbo rezultatų praktinė reikšmė, ginamieji teiginiai. Įvado pabaigoje pristatomos disertacijos tema autoriaus paskelbtos publikacijos ir konferencijų pranešimai bei disertacijos struktūra.
Pirmajame skyriuje pateikiama su disertacijos... [toliau žr. visą tekstą]
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Terminių srautų aptikimas ir prognozavimas taikant dirbtinius neuronų tinklus / Artificial neural networks to updrafts localization and forecastingSuzdalev, Ivan 08 March 2013 (has links)
Disertacijoje nagrinėjamos terminių srautų paieškos ir prognozavimo autonominio orlaivio skrydžio metu problemos. Pagrindinis tyrimų objektas yra terminių srautų aparatinis aptikimas ir prognozavimas. Terminiai srautai yra labai svarbus autonominio orlaivio skrydžio charakteristikų, kaip antai skrydžio laikas ir trukmė, gerinimo šaltinis.
Pagrindinis disertacijos tikslas – sukurti metodikas ir algoritmus, leidžiančius aptikti terminį srautą, nustatyti bei sėkmingai prognozuoti jo parametrus. Sukurtų metodų ir algoritmų taikymo sritis – autonominių orlaivių valdymo sistemų sintezė, meteorologiniai mezomastelinių meteorologinių reiškinių tyrimai, biologinius skaičiavimo modelius naudojančių sistemų sintezė.
Darbe sprendžiami keli uždaviniai: terminio srauto aptikimas naudojant orlaivio navigacinių parametrų matavimo duomenis, terminio srauto modeliavimas bei modeliui reikalingų duomenų pateikimas.
Disertaciją sudaro įvadas, keturi skyriai, rezultatų apibendrinimas, naudotos literatūros ir autoriaus publikacijų disertacijos tema sąrašai ir tris priedai.
Įvadiniame skyriuje aptariama tiriamoji problema, darbo aktualumas, aprašomas tyrimų objektas, formuluojamas darbo tikslas bei uždaviniai, aprašoma tyrimų metodika, darbo mokslinis naujumas, darbo rezultatų praktinė reikšmė, ginamieji teiginiai. Įvado pabaigoje pristatomos disertacijos tema autoriaus paskelbtos publikacijos ir konferencijų pranešimai bei disertacijos struktūra.
Pirmajame skyriuje pateikiama su disertacijos... [toliau žr. visą tekstą] / The dissertation examines the thermal flow detection and prediction prob-lems during an autonomous aircraft flight. The main research object is the thermal flows and artificial neural networks. Thermal flows are a very im-portant source for improving autonomous aircraft flight parameters, such as flight time and duration.
The primary aim of the dissertation is to create methodologies and algorithms to detect, identify and to successfully predict the parameters the thermal flows. The application are of the methods and algorithms developed is autonomous aircraft control system synthesis, research on mesoscale meteorological phenomena and synthesis of computing systems using biological models.
The following objectives are carried out: thermal flow sensing using aircraft navigational parameters measurement data, thermal flow simulation modeling and data input necessary for modeling.
The dissertation consists of an introduction, four chapters, conclusions, bibliography, and list of author publications on the topic as well as three annexes.
The introductory chapter discusses the research problem and the relevance of the research described in the thesis, formulates the goal and objectives, describes the research methodology, scientific novelty, the practical significance of the results, hypotheses. In the end of the introduction a list of author's publications on the topic and the structure of the dissertation are presented.
The first section provides a review of previous... [to full text]
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Nonlinear State Estimation and Modeling of a Helicopter UAVBarczyk, Martin Unknown Date
No description available.
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Post-manoeuvre and online parameter estimation for manned and unmanned aircraftJameson, Pierre-Daniel 07 1900 (has links)
Parameterised analytical models that describe the trimmed inflight behaviour of classical
aircraft have been studied and are widely accepted by the flight dynamics community.
Therefore, the primary role of aircraft parameter estimation is to quantify the parameter
values which make up the models and define the physical relationship of the air vehicle with
respect to its local environment. Nevertheless, a priori empirical predictions dependent
on aircraft design parameters also exist, and these provide a useful means of generating
preliminary values predicting the aircraft behaviour at the design stage. However, at
present the only feasible means that exist to actually prove and validate these parameter
values remains to extract them through physical experimentation either in a wind-tunnel
or from a flight test. With the advancement of UAVs, and in particular smaller UAVs
(less than 1m span) the ability to fly the full scale vehicle and generate flight test data
presents an exciting opportunity. Furthermore, UAV testing lends itself well to the ability
to perform rapid prototyping with the use of COTS equipment.
Real-time system identification was first used to monitor highly unstable aircraft behaviour
in non-linear flight regimes, while expanding the operational flight envelope. Recent
development has focused on creating self-healing control systems, such as adaptive
re-configurable control laws to provide robustness against airframe damage, control surface
failures or inflight icing. In the case of UAVs real-time identification, would facilitate rapid
prototyping especially in low-cost projects with their constrained development time. In
a small UAV scenario, flight trials could potentialy be focused towards dynamic model
validation, with the prior verification step done using the simulation environment. Furthermore,
the ability to check the estimated derivatives while the aircraft is flying would
enable detection of poor data readings due to deficient excitation manoeuvres or atmospheric
turbulence. Subsequently, appropriate action could then be taken while all the
equipment and personnel are in place.
This thesis describes the development of algorithms in order to perform online system
identification for UAVs which require minimal analyst intervention. Issues pertinent
to UAV applications were: the type of excitation manoeuvers needed and the necessary
instrumentation required to record air-data. Throughout the research, algorithm development
was undertaken using an in-house Simulink© model of the Aerosonde UAV which
provided a rapid and flexible means of generating simulated data for analysis. In addition,
the algorithms were further tested with real flight test data that was acquired from
the Cranfield University Jestream-31 aircraft G-NFLA during its routine operation as a
flying classroom. Two estimation methods were principally considered, the maximum likelihood
and least squares estimators, with the aforementioned found to be best suited to
the proposed requirements. In time-domain analysis reconstruction of the velocity state
derivatives ˙W and ˙V needed for the SPPO and DR modes respectively, provided more statistically
reliable parameter estimates without the need of a α- or β- vane. By formulating
the least squares method in the frequency domain, data issues regarding the removal of
bias and trim offsets could be more easily addressed while obtaining timely and reliable
parameter estimates. Finally, the importance of using an appropriate input to excite the
UAV dynamics allowing the vehicle to show its characteristics must be stressed.
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DEVELOPMENT OF AN UNMANNED AERIAL VEHICLE FOR LOW-COST REMOTE SENSING AND AERIAL PHOTOGRAPHYSimpson, Andrew David 01 January 2003 (has links)
The paper describes major features of an unmanned aerial vehicle, designed undersafety and performance requirements for missions of aerial photography and remotesensing in precision agriculture. Unmanned aerial vehicles have vast potential asobservation and data gathering platforms for a wide variety of applications. The goalof the project was to develop a small, low cost, electrically powered, unmanned aerialvehicle designed in conjunction with a payload of imaging equipment to obtainremote sensing images of agricultural fields. The results indicate that this conceptwas feasible in obtaining high quality aerial images.
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