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The Design of a Video Acquisition System for JSFVu, Doug, Roach, John 10 1900 (has links)
ITC/USA 2009 Conference Proceedings / The Forty-Fifth Annual International Telemetering Conference and Technical Exhibition / October 26-29, 2009 / Riviera Hotel & Convention Center, Las Vegas, Nevada / The F-35 program, known as the Joint Strike Fighter (JSF), is the largest DOD program ever awarded. There are three F-35 variations, each intended to meet the specific needs of the Air Force, Navy, Marine Corps, and Allies. The F-35 Joint Strike Fighter represents the newest advanced military aircraft to make use of Fibre Channel as its primary avionics information transport network. In addition to its use for carrying tactical information systems data, the Fibre Channel network will also transport the real-time digital video used in the cockpit; primarily the pilot's helmet mounted display (HMD) and the high-resolution configurable panoramic cockpit display (PCD). In addition to the fighter's instrumentation configuration for orange wire and avionics data, the aircraft will carry a separate instrumentation package to allow for both the recording and telemetry of either high-resolution Fibre Channel digital video or standard resolution analog video inputs during flight tests. This multiplexer is designed to record cockpit video and audio data, while supporting an option for the test engineer to select up to three out of eight video and audio inputs for real-time telemetry to the ground. This paper describes the architecture of this system, along with the techniques used to reduce the 5 MBps Fibre Channel digital video to a bandwidth acceptable for telemetry.
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Secure ground-based remote recording and archiving of aircraft "Black Box" data /Schoberg, Paul R. January 2003 (has links) (PDF)
Thesis (M.S. in Computer Science)--Naval Postgraduate School, September 2003. / Thesis advisor(s): Cynthia E. Irvine, Scott Cote. Includes bibliographical references (p. 169-171). Also available online.
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Einsatz automatischer Abstandsregelung bei der Sequenzierung von Luftfahrzeugen im erweiterten Nahbereich von VerkehrsflughäfenPütz, Thomas January 2008 (has links)
Zugl.: Berlin, Techn. Univ., Diss., 2008
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Darstellung von Belastungsparametern und Steuerbefehlen in einem modernen Glascockpit zur Vermeidung der Überschreitung der ultimate loadDaser, Gunther. Unknown Date (has links) (PDF)
Techn. Universiẗat, Diss., 2002--Berlin.
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Verwendung stereoskopischer Informationsdarstellung in durchsichtfähigen Anzeigen am Beispiel eines Head-Up Displays /Kaiser, Jochen. January 2004 (has links)
Techn. Universiẗat, Diss., 2004--Darmstadt.
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Přístrojové vybavení pro čtyřmístný sportovní a turistický letoun / Cockpit instruments for four-seater sport and leisure aircraftLiberda, Jiří January 2013 (has links)
This master thesis includes a comprehensive review of four-seater sport and leisure aircraft with focus on their cockpit instruments. The description of the selected glass cockpits is listed. Thesis also includes design of instrument panel, which is designed according to the relevant regulations and standard configuration of existing aircrafts. There is also a brief overview of the regulations necessary for the installation of these systems in the aircrafts. At the end of the this work is failure mode and effects analysis, with calculation of probability malfunction for critical functions.
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AN XML-DRIVEN ARCHITECTURE FOR INSTRUMENTATION COCKPIT DISPLAY SYSTEMSPortnoy, Michael, Berdugo, Albert 10 1900 (has links)
ITC/USA 2005 Conference Proceedings / The Forty-First Annual International Telemetering Conference and Technical Exhibition / October 24-27, 2005 / Riviera Hotel & Convention Center, Las Vegas, Nevada / Designing and implementing an instrumentation cockpit display system presents many unique
challenges. The system must be easy to use, yet highly customizable. Typically, these systems
require an experienced programmer to create graphical display screens. Furthermore, most
current display systems do not provide for bi-directional communication between the
instrumentation system and the display system.
This paper discusses an architecture that addresses these issues and other common problems with
cockpit displays. This system captures data from the instrumentation system, displays
parameters, and returns calculated parameters and status information regarding pilot actions to
the instrumentation system. Unlike traditional systems, the configuration of the graphical
presentation of the cockpit display can be done by a non-programmer. All communication
between the instrumentation system and the cockpit display system is done transparently using
XML. The usage of XML in this system facilitates real-time form previewing, cross-platform
compatibility, and seamless transitions between project management, graphical configuration,
and engineering unit conversions.
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Análise de cockpits de ônibus a partir das demandas dos motoristas e características da tarefaBasso, Claudia Rafaela January 2018 (has links)
Os motoristas de ônibus apresentam problemas de saúde física e psicológica decorrentes da exposição a fatores relacionados com a organização do trabalho e com a própria configuração do ônibus, mais especificamente da cabine, onde realizam suas atividades. Os projetos das cabines dos ônibus e do seu cockpit, interface através da qual o motorista envia comandos para o ônibus, normalmente desconsideram a opinião do motorista e a relação entre produto/usuário/contexto de uso real, fundamental para garantir um projeto de interface adequado, segundo os conceitos de ergonomia e design. Assim, esta pesquisa tem como objetivo estudar e determinar as demandas dos motoristas de transporte rodoviário e urbano de passageiros com relação aos cockpits de ônibus, a fim de propor melhorias considerando as características da tarefa e a opinião dos motoristas com relação ao seu conforto e desempenho. Participaram do estudo duas empresas de transporte de passageiros, uma rodoviária e outra urbana. A metodologia foi estruturada em três fases. A primeira (Pré-análise) teve como objetivo conhecer os cockpits dos ônibus, entender os requisitos considerados na compra de novos veículos e evidenciar as condições do cockpit que atuam na dirigibilidade do veículo. A segunda fase (Análise) consistiu em investigar a percepção dos motoristas com relação aos cockpits dos ônibus, realizado observação in loco, filmagens, entrevistas, questionário e dinâmica do protótipo de papel Na terceira fase (Pós-análise) foi realizada a triangulação dos dados para identificar os fatores de conforto mais relevantes e a comparação dos resultados dos dois grupos de motoristas. Os resultados da dinâmica convergiram com aqueles das entrevistas e questionários evidenciando que, em geral, os motoristas tendem a manter os comandos nos locais em que se acostumaram, modificando somente o posicionamento daqueles que não atendem suas necessidades de forma satisfatória. A principal demanda dos motoristas de transporte rodoviário está vinculada ao posicionamento do comando do ar-condicionado no cockpit e às condições de conforto térmico na cabine. Os motoristas de transporte urbano de passageiros, por outro lado, desejam o reposicionamento do comando do itinerário para um local de fácil alcance e visibilidade quando em sedestação. Esses também relataram desconforto térmico relacionando com a inexistência do dispositivo da ventarola, uma vez que a maioria dos veículos da frota não dispõe de ar-condicionado. Os dois grupos de motoristas indicaram a necessidade de melhorar a visibilidade do painel de instrumentos que, por vezes, é dificultado pelo mau posicionamento do volante. Além disso, os dois grupos de motoristas consideraram o espaço interno da cabine, o ruído, bem como o conforto do banco, características a serem melhoradas. / Bus drivers have physical and psychological health problems due to exposure to factors related to work organization and the configuration of the bus, specifically the cabin, where they carry out their activities. The bus cabins and their cockpit‟s designs, the interface through which the driver sends commands to the bus, usually disregard the driver's opinion and the relationship between product/ user/ context of actual use, primal to ensure a proper interface design, according to the concepts of ergonomics and design. Thus, this research aims to study and determine the demands of road and urban passenger transport drivers in relation to bus cockpits, in order to propose improvements considering the characteristics of the task and the opinion of the drivers regarding their comfort and performance. The study included an urban and a road passenger transport companie. The methodology was structured in three phases. The first one (Preanalysis) had as objective to know the cockpits of the buses, to understand the requirements considered in the purchase of new vehicles and to understand the conditions of the cockpit that act in the dirigibility of the vehicle. The second phase (Analysis) was to investigate the drivers' perception regarding the cockpits of the buses through in loco observation, filming, interviews, questionnaire and paper prototype dynamics In the third phase (Post-analysis) the triangulation of the data was performed to identify the most relevant comfort factors and the results of the two groups of drivers were compared. The results of the dynamics converged with those of the interviews and questionnaires showing that, in general, drivers tend to keep the controls in the places they have become used to, modifying only the positioning of those who do not meet their needs. The main demand of road transport drivers is linked to the positioning of the air conditioning control in the cockpit and the conditions of thermal comfort in the cabin. Passenger urban transport drivers, on the other hand, want the itinerary Command relocate to a location within easy reach and visibility when in the sitting position. They also reported thermal discomfort relating to the absence of ventarola device, since most vehicle do not have air conditioning. The two groups of drivers indicated the need to improve the visibility of the instrument panel which is sometimes hampered by poor steering positioning. In addition, the two groups of drivers considered the interior space of the cabin, the noise as well as the comfort of the seat, features to be improved.
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Methods for Validatng Cockpit Design The best tool for the taskSinger, Gideon January 2002 (has links)
No description available.
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Design of Collaborative Systems for Modern CockpitsMcKay, Paul January 2009 (has links)
One of the most significant developments in cockpit technology over the past several years is the emergence of a new cockpit architecture that uses cursor control devices and keyboards for interaction with individual and shared displays. This architecture has allowed for the design of cockpit interfaces with many advantages compared to traditional designs. However, there are a number of challenges associated with these new cockpits that should be addressed so that pilots will be able to take full advantage of the performance improvements available from the new designs.
This thesis describes three of the major challenges associated with the new architecture: supporting awareness, assisting interruption recovery, and mitigating interaction conflicts. It also describes the analysis process used to identify these challenges and proposes an interface augmentation with the potential to address them. The proposed design uses visualizations of the history of operator interactions with the interface to provide cues to the pilots about where each of them has been (and is currently) interacting. This interaction data includes both visual (sourced from a gaze tracking system) and input (from the keyboard or cursor control device) information, and was communicated on the interface using dynamic borders around the relevant areas of the interface. This augmentation aimed to address the three identified challenges by providing pilots with: improved awareness of each other’s actions, visual cues of where they were working prior to an interruption and what has changed since, and clear indications of where each is working to allow them to avoid conflicts.
A two-stage evaluation process was used to determine the utility of the interface concept in a cockpit context by developing a non-interactive video prototype and showing it to pilots. The results of the evaluation indicated that the design has sufficient potential to warrant further study, as evaluation in higher fidelity environments would help provide further evidence of its potential utility for live cockpit operations. Therefore, future work should include the development and evaluation of a fully interactive prototype for live cockpit operations, as well as further examination of the design concept’s potential for use as a training tool.
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