Flight Gear Simulation System: Outline Submission

profilea7med89
4.3FlightGearSimulationSystem.docx

Flight Gear Simulation System

4.3 Field Study and Evaluation: Outline Submission

In this assignment you will complete an outline of your study and identify potential references. View the suggested sections of your study below. (Note: these may be edited and rearranged to fit the needs of your study).

Each heading and subheading should have a brief description of the expected content. For example, under the Simulation Description heading below, view the sample annotation.

General Sections for Evaluation Outline

· Abstract

· Introduction

· Simulation Description

· (Sample annotation): Description of the Real-Flight X simulation, how the interface works, what aircraft are available, and the various training and racing modes.

· Methodology

· Evaluation - this section may include subsections of:

· Fidelity

· Performance

· Strengths & Limitations

· User Interface

· Transfer of Training

· Cost Effectiveness

· Applications for Training

· Or any other subsection you deem necessary

· Recommendations

· Conclusion

· References

Rubric

SECTION DESCRIPTION. The outline provides the section headings and adequate detail (1-2 sentences) to explain the contribution and it meets the specified requirements.

SOURCES. The type of references that will be used and examples are provided. The variety of sources clearly relate to the simulation or its function and will contribute to the depth of the evaluation. The currency (publication date), variety (primary and secondary), primacy (jurried & seminal), and number of documented sources meet the assignment requirements.

FORMAT. The outline includes a title page with the working title of the manuscript, full names of the author(s), course title and institution byline, and submission date. The outline is written in APA format with proper section titles.

Helpful resoues:

hang, H. M., & Li, L. (2013). A flight evaluating system using flight gear. Applied Mechanics and Materials, 347-350, 891. doi:http://dx.doi.org.ezproxy.libproxy.db.erau.edu/10.4028/www.scientific.net/AMM.347-350.891

https://apps.dtic.mil/dtic/tr/fulltext/u2/a303799.pdf

https://www.sciencedirect.com/science/article/pii/S1658361215000141

Cereceda, O., Rolland, L., & O’Young, S. (2019). Giant big stik r/c uav computer model development in jsbsim for sense and avoid applications. Drones3(2), 48.

Ganoni, O., & Mukundan, R. (2017). A framework for visually realistic multi-robot simulation in a natural environment. arXiv preprint arXiv:1708.01938.

Larsen, A. H., Mortensen, J. J., Blomqvist, J., Castelli, I. E., Christensen, R., Dułak, M., ... & Hermes, E. D. (2017). The atomic simulation environment—a Python library for working with atoms. Journal of Physics: Condensed Matter29(27), 273002.

Mairaj, A., Baba, A. I., & Javaid, A. Y. (2019). Application specific drone simulators: Recent advances and challenges. Simulation Modelling Practice and Theory94, 100-117.