Prepares students who desire careers as professional pilots. Emphasizes complete ground tutoring and flight instruction relating to instrument maneuvers, SOP's, regulation interpretation, pilot discipline, and professional procedures. Crew resource management, LOFT, and turbine-transition flights in an advanced jet flight simulator are used. This course is taken in conjunction in the same semester as AVIA 450.

Prerequisites:

AVIA 253

This is a stand-alone course designed for the person who is not an MSU aviation major. The course offers a complete jet aircraft transition training program.

The fundamental principles and calculation of the performance in various phases of flight: takeoff and land, climb and descent performance, maximum-range and maximum-endurance cruise, single-engine performance in multi-engine aircraft, standard atmosphere and basic subsonic and supersonic aerodynamics is covered.

Prerequisites:

AVIA 338

Covers aeromedical factors that are essential for high-altitude flying aircraft. Hypoxia, hyperventilation, dysbarism, basic gas laws. Armstrong line, vision in flight, day and night. Pressurization systems, pressurized suits, danger of loss of cabin pressure, future HSCT and LEO commerical flights.

This course will provide the student with knowledge of advanced UAS operations to include a mapping project from proposal through implementation to completion. It will identify security requirements and develop threat models and risk assessment.

Prerequisites:

CIS 350, AVIA 375

This course will review and expand on knowledge that has been taught in the program. The student will demonstrate UAS concepts with a meaningful research project using the skills and knowledge learned from the program. They will apply these skills to real world scenarios.

Prerequisites:

AVIA 470

.

Supervised experience in business, industry, state or federal institutions.

Allows the student an individual course of study on an aviation topic to be arranged with the department.

This course provides students with a basic understanding of the general principles and concepts of safety and helps students develop a safety conscience. It is designed to help students better understand the role of safety in aviation and how these general principles and concepts relate to various roles within the aviation industry. Emphasis is placed on managing safety through regulatory guidelines, industry initiatives, and airline crew operations.

This course studies the role of humans in all aspects of the aviation industry. It is intended to provide students with a solid understanding of human factors concepts, principles, issues, solutions, and needs. Applications of these concepts are demonstrated in different aviation domains (e.g., cockpit, ATC, aviation maintenance). The course explores the effective interactions among people who work across organizational, geographical, temporal, and cultural boundaries, as a means to design effective socio-technical systems.

This course deals with the scheduled performance planning of multi-engine transport-category (Part 25) airplanes in commercial air transportation. Airplane performance theory and operational and structural limitations are reviewed. Maximum aircraft masses/weights are computed utilizing inverse mathematical methods before each takeoff so that performance margins specified in Part121 flight safety rules are unlikely to be exceeded in any phase of flight assuming sudden engine(s) failures. Measured, gross, and net performances are evaluated for various environmental and flightpath conditions. A fine balance between the required flight safety margins and the economy of air transportation is established based on the severity and the probability of failures.

This course focuses on Safety Management Systems (SMS). Students will acquire a foundation of four components in SMS (safety policy, safety risk management, safety assurance, and safety promotion) and learn how to design, develop, and implement SMS in an aviation organization to manage organizational safety and prevent organizational accidents.

This course covers several major proactive safety programs monitored by FAA and NASA, such as the Flight Operations Quality Assurance (FOQA) and the Aviation Safety Action Plan (ASAP). Programs used by air carriers, such as the Advanced Qualification Program (AQP) and the Line Operations Safety Audit (LOSA), are discussed. Additional organizational safety programs include: Fatigue Risk Management Plan (FRMP), Internal Evaluation Program (IEP), and Voluntary Disclosure Reporting Program (VDRP).

This course is designed to teach students the fundamentals required to conduct an aviation accident investigation. It covers all aspects of the aircraft accident investigation process, from pre-planning to report writing and follow-up work designed to avoid similar or related aircraft accidents. Students will learn how to collect, preserve, and reconstruct accident scene data, explore methods for determining probable causes, and discover solutions to problems faced during accident investigations.

This course includes a series of case studies that illustrate the role of humans, software, hardware, and the environment in the failure of simple and complex systems. The case studies are drawn from many domains, including flight operations, ATC, maintenance, and airport operations. Students are given the opportunity to use system analysis techniques to evaluate common failure modes and explore the conditions conducive to system success or failure.

This course is designed to equip students with techniques and skills to identify research problems, and apply appropriate qualitative and quantitative research methods to solve research problems in the aviation field. The course develops students¿ understanding of research questions, literature review, methodology, and reporting results, recommendations, and conclusions.

This course exposes students to the latest research in the aviation safety area. Current aviation safety problems encountered by an aviation professional working in the industry are identified, analyzed, interpreted, and solved. The course requires students to review and synthesize literature, critically analyze data by using quantitative or qualitative research methods, present research findings, and propose recommendations for industry practitioners.

This course is designed to increase students' knowledge of disaster preparedness and emergency response procedures and practices in both government and private organizations. It includes thorough coverage of all phases of the emergency management discipline, including preparedness, mitigation, response, and post-emergency recovery operations. Theory, practices, and techniques utilized in the response phase of aircraft crashes and emergencies are examined. Additional topics include elements of an emergency response plan, training requirements, the incident command system, and essential human services and support.

This course reviews the development and implementation of the system safety discipline in numerous industries, especially aviation. This course emphasizes the utilization of safety resources in all phases of the life cycle of a given system. Topics include quantitative and qualitative techniques and tools for system analysis applied to accident prevention, analysis, and mitigation.

The course covers the design, development, implementation, and evaluation of aviation training programs, from effective training materials to training methods for a given situation. In addition, this course equips students with the knowledge and skills to be the next generation of leaders in the air transportation industry. The course is designed to help students better understand the importance of diversity, equity, and inclusion as team leaders.

This course explores ethical issues and practical ways of resolving moral conflict and promoting ethical behavior in the aviation community. Since best practices in any workplace require making good decisions, the role of ethics, diversity, equity, and inclusion in good decision-making on personal, organizational, and social levels will be discussed.

This course addresses the application of safety management principles and techniques to air transportation operations. Topics include flight operation safety, cabin safety, ground safety, transportation of dangerous goods, and organizational safety culture promotion. FAA regulatory requirements and industry standards are included throughout the course. Students will gain complete and updated knowledge of the current safety management issues and best practices for air transportation.

This course covers aviation maintenance safety policies, procedures, and practices in use throughout the aviation industry. The course develops students¿ understanding of the influence and role of the regulatory agencies in aviation maintenance safety, the role of maintenance safety in relation to the overall safety management program in an organization, and mechanics¿ safety responsibilities in their areas of operation.

This course introduces students to both commercial and generation aviation airport operational safety and security. The course focuses on compliance with regulations as they pertain to airport operations and the best practices that can be implemented in the airport environment. Specific topics include: airport certification, airport emergency plan (AEP), airport rescue and fire fighting, runway safety, wildlife management, winter operations, ground vehicle operations, airport threats, and security measures, security-related incidents response and departmental cooperation. Students will learn how to plan, coordinate, implement, and monitor preventive security measures at airports.