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OUTLINE 

Mission Integration and Execution

• Mission Operations – The formation of a tightly integrated, efficient, and effective operational team
• Principles of Mission Control – Foundations for values, culture and teamwork
• Plan, Train, Fly – The process of flight operations
• Cultural Integration – Local, Regional, Global
• Fundamentals of Flight Operations – Case studies and lessons learned
• Human Factors
• Spaceflight Resource Management
• Team Interactions and Interdependency
• Philosophy of Failure and Redundancy Management
• Guidance for Future Mission Control Centers

• The Evolution of Mission Engineering – Mercury through Space Shuttle and ISS
• A Bridge between the Designers and Mission Control
• Assumptions, Constraints and Operational Limits
• Simplified Analysis
• Time Scales of Solution Engineering
• Levels of Awareness
• The Importance of Data
• Lessons Learned for Future Missions

• Power Systems for Spacecraft – History and evolution
• Power System Elements and Design
• Power System Architectures – ISS as most complex example to date.
• Sizing, Degradation, Operational Constraints
• Power Operations – Monitoring and system Interactions
• Malfunction Analysis and Criticality of Data
• Failure Modes and Redundancy
• Practical Examples and Case Studies

• The Evolution of Life Support Systems
• Crew Support Requirements
• Atmosphere Control and Supply
• Atmosphere Revitalization
• Fire Detection and Suppression
• Temperature and Humidity Control
• Water Recovery and Management
• Regenerative Life Support
• Failure Management and Emergencies

• The Evolution of Space Communications
• Communication Theory and Applications
• Command and Data Handling Systems and Processes
• Space Shuttle and ISS C3 Systems
• Crew Control, Monitoring and Command Interfaces
• Space C3 Lessons Learned
• The Future of C3

• The Thermal Environment of Space
• Thermal Control - Background Theory (Conduction, Convection, Radiation)
• Elements of a Spacecraft Thermal Systems – Active and Passive Thermal Devices
• Thermal Control Operations—Mission Control and On-Orbit
• Support and Interactions with Other Systems
• Failure Modes, Redundancy and Malfunction Response
• Practical Examples and Case Studies

• Trajectory Design from Gemini through Apollo and Shuttle/ISS
• Orbital Mechanics Concepts – Time systems, Coordinate systems, orbital elements, 2-body equations, perturbations, propagation methods, spacecraft attitude, maneuvers.
• Spacecraft Navigation
• Launch Windows
• Collision Avoidance
• Burn Targeting Operations
• Rendezvous Strategies
• Mission Monitoring and Analysis Tools
• Off-Nominal Scenarios
• Lessons for Future Missions

• Architecture of GNC Systems
• Development and Operations of Navigation (Position and Attitude) Sensors
• State Vector Determination
• Ascent and Entry Navigation
• Fault Detection Isolation & Recovery (FDIR)
• Powered Flight Guidance Systems - Ascent Guidance and Aborts
• Entry Guidance – Capsules vs Space Shuttle
• Spacecraft Control Systems
• Propulsive vs Gyro Attitude Control
• Control/Structure Interactions
• Manual Control Modes - Requirements for Human Rated Spacecraft
• Hand Controllers and Handling Qualities
• Propulsion Systems
• Thrusters
• Orbital Maneuvers, Attitude Maneuvers
• Propellant Gauging and Management
• Case Studies and Lessons Learned

• History and Evolution of Extravehicular Activity
• Spacesuit Systems and Design Considerations
• Airlock Operations and Pre-Breathe Protocols
• EVA Tools, Equipment, Interfaces
• EVA Training and Facilities – Neutral Buoyancy, Zero-G, Virtual Reality
• Mission EVA Development
• New Challenges for the Spacewalks of the Future – Moon & Mars
• Case Studies and Lessons Learned

• Types of Space Robotics – Probes, Landers, Manipulators
• Challenges of Space vs Terrestrial Robots
• Design of Robotic Systems – Space Shuttle and ISS Systems
• Principles of Space Manipulators
• Work envelope, singularities, joint limits, self-collision
• Reference frames
• Forward-Inverse kinematics
• Modes of Operation – Automatic, Manual
• Failure Management and Response – Redundancy and fault tolerance
• Operational Considerations and Tools – Trajectory planning
• ISS Robotic Operations – Capture, Contingency Procedures, EVA Support
• Team Coordination – Ground and crew communication
• Training and Facilities – Preflight crew and ground, onboard currency
• Lessons Learned and Future Robotic Operations

• Evolution of Payload Operations – Skylab, Spacelab, Space Shuttle and ISS
• ISS Timeline—From the Perspective of Payload Operations
• ISS - A One-of-a-Kind Research Facility
• Scope of Onboard Science - Facilities and Capabilities
• Payload Operations Integration
• Strategic, Tactical and Operational Phases
• Development, installation, operations, analysis
• Payload Operations Case Studies and Lessons Learned
• Science and Research Operations in the Future

• Astronaut Health
• Space Physiology – Launch, Microgravity, Landing
• Space Motion Sickness, Cardiovascular Effects, Musculoskeletal
• Neurovestibular, Radiation, Toxicology, Immunology, Microbiology, Nutrition
• Spaceflight-Associated Neuro-Ocular Syndrome (SANS)
• Medical Aspects of Spacewalking (EVA)
• Barotrauma, Decompression Sickness
• Evolution of Pre-Breathe Protocols
• The Suit vs Astronaut – Musculoskeletal Injuries, Nutrition, Hydration, Waste
• Physiology of Return to Gravity
• Historical Medical Events
• Medical Preparedness – Biomedical Team, Crew Training, Onboard Equipment
• Landing Support
• Future Space Medicine – Altered gravity, isolation, hostile environments, radiation, and distance from Earth

• Skylab 4 Case Study – Early Lessons Learned for Mission Planning
• Elements of Mission Planning
• Team Dynamics – Systems, Priorities, Organizations, Countries
• Mission Planning Evolution from Mercury through ISS
• Mission Planning and Project Management
• Short and Long Duration Missions
• Managing Rules, Limitations and Constraints
• Plan Development Cycle
• US vs Russian Approaches to Planning
• A Day in the Life of ISS
• Mission Planning Lessons Learned
• The Future of Mission Planning

• The Columbia Accident - Case Study and Lessons Learned
• Spaceflight Safety
• Defining Safety and Risk – Causes of Accidents
• Learning from Human Spaceflight Accidents
• Responses to Perceived Risk – Continuous Risk Management
• Engineering Changes
• Revised Regulations or Rules
• Improving Human Behavior – Crew Resource Management
• Improving Organizational Structure
• Risk Analysis – Likelihood vs Consequences Risk Matrix
• Hazard Analysis and Control
• Where is Human Spaceflight Now?
• Safety Recommendations for Future Spaceflight Operations

• Evolution of the Kennedy Space Center
• Space Shuttle Ground Processing and Operations
• The Space Station Processing Facility (SSPF)
• Launch Pad Workflow
• Landing Operations
• Case Studies and Lessons Learned
• A Spaceport for the Future

• A Brief History of Astronauts from the Mercury 7 to the Present
• Spaceflight Training and Facilities – Short vs Long Duration Missions
• Dynamic Flight – Launch, Rendezvous and Entry
• Living and Working in Space – Arrival, Operations, Habitability, Crew Systems, Food
• On-Orbit Operations and Lessons Learned
• Installation, Maintenance and Repair
• Onboard Equipment and Tools
• Inventory and Stowage
• Alarms and Emergencies
• Maintaining Mental and Physical Health
• Crew Efficiency
• Lessons Learned for Future Missions