• Systems engineering processes and principles for avionics system design
• Developing overall and subsystem architectures
• Evaluation and determination of risks, safety and trade studies
• Development of avionics system requirements
• Design techniques for satellite avionics systems
• Emerging technologies for the future

AUDIENCE
Satellite and launch vehicle systems engineers, avionics subsystem designers, managers, business development personnel, system safety engineers, risk engineers and managers, electrical ground support equipment engineers, integration and test engineers, and environmental test engineers. Technologists who wish to expand their knowledge base in spacecraft subsystems. Systems engineers who need to know how the avionics system fits into the overall satellite operational makeup. Program managers needing more data on current developments in spacecraft technologies. Educators who teach related satellite topics at the university level. In summary, this is a must course if you are an engineer or hands-on manager in system engineering, electronic component design and integration and test.

MATERIALS: All course slides and additional references will be available for immediate download. Stream the 15 hours of video recordings anytime, 24/7. No part of these materials may be reproduced, distributed, or transmitted, unless for course participants. All rights reserved.

CERTIFICATE: Receive an AIAA Course Completion Certificate upon viewing all course recordings. Please contact Lisa Le for a certificate.

COURSE FEES (Sign-In To Register)
- AIAA Member Price: $895 USD
- Non-Member Price: $1,095 USD
- AIAA Student Member Price: $495 USD

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OUTLINE

1. Definitions. Fundamental definitions and terms for spacecraft avionics systems and subsystems.
   
   
2. Systems Engineering Process. Exploration of the classic systems engineering “V” process and how it is applied at the mission, systems and subsystem levels, for both spacecraft and instrument to deliver a system that meets stakeholder expectations.
• Systems Requirements: Starting at the customer/stakeholder level 1, allocating down to Level 2, performing trade studies within levels 1 & 2 refining the mission requirements for optimum level 2 requirements. Allocating requirements to level 3 with trade studies refining level 2 & 3 for optimum spacecraft and/or instrument architecture. Further requirements allocation and derivation, requirements management, verification and validation. Using the Concept of Operations to further refine Level 1 & 2 requirements.
• Requirements documentation: Generating the Program/Project level documentation.
• Mission Assurance: Correlation of the radiation environment and radiation analysis, risks and safety assessments to the importance of system and subsystem architectures and requirements.
  
  
3. Scheduling. Understanding the scheduling process from Program/Project Milestones, to mission, to system, to subsystem levels. The correct allocation, linking and resource loading too enable successful program execution and cost control.
   
   
4. Costing. Understand how costing your activity is closely coupled to the scheduling, requirements, verification and validation processes.
   
   
5. System Architecture. How high-level trade studies, requirements, requirements verification, and mission validation process lead to a concise system level architecture; allocation to subsystem level requirements and architecture, derivation and linking back to mission level 1 requirements.
   
   
6. Testing. How testing to lower level requirements leads to higher-level verification and mission validation. The overall test flow and pitfalls. Electronic ground support equipment for board-to-box-to-system level and environmental testing-to-operations.
   
   
7. Subsystem Level Architecture. In-depth subsystem level architecture for Guidance, Navigation and Control (GN&C), Command and Data Handling (C&DH) including Flight Software (FSW), RF Communications (RF Comm), Electrical Power (EPS) and Propulsion (Prop).