Principles of Systems Engineering

1 The Context of Systems Engineering – From Organization to Project level: The need for Systems Engineering from an organizational point of view. These processes help ensure the organization’s capability to realize a system through the initiation, support and control of projects by providing resources and infrastructure.

• 1.1 Introduction to Systems Engineering: Identify what a system is and how systems engineering is used to create them.INCOSE SE Handbook and SE Standard – ISO/IEC/IEEE 15288:2015;  concept of the System Life Cycle Model. Processes covered: 7.1 Life Cycle Model Management and 8.0 Tailoring
• 1.2 Organizational Processes – Project-Enabling and Agreements: Identify the processes an Organization needs to use in order to create and resource a project.  Processes covered:  7.3 Portfolio Management; 7.5 Quality Management; 7.6 Knowledge Management; 7.2 Infrastructure Management; 7.4 Human Resource Management; 6.1 Acquisition; 6.2 Supply

2 Requirements: From Stakeholder to System: Analyze mission needs and then transform this stakeholder, user-oriented view of desired capabilities into a technical view of a solution that meets the operational needs of the user.

• 2.1 Mission and Stakeholder Requirements: Analyze mission needs and document stakeholder, user-oriented view of desired capabilities.  Processes covered: 4.1 Business or Mission Analysis; 4.2 Stakeholder Needs and Requirements Definition; Life Cycle Concepts; Characteristics of Good Requirements
• 2.2 System and Interface Requirements: Transform stakeholder desired capabilities into a technical view of a solution that meets the operational needs of the user.  Processes covered: 9.3 Functions-Based Systems Engineering Method; 4.3 System Requirements Definition; 4.4 Architecture Definition; 9.6 Interface Management; 4.5 Design Definition

3 Design Considerations: While considering the system design, the Systems Engineer needs to address specialized engineering areas, and consult Subject Matter Experts  and assign them, as appropriate, to conduct specialty engineering analysis.

• 3.1 Specialty Engineering Activities Part 1: Design impact from Cost, Electromagnetic, Environmental, Interoperability and Logistics concerns.  HDBK Sections covered: 10.1 Affordability/Cost-Effectiveness/Life Cycle Cost Analysis; 10.2 Electromagnetic Compatibility; 10.3 Environmental Engineering Impact Analysis; 10.4 Interoperability Analysis; 10.5 Logistics Engineering;
• 3.2 Specialty Engineering Activities Part 2: Design impact from Manufacturing, Mass, RAM, Resilience, Safety, Security, Training and HSI concerns.  HDBK Sections covered: 10.6 Manufacturing and Producibility Analysis; 10.7 Mass Properties Engineering; 10.8 Reliability, Availability, and Maintainability; 10.9 Resilience Engineering; 10.10 System Safety Engineering; 10.11 System Security Engineering; 10.12 Training Needs Analyses; 10.13 Usability Analysis/Human Systems Integration

4 Technical Processes – From Element Design to Disposal: Designing and then realizing the specified system elements that make up the solution, then integrating them together, and ensuring the completed system fulfills its specified requirements characteristics and mission. Deploy and sustain the system within its operational environment. When use is no longer required, dispose the system properly.

• 4.1 Implementation to Verification: Understand the processes for realizing the specified system elements that make up the solution, then integrating them together, and ensuring the completed system was built right.   Processes covered:  4.7 Implementation; 4.8 Integration; 4.9 Verification
• 4.2 Transition to Disposal: Understand the processes for ensuring the right system was built to fulfills its mission, that the system is deployed, operated and sustained within its operational environment, and eventually disposed of properly.Processes covered: 4.1 Transition; 4.11 Validation; 4.12 Operation; 4.13 Maintenance; 4.14 Disposal