Systems Engineering

The systematic process of eliciting, analyzing, documenting, validating, and managing the needs and requirements of stakeholders for a system. Requirements define what the system must do (functional) and how well it must perform (non-functional).

The conceptual model that defines the structure, behavior, and views of a system. It identifies the major components (subsystems), their interfaces, and how they interact to fulfill system requirements.

Verification asks 'Are we building the system right?' (confirming the system meets specifications). Validation asks 'Are we building the right system?' (confirming the system meets stakeholder needs). Together, V&V ensure quality and fitness for purpose.

A systems development lifecycle model that maps each development phase (requirements, design, implementation) to a corresponding testing phase (acceptance testing, integration testing, unit testing), forming a V shape that emphasizes verification and validation at every level.

The identification, definition, documentation, and control of the physical and functional interfaces between system elements and between the system and its environment. Poor interface management is a leading cause of system integration failures.

A structured methodology for evaluating alternative solutions against a set of weighted criteria to select the best approach when competing requirements or constraints exist. Trade studies balance performance, cost, risk, schedule, and other factors.

The process of identifying, controlling, tracking, and auditing the versions and changes to all system artifacts (requirements, designs, hardware, software, documentation) throughout the system lifecycle.

The formalized application of modeling to support system requirements, design, analysis, verification, and validation activities from conceptual design through development and later lifecycle phases, replacing document-centric approaches.

The complete set of phases a system passes through from initial concept and development through production, operation, maintenance, and eventual retirement and disposal. Systems engineering manages the system across all lifecycle stages.

The systematic identification, assessment, prioritization, and mitigation of risks that could affect system performance, cost, or schedule. Risk is typically characterized by the probability of occurrence and the severity of impact.