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ISO 15288

( Duration: 3 Days )

ISO 15288 is a system engineering standard covering processes and lifecycle stages. It defines a set of processes and associated terminology from an engineering viewpoint. These processes can be applied at any level in the hierarchy of a system’s structure.

In ISO 15288 training course, you will learn to use ISO/IEC/IEEE8 15288 standard, "Systems and Software Engineering–System Life Cycle Processes" for use by acquisition and system projects. This course will cover how ISO/IEC/IEEE8 15288 standard establishes a common process framework for describing the life cycle of man-made systems and defines a set of systems engineering (SE) processes and associated terminology typical for the full system life cycle, including conception, development, production, utilization, support, and retirement.

By attending ISO 15288 workshop, delegates will learn:

  • Life cycle framework to perform systems and software tasks/activities in an organized disciplined manner
  • Process framework that can be tailored to suit
  • Framework that can reduce risk
  • Framework for achieving customer expectations

The ISO 15288 class is ideal for:

  • System and Software Engineers, Project Managers, Enterprise Architects, QA, Reliability, Safety, V&V, and anyone else involved in system engineering and system development processes.

COURSE AGENDA

1

Foundation of Systems and Software Engineering

  • Foundations of Systems Engineering
  • Systems Engineering and Management
  • Applications of Systems Engineering
  • Overview of Systems Engineering Frameworks
  • ISO/IEC 15288, NASA SE, DoD SE, INCOSE Certifications
  • Enabling Systems Engineering
  • Related Disciplines
  • Systems Engineering Implementation Examples
  • Emerging Knowledge
2

Applying the Systems Approach

  • Systems Approaches
  • Systems Thinking
  • Systems Thinking Foundation
  • Concepts of Systems Thinking
  • Principles of Systems Thinking
  • Patterns of Systems Thinking
  • Engineered System Context
  • Identifying and Understanding Problems and Opportunities
  • Synthesizing Possible Solutions
  • Analysis and Selection between Alternative Solutions
  • Implementing and Proving a Solution
  • Deploying, Using, and Sustaining Systems to Solve Problems
3

Systems Engineering and Management

  • Introduction to Life Cycle Processes
  • System Life Cycle Process Drivers and Choices
  • Integration of Process and Product Models
  • Lean Engineering
  • Business or Mission Analysis
  • Mission Engineering
  • Planning
  • Assessment and Control
  • Risk Management
  • Measurement
  • Decision Management
  • Configuration Management
  • Information Management
  • Quality Management
  • Product and Service Life Management
  • Developing Systems Engineering Capabilities within Businesses and Enterprises
  • Culture
  • Enabling Teams
  • Enabling Individuals
  • Roles and Competencies
  • Ethical Behavior
  • Reliability, Availability, and Maintainability
  • Human Systems Integration
  • Safety Engineering
  • Security Engineering
  • Electromagnetic Interference/Electromagnetic Compatibility
  • System Resilience
  • Manufacturability and Producibility
4

Applying the Systems Approach

  • Systems Approaches
  • Systems Thinking
  • Systems Thinking Foundation
  • Concepts of Systems Thinking
  • Principles of Systems Thinking
  • Patterns of Systems Thinking
  • Engineered System Context
  • Identifying and Understanding Problems and Opportunities
  • Synthesizing Possible Solutions
  • Analysis and Selection between Alternative Solutions
  • Implementing and Proving a Solution
  • Deploying, Using, and Sustaining Systems to Solve Problems
5

Foundations of Model Based Systems Engineering (MBSE) and SysML (System Modeling Language)

  • Introduction to System Modeling
  • Representing Systems with Models
  • What is a Model?
  • Why Model?
  • Overview of the Systems Approach with MBSE
  • Types of Models
  • System Modeling Concepts
  • Integrating Supporting Aspects into System Models
  • Modeling Standards
6

Foundations of Model Based Systems Engineering (MBSE) and SysML (System Modeling Language)

  • Introduction to System Modeling
  • Representing Systems with Models
  • What is a Model?
  • Why Model?
  • Overview of the Systems Approach with MBSE
  • Types of Models
  • System Modeling Concepts
  • Integrating Supporting Aspects into System Models
  • Modeling Standards
7

Foundation of ISO/IEC 15288

  • Overview of ISO/IEC 15288 framework
  • Primary lifecycle processes
  • Process input, enablers, constraints, activities, and output
  • Technical, Project, Agreement and Enterprise processes
  • The supporting processes
  • Agreement Processes: Acquisition and Supply
  • Technical Management Processes: Project Planning, Project Assessment and Control, Decision Management, Risk Management, Configuration Management, Information Management, Measurement and Quality Assurance
  • Technical Processes: Business or Mission Analysis
  • Stakeholder Needs and Requirements Definition, System Requirements Definition, Architecture Definition, Design Definition, System Analysis, Implementation, Integration, Verification, Transition, Validation, Operation, Maintenance, Disposal
  • Organizational Project-Enabling Processes: Life Cycle Model Management, Infrastructure Management, Portfolio Management, Human Resource Management,, Quality Management, and Knowledge Management
8

Tailoring ISO/IEC/IEEE 15288

  • Project Characteristics That May Drive Tailoring
  • Project Characteristic Sub-Characteristics
  • \Life-cycle considerations
  • Acquisition life cycle phases covered
  • Mission application
  • Mission criticality (“-ilities” required; domain regulations)
  • Number of deployment sites / environments
  • Design for reusability
  • Organizational complexity
  • Reuse of existing components or intellectual property
  • Staff experience, capability, size, and skills needed
  • Technical complexity
  • Number of requirements
  • Number of system external interfaces
  • Number of different types of users
  • Number of system elements / internal interfaces /architectural levels
  • Number of KPPs
  • Total development cost
  • Risk , System precedence and technology availability
  • Technology obsolescence
  • Integration of the technology
  • Programmatic / external risk
  • Sustainment / disposal risk
  • Manufacturing / supply chain risk
  • Technical understanding
  • Requirements understanding
  • Architecture understanding
  • Emergence likelihood
9

Workshop: Applying Systems Engineering and ISO/IEC/IEEE 15288

  • Analysis and Selection between Alternative Solutions
  • Synthesizing Possible Solutions
  • Systems Engineering and Management
  • System Life Cycle Process Models: Vee
  • System Definition
  • Business or Mission Analysis
  • System Requirements
  • Logical Architecture Model Development
  • System Realization
  • System Implementation
  • System Verification
  • System Deployment
  • Operation of the System
  • System Maintenance
  • Planning
  • Configuration Management
  • Information Management
  • Integration of Process and Product Models
  • Logical Architecture Model Development
  • System Validation

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