MBSE Training Crash Course covers all the principals, theories, and techniques associated with Model-based Systems Engineering (MBSE). Model-based systems engineering (MBSE) is the formal use of modeling to provide system requirements, design, analysis, and verification and validation activities. Such activities initiate in the conceptual design stage and continue throughout development and later life cycle phases.
#MBSE Goals
Improved communications
With stakeholders
Within the engineering project teams
Across spoken language barriers
Improved quality
Early identification of requirements issues
Enhanced system design integrity
Improved specification of allocated requirements to hardware and software
Fewer errors during integration and testing
More rigorous requirements traceability
Consistent documentation
Increased productivity
#Audience
MBSE training crash course is a 4-day training designed for:
Product manager
Project director
R and D manager
Engineering manager
Systems engineer
Capability developer
Business analyst
Systems analyst
System architect
Enterprise architect
Software systems engineer
Software engineer
Design engineer
Hardware engineer
Project engineer
LSA specialist
Industrial engineer
#Training Objectives
Upon completion of MBSE training crash course, the attendees are able to:
Comprehend the general principals of systems engineering
Discuss the main characteristic of a system
Understand the overall process factors, and their relationships, which together establish the bases of systems engineering
Relate the roles of developer as supplier, developer as creator and developer as acquirer, and to position their own roles, and those of their customers (internal and external) and suppliers (internal and external) within this framework
Perform the fundamentals of some of the more important techniques of system requirements analysis, development of physical solution, development of logical solution, evaluation of solution alternatives (trade-off studies) and design iteration
Discuss the principles and major techniques of engineering management in a systems project context
Learn more about MBSE Training
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1. MBSE Training Crash Course
tonex.com/training-courses/mbse-training-crash-course/
Price: $3,999.90
Length: 4 Days
MBSE Training Crash Course Description
MBSE Training Crash Course covers all the principals, theories, and techniques associated
with Model-based Systems Engineering (MBSE).
Model-based systems engineering (MBSE) is the formal use of modeling to provide system
requirements, design, analysis, and verification and validation activities. Such activities
initiate in the conceptual design stage and continue throughout development and later life
cycle phases.
A model often provides various perspectives to serve different purposes.
MBSE Goals
Improved communications
With stakeholders
Within the engineering project teams
Across spoken language barriers
Improved quality
Early identification of requirements issues
Enhanced system design integrity
Improved specification of allocated requirements to hardware and software
Fewer errors during integration and testing
More rigorous requirements traceability
Consistent documentation
Increased productivity
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2. Improved impact analysis of requirements changes
Improved interaction across a multi discipline team
Reuse of existing models to support design and technology evolution
Auto-generation of documentation
Reduced risk
Improved cost estimates
Early, and on-going, requirements validation and design verification
MBSE Techniques and Tools
Structured analysis and design
Data flow diagramming
State transition diagramming
Behavioral modeling
Entity relationship modeling
Finite element modeling
Environment virtualization
Computer Aided Design (CAD)
Analytical modeling
Process modeling
System Model
Requirements
Behavior
Structure
Properties
Interconnections
Audience
MBSE training crash course is a 4-day training designed for:
Product manager
Project director
R and D manager
Engineering manager
Systems engineer
Capability developer
Business analyst
Systems analyst
System architect
Enterprise architect
Software systems engineer
Software engineer
Design engineer
Hardware engineer
Project engineer
LSA specialist
2/6
3. Industrial engineer
Training Objectives
Upon completion of MBSE training crash course, the attendees are able to:
Comprehend the general principals of systems engineering
Discuss the main characteristic of a system
Understand the overall process factors, and their relationships, which together
establish the bases of systems engineering
Relate the roles of developer as supplier, developer as creator and developer as
acquirer, and to position their own roles, and those of their customers (internal and
external) and suppliers (internal and external) within this framework
Perform the fundamentals of some of the more important techniques of system
requirements analysis, development of physical solution, development of logical
solution, evaluation of solution alternatives (trade-off studies) and design iteration
Discuss the principles and major techniques of engineering management in a
systems project context
Demonstrate the fundamental skills to adjust the use of the systems engineering
concepts and methods to different application scenarios
Explain the concepts and rational behind MBSE, and how it compares to traditional
SE
Describe overall benefits of MBSE
Explain the application of MBSE in the industry
Comprehend SysML and that how it supports MBSE
Explain how MBSE methods are used to specify and design systems
Explain how an organization can transition to MBSE?
Course Outline
Overview
What is a system
Systems thinking
Applying systems thinking to systems design
What is systems engineering?
Multidisciplinary technique
Problem classes
The design space: three systems
The design space: boundaries
The process
Domains
Communication
The System Life Cycle and Solution Development
The solution domain: key concepts, relationships, information types and work
products, MBSE
OCD/CONOPS/OSD/ADD issues
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4. Architectural frameworks
Impact of problem definition and stakeholder satisfaction
Systems of systems engineering
Waterfall, incremental, evolutionary and spiral developments
Agile, lean and concurrent/simultaneous engineering
Systems Engineering Processes: Principles, Concepts and Components
System concepts
SE process principles & components
Requirements assessment
Development of physical solution description
Development of logical solution description MBSE
Effectiveness evaluation and decision
System elements – specification writing
System integration
Verification and validation
Engineering management
Requirements Analysis
What are requirements?
Various types of requirements, and how they relate to analysis, specification &
design
Requirements quality qualities
Requirements languages: operational, formal
Requirements analysis (RA) – how to do it
MBSE in the problem domain
Requirements quality measures
Lean concepts in functional analysis for the product-oriented enterprise
ERA analysis, rest-of scenario analysis, out-of-range analysis, other constraints
search, stakeholder value analysis
The Operational Concept Description (OCD)/CONUSE
Managing RA
Requirements analysis and management software tools
Development of the System Physical Solution Description (Synthesis)
Technology and innovation in solution development
Configuration items
Standards for selecting configuration items
Development of the System Logical Solution (MBSE in Design)
Rational representation classification
Functional analysis in design
Architecture process
Implementation risks
SysML, LML and other systems modeling languages
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5. n-squared charts, behavior modeling, and other functional notations
Assessment and design software tools
What is A Model?
Components of a model
Characteristics of a model
Language: the systems model is language-based language of behavior
Managing complexity with language
Structure: the model expresses system relationships
Argument: the model is used to “prove” the concept of the design
Presentation: the model must be “viewable”
Model-Based Systems Engineering
Requirements for a systems engineering processes
MBSE model and system definition language developing layer 1 of our solution
Proceeding with layer 2
Architecture design at layer n
Verification and validation
MBSE Definitions & Advantages
International council on systems engineering (incose) definition & advantages
Model-Based Systems Engineering (MBSE) definition
Advantage to using MBSE
Sysml forum mbse definition & advantage
SysML forum MBSE definition
SysML forum MBSE advantage
INCOSE Systems Engineering Vision 2020
Vision 2020 integrating framework
Systems engineering vision
Role of MBSE within systems engineering vision 2020
MBSE Methodologies
INCOSE Object-Oriented Systems Engineering Method (OOSEM)
IBM rational telelogic harmony-se
IBM rational unified process for systems engineering (RUP-SE)
JPL State Analysis (Sa)
VITECH MBSE methodology
Dori Object-Process Methodology (OPM)
Weilkiens Systems Modeling Process (SYSMOD)
Fernandez ISE & Process Pipelines in OO Architectures (ISE&PPOOA)
MBSE Modeling Language Standards
SysML
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6. UML
MBSE Software Tools
MBSE tools and relevance of other “de-facto” MBSE visual modeling standards
SAE Architecture Analysis and Designing Language (AADL)
Vitech Core
MagicDraw
Phoenix integration
IBM® RATIONAL® RHAPSODY®
Eclipse
ISIGHT & the SIMULIA execution engine
Lean Engineering
Lean Implementation Develops From TPS
Differences From TPS
Lean goals and strategy
Steps to achieve lean systems
How Can Lean Connect With MBSE
Hands-On activities
Labs
Individual/small group activities
Hands-on workshops
TONEX MBSE Hands-On Workshop Sample
Defining the problem
Studying the system and its components
Figuring out the relationship between the components and the entire system
Discussing the characteristics of the system
Modeling the system
MBSE Training Crash Course
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