Model-based systems engineering (MBSE), as a formal application of modeling to support system requirements, design, analysis, verification and validation activities, starting from the conceptual design stage and continuing to the entire development stage and subsequent life cycle stages
When the systems engineer defines or creates something during a diagram, the SysML tool maintains consistency altogether the opposite diagrams during a process called traceability.
The advantage of MBSE and SysML is that the ability to make models/diagrams for the system rather than using documents.
The reasons for his or her popularity are
MBSE gives a uniform way of capturing and managing the system’s requirements, architecture, design, and processes
Facilitates communication among various stakeholders by providing discipline-specific views for various purposes
Allows detecting defects early within the system development life cycle
Can function one source of truth for systems engineers and other team members
Allows exploring multiple solutions with minimal investment.
12 Industries stand to profit from the MBSE approach:
Transportation and Mobility
Aerospace and Defense
Industrial Equipment
Energy and Utilities
Architecture and Construction
Life Sciences
High-tech
Marine and Offshore
Financial and Business Services
Consumer Goods and Retail
Natural Resources
Consumer Packaged Goods and Retail.
Introduction to Model-Based Systems Engineering (MBSE) Course by Tonex
Learn about modeling, modeling applied to systems engineering, system modeling language (SysML) applications, etc.
Audience:
Developers
Systems Engineers
Testers
Project Managers
Analysts
Anyone else who wants to learn the application of modeling to modern systems engineering practices.
Learning Objectives
Explain models and Model-Based Systems Engineering (MBSE)
Express what SysML is
Explore model-based systems engineering approach
List SysML diagrams and language concepts
Apply SysML as part of a model based SE process applied to design and manufacturing
Expand a system conceptual model and architecture using MBSE/SysML
Describe system use cases, requirements, architecture, function, structure, behavior and tests with SysML
Explain the notions of system, product, service, and project with SysML
Model a combined Project-Product Life cycle Management system and study the benefits of the project-product synergies with SysML
Work with real life projects using MBSE approach with SysML
Course Agenda
Model Based Systems Engineering (SE) Overview
Model-based systems engineering (MBSE) vs. Document-Based Systems Engineering
SysML Overview
Diagram Techniques of SysML
Working with MBSE and SysML
Workshop
Learn more:
https://www.tonex.com/training-courses/introduction-to-model-based-systems-engineering-mbse/
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Introduction to Model-Based Systems Engineering (MBSE) Course
1.
2. Model-based systems engineering (MBSE), as a
formal application of modeling to support system
requirements, design, analysis, verification and
validation activities, starting from the conceptual
design stage and continuing to the entire
development stage and subsequent life cycle stages
3. When the systems engineer defines or creates
something during a diagram, the SysML tool
maintains consistency altogether the opposite
diagrams during a process called traceability.
The advantage of MBSE and SysML is that the
ability to make models/diagrams for the system
rather than using documents.
4. The reasons for his or her popularity are
• MBSE gives a uniform way of capturing and managing the
system’s requirements, architecture, design, and processes
• Facilitates communication among various stakeholders by
providing discipline-specific views for various purposes
• Allows detecting defects early within the system development
life cycle
• Can function one source of truth for systems engineers and
other team members
• Allows exploring multiple solutions with minimal investment.
5. The goal is that the Digital Thread, the entire set of
domain models organized, connected and version-
managed during a way that permits everyone on the
event team to seek out the info they have to try to to
their jobs. Each discipline and every organization
have a seat at the MBSE table.
6. In each enterprise, the implementation of digital
threads is still incremental. Early adopters hope to
enhance collaboration between team members
through specific integrations, speed up the
completion of tasks and reduce errors caused by
inconsistent domain models.
As they implement digital threads more
comprehensively, they have gained greater benefits
in model verification and verification, allowing them
to explore the system design space more deeply in
the project schedule.
7. One more style in the MBSE field is how
engineering software tools and the digital thread
infrastructure connecting them have become
scalable enterprise applications that can share
services and data in the cloud or on a local server.
In the past 13 years, MBSE has been widely adopted
by system engineers as part of a long-term trend
toward model-centric adoption by other engineering
disciplines (including mechanical, electrical, and
software).
8. 12 Industries stand to profit from the MBSE approach:
• Transportation and Mobility
• Aerospace and Defense
• Industrial Equipment
• Energy and Utilities
• Architecture and Construction
• Life Sciences
• High-tech
• Marine and Offshore
• Financial and Business Services
• Consumer Goods and Retail
• Natural Resources
• Consumer Packaged Goods and Retail.
9. Introduction to Model-Based Systems Engineering
(MBSE) Course by Tonex
Learn about modeling, modeling applied to systems
engineering, system modeling language (SysML)
applications, etc.
10. Participants will gain knowledge of how to apply
MBSE and how modern systems engineering uses
models to create structure and dynamic artifacts for
conops, system requirements, design, architecture,
analysis verification and validation activities.
During case studies and examples, participants will
discover the application of modeling in system
engineering, model-based analysis, requirements,
design and testing methods.
11. For system engineers, developers, testers and project
managers, the System Modeling Language (SysML)
uses static and dynamic diagrams suitable for system
collection to represent system-related information.
The MBSE introduction will explain the advantages
of MBSE and SysML and the ability to create
models/diagrams for systems rather than documents.
12. Audience:
• Developers
• Systems Engineers
• Testers
• Project Managers
• Analysts
• Anyone else who wants to learn the application of
modeling to modern systems engineering practices.
13. Learning Objectives
• Explain models and Model-Based Systems
Engineering (MBSE)
• Express what SysML is
• Explore model-based systems engineering approach
• List SysML diagrams and language concepts
• Apply SysML as part of a model based SE process
applied to design and manufacturing
• Expand a system conceptual model and architecture
using MBSE/SysML
14. Learning Objectives
• Describe system use cases, requirements,
architecture, function, structure, behavior and tests
with SysML
• Explain the notions of system, product, service, and
project with SysML
• Model a combined Project-Product Life cycle
Management system and study the benefits of the
project-product synergies with SysML
• Work with real life projects using MBSE approach
with SysML
15. Course Agenda
• Model Based Systems Engineering (SE) Overview
• Model-based systems engineering (MBSE) vs.
Document-Based Systems Engineering
• SysML Overview
• Diagram Techniques of SysML
• Working with MBSE and SysML
• Workshop
16. Learn More:
Introduction to Model-Based Systems Engineering Course
https://www.tonex.com/training-courses/introduction-to-
model-based-systems-engineering-mbse/