Advanced Systems Engineering Certification
Advanced systems engineering certification training courses offer several courses in various fields of systems engineering.
Systems engineering is an interdisciplinary technique and tools to allow you to understand the effective systems. It concentrates on describing what customer wants and necessary operation in beginning of the development process, documenting criteria, then continuing with design and system validation while bearing in mind the whole problem including processes, execution, analysis, production, cost, and timetable.
Systems engineering courses relate systems engineering to principals of decision theory, statistics, and optimization. It also provides the most recent, commercially effective tools for systems engineering.
Systems engineering training courses covers various trainings from the basic to advanced levels, providing a fundamental, conceptual-level definition of engineering management strategies that discuss the development and life cycle management of a system. They deliver thorough trainings of how a system is developed for the non-engineers, while delivering a framework for planning and assessing system development for the engineers and project managers.
You will learn about systems engineering process, systems analysis and control, planning, organizing, and managing. You will receive knowledge on the fundamental notions that oversee the systems engineering processes and they fit your organization processes.
Advanced Systems Engineering Certificate of TONEX provides in-depth knowledge and technical abilities in the field of systems engineering and systems of systems to enhance your performance and skills when you go back to your work in your organization, either in private sectors or government. These systems-centric training courses consider the needs of engineers and scientists involved in all fields of evaluation, design, incorporation, manufacturing, and execution of modern systems.
The systems engineering process organizes and guides the conversion of an operational requirement into a system planned to cover that need. It combines the inputs of all the necessary technical methods into a synchronized effort that complies to proven implementation, budget, and schedule objectives. Systems engineers offer the leadership and coordination of the planning, development, and engineering of technical systems, including hardware and software elements.
System is a combination of people, products, and processes that deliver the ability to fulfill a need or objective.
Systems engineering consists of two substantial perspectives: the technical knowledge area where the systems engineer works, and the systems engineering management. Some of the well-established standards define systems engineering as the following:
- A rationale order of actions and decisions that renovates a functional demand into a description of system execution elements and a preferred system construction. (MIL-STD- 499A, Engineering Management)
- A cross-functional technique that covers the whole technical work, and alters and verifies an incorporated and life cycle stable series of system people, goods, and process resolutions that fulfill customer demands. (EIA Standard IS-632, Systems Engineering)
- An interdisciplinary, cooperative technique that develops, grows, and confirms a life-cycle well-adjusted system solution, which fulfills customer prospects and public acceptability. (IEEE P1220, Standard for Application and Management of the Systems Engineering Process)
To summarize, systems engineering is a cross-functional engineering management procedure that changes and confirms a cohesive, life-cycle stable sequence of system solutions that satisfy customer expectations.
Systems Engineering Management
Systems engineering management is achieved by incorporating three major actions:
- Development phases that oversees the design process and delivers baselines that organize design efforts
- A systems engineering process that delivers a configuration for solving conceptual problems and tracing requirements flow within the design
- Life cycle incorporation that includes customers in the design process and guarantees that the developed system is feasible throughout its life
Stating the Problem
The problem statement begins with a definition of the top-level operations that the system must execute: this could be in the shape of a mission statement, a concept of operations or a description of the deficiency that must be enhanced. Most obligatory and execution requirements should be distinguishable to such problem statement.
Acceptable systems must fulfill all the compulsory requirements. The optional requirements are exchanged to discover the preferred alternatives. The problem statement expresses the customer expectations in operational or performance expressions. It might be constructed in words or as a model. Inputs are defined based on the expectations coming from end users, operators, maintainers, suppliers, acquirers, owners, regulatory agencies, victims, sponsors, manufacturers and other stakeholders.
Modeling the System
Modeling the system is particularly useful when the system is complex or is constructed of several layers and subsystems that are not easy to comprehend. Modeling would allow you to decompose the system into smaller units that are easier to model, while still considering the system as a whole. The model is applied to help manage the system across its entire life cycle. Various forms of system models include physical analogs, analytic equations, state machines, block diagrams, functional flow diagrams, object-oriented models, computer simulations and mental models.
Systems Engineering is accountable for creating and producing process of a product. Therefore, models should be configured for both the product and the process. The process models let us study the timetable modifications, create dynamic PERT diagrams and execute sensitivity assessments to demonstrate the impacts of delaying or accelerating specific subprojects. Executing the process models exposes bottlenecks actions, decreases the expenses, and reveals overlapping effort. On the other hand, the products models allow describing the system. Such models are also applied in tradeoff investigations and risk management analysis. However, one should remember that systems engineering process is not consecutive: it is parallel and iterative.
Systems, businesses, and people should be united so that they communicate with one another. Integration is defined as gathering all the elements so they operate as a whole. Boundaries among subsystems must be designed. Subsystems should be precisely described beside natural interfaces. Subsystems help to reduce the amount of data to be traded off between the subsystems. Clever subsystems conduct final products to other subsystems. Feedback loops around individual subsystems are simpler to manage than feedback loops around interconnected subsystems.
What Should You Expect To Learn?
Upon completing the advanced systems engineering certificate courses, you will know how to:
- Use technical knowledge of mathematics, science, and engineering to the realization and analysis of complicated systems and systems of systems.
- Illustrate the capability to consider of, collect user needs and requirements, plan, derive, combine, and evaluate complex systems by employing systems engineering thinking and processes, through necessary operational and acquisition system ecosystem.
- Comprehend and use the life cycle phases of systems development from concept development through production and operational maintenance.
- Practice your roles in managing the cost-effective systems product development by coaching and collaborating in interdisciplinary teams.
- Communicate complicated ideas and techniques in spoken and written style.
- Display awareness and ability in applying means and approaches in the systems engineering process.
Why Should You Choose TONEX?
- We have more than 15 years of experience in systems engineering
- Our instructors possess extensive experience in both industry and academia, allowing them to have a comprehensive perspective of what the participants need to learn and how to learn it
- Our courses are a combination of theories and practices
- The practical sections of our trainings include several labs, individual and group activities, and hands-on workshops
- The examples and projects we use are chosen from the real-world case studies
- Participants are encouraged to bring in their own organizational project to the class to work on during the hands-on workshops or class activities
- The courses agenda are flexible. We will tailor the course content to fit the needs of your organizations
- Finally, our courses are fun and interactive
Would Like To Learn More?
Simply browse through our courses category to explore what fits you best, while keeping in mind that all the courses can be tailored and adjusted to uniquely answer your needs too.
Advanced Systems engineering Certification