MT2576 - Systems Engineering, Theory and Applications

1. Descision

This course is established by Dean 2021-12-03. The course syllabus is approved by Head of Department of Mechanical Engineering 2022-03-01 and applies from 2022-08-29.

2. Entry requirements

Admission to the course requires at least 180 completed credit of which 90 credits in Mechanical Engineering, Industrial Economics and Management or adjacent subject area within the field of technology.

3. Objective and content

3.1 Objective

Systems Engineering as a discipline was originally introduced in response to the need to develop increasingly complex systems in the aerospace industry. The application of methods and tools for systems engineering has largely impacted the development of aircraft or satellites. The increasing socio-economic challenges related to globalization, population growth, economic interdependence, and sustainability are stressing the need for systems engineering competencies to be applied in different domains. Systems Engineering projects require multidisciplinary skills and cross-functional design teams, including a wide set of disciplines, such as design, manufacturing, system analysis, knowledge management, and sustainability analysis

3.2 Content

The course addresses topics such as:

Systems engineering definition and fundamentals
Stakeholders and needs analysis
Requirements formulation and management
Functional modeling
Reverse engineering
Systems engineering management
Failure Mode and Effect Analysis
Risk assessment and analysis of investment in Systems Engineering

4. Learning outcomes

The following learning outcomes are examined in the course:

4.1. Knowledge and understanding

On completion of the course, the student will be able to:

Identify when the use of systems engineering is desirable
Recognize what characteristics differentiate systems engineering from traditional product development
Describe how systems engineering methods are used in the development of complex systems
Explain how systems engineering can be applied for the development of sustainable product-service systems solutions

4.2. Competence and skills

On completion of the course, the student will be able to:

Describe the solution of a systems engineering problem by means of established systems engineering methods
Apply systems engineering methods to the reverse engineering of a system
Analyze the systems implications of a design modification at subsystem level
Formulate a list of product and system requirements
Identify the functions of a system and model their correlations and dependencies
Identify and illustrate the boundaries of a system
Analyze and illustrate the relations between the needs of the stakeholders and the engineering characteristics of a system
Identify and estimate the major risks related to a systems engineering project

4.3. Judgement and approach

On completion of the course, the student will be able to:

Summarize limits and potential of systems engineering methods
Justify the usability of systems engineering methods in different development contexts
Compare and judge the correct application of systems engineering methods

5. Learning activities

The course features a combination of learning activities.
Pre-recorded lectures on systems engineering theories and methods are combined with short exercises where students actively work in groups on a defined task related to the lecture.

A reverse engineering role-play is organized as a central event of the course to give participants a first-hand experience of the systems engineering methods applied in the context of a reverse engineering exercise. The role-play is run in teams while the participants will ultimately individually reflect on the systems engineering dynamics of the role-play.

A course project is run individually or in teams in collaboration with a selected partner company. The project is run in parallel with the other learning activities all along the period of study and will challenge the students in applying systems engineering method on a real industrial problem. The course project will be detailed in a final written assignment including a live presentation of the results.

Team coaching is provided along the course of the project and it is complemented by peer evaluation in the form of class presentations and feedback about both the process and the results. The university educational platform is used as a virtual environment to support knowledge sharing among students’ teams and teachers.

6. Assessment and grading

Modes of examinations of the course

Code	Module	Credit	Grade
2210	Written assignment 1	2.5 credits	GU
2220	Written assignment 2	2.5 credits	GU

The course will be graded G Pass, UX Failed result, a little more work required, U Fail.

The information before the start of the course states the assessment criteria and make explicit in which modes of examination that the learning outcomes are assessed.

An examiner can, after consulting the Disability Advisor at BTH, decide on a customized examination form for a student with a long-term disability to be provided with an examination equivalent to one given to a student who is not disabled.

7. Course evaluation

The course evaluation should be carried out in line with BTH:s course evaluation template and process.

8. Restrictions regarding degree

The course can form part of a degree but not together with another course the content of which completely or partly corresponds with the contents of this course.

9. Course literature and other materials of instruction

Product and Systems Development : A Value Approach ISBN: 978-1-118-33154-5

Course syllabus

1. Descision

2. Entry requirements

3. Objective and content

3.1 Objective

3.2 Content

4. Learning outcomes

4.1. Knowledge and understanding

4.2. Competence and skills

4.3. Judgement and approach

5. Learning activities

6. Assessment and grading

7. Course evaluation

8. Restrictions regarding degree

9. Course literature and other materials of instruction