Cyber-Physical Systems

2022/2023

Content, progress and pedagogy of the module

The module is based on knowledge achieved in the project module Control systems and microprocessor based systems or similar.

Learning objectives

Knowledge

  • Have insight on the modeling of a system and the computational aspects in hardware and software needed to implement cyber-physical systems 
  • Have insight on how to implement digital communication within the components of a cyber-physical system using libraries
  • Be able to understand how to use discrete time to model the cyber or computational part and continuous time to model the physical world
  • Be able to understand basic concepts in operating systems, concurrency, finite state machines or flow charts to design the software of a cyber-physical system
  • Be able to understand the effect of the HW components and SW algorithms on the overall performance of a cyber-physical system
  • Be able to understand and create a business case for the cyber-physical system
  • Energy digital auditing and sensor placement in energy assets for predictive control maintenance

Skills

  • Be able to design cyber-physical systems that include digital controllers, their algorithms and their implementation in HW and SW
  • Be able to simulate parts or the whole of a cyber-physical system using data-flow based tools such as Matlab Simulink, Labview, Microprocessors and industrial platform software’s.
  • Be able to design and implement the SW of a cyber-physical system using high-level computer languages and libraries
  • Be able to implement the interface of a cyber-physical system to the physical world using ADC, DAC, microprocessor systems, sensors and actuators
  • Be able to use a cyber-physical systems approach to design, implement and solve an engineering problem in industry 4.0, IoT, robotics or within the energy sector and power electronics.
  • Be able to make a cost-benefit analysis of the cyber-physical system

Competences

  • Be able to design a cyber-physical system in a professional way
  • Be able to perform real-time analysis and programming of the designed system
  • Be able to evaluate the basic economic conditions for the development and commissioning of the cyber-physical system

Type of instruction

Problem based and project oriented work in project groups.

Some lectures are given in business economy to support the objectives in this area.

Extent and expected workload

Since it is a 15 ECTS project module, the work load is expected to be 450 hours for the student.

Exam

Exams

Name of examCyber-Physical Systems
Type of exam
Oral exam based on a project
Oral examination with external examiner based on a presentation of the project report.
ECTS15
Assessment7-point grading scale
Type of gradingExternal examination
Criteria of assessmentThe criteria of assessment are stated in the Examination Policies and Procedures

Facts about the module

Danish titleCyber-fysiske systemer
Module codeN-AIE-B5-2B
Module typeProject
Duration1 semester
SemesterAutumn
ECTS15
Language of instructionEnglish
Empty-place SchemeYes
Location of the lectureCampus Esbjerg
Responsible for the module
Time allocation for external examinersB

Organisation

Study BoardStudy Board of Energy
DepartmentDepartment of Energy
FacultyThe Faculty of Engineering and Science