ACIT4035 Rehabilitation and Assistive Technology Emneplan

From prosthetic limbs, exoskeletons, orthotics, hearing aids, and muscle-controlled mobility solutions to artificial organs and cognitive aids, the modern era of rehabilitation and assistive technology has created a paradigm shift in what technology can achieve to help people who need it. This course provides an exploration of rehabilitation and assistive technologies, with a strong emphasis on hands-on, problem-based prototyping. Students will be introduced to the essential principles and foundational knowledge of various existing rehabilitation and assistive devices designed to enhance daily living activities for individuals with disabilities. The course aims to develop the skills required to understand user needs, conceptualize ideas, and create functional prototypes, while also providing a comprehensive understanding of the current landscape of assistive technology. By the end of the course, students will be equipped with both theoretical knowledge and practical experience in designing effective, user-centred rehabilitation technologies.

Previous knowledge or practical hands-on experience in electronics, mechanics, or robotics and control is beneficial. It is recommended that the student takes some of the following courses: ACIT4720 Medical Sensors and Actuators, ACIT4730 Special Biomedical Engineering Subject, or ACIT4820 Applied Robotics and Autonomous Systems.

The student should have the following outcomes upon completing the course:

Knowledge

Upon successful completion of the course, the student has:

• thorough knowledge of cyber security
• advanced knowledge of mechanisms for cyber defense, and how they are used in practice
• a thorough understanding of societal aspects of cyber security
• a thorough understanding of the relation between security and privacy

Skills:

Upon successful completion of the course, the student can:

• describe the main aspects of the relation between security and privacy
• describe central problems related to cyber security governance
• plan and describe the structure of cyber defense for an organization

General com​petence:

Upon successful completion of the course, the student:

• understands the role of, and mechanisms that are used in penetration testing
• understands the role of, and mechanisms that are used for cyber defence
• can explain and discuss security challenges related to cyber security to experts and non-experts alike
• can explain and discuss societal aspects of cyber security with experts and non-experts alike.

This course features weekly lectures and workshops to provide both theoretical content and hands-on experience. Students work individually or in groups to complete assignments. The students supplement the lectures and workshops with their own reading. Compulsory assignments are given throughout the semester.

• Application of advanced movement theories, anatomical and functional approaches and methods into a specific rehabilitation or assistive device.
• Project work related to chosen rehabilitation or assistive device or part thereof.

The following required coursework must be approved before the student can take the exam:

• 8 assignments focusing on technical work or on theoretical aspects, documented in reports.

Individual written exam 3 hours.

The exam grade can be appealed.

New/postponed exam

In case of failed exam or legal absence, the student may apply for a new or postponed exam. New or postponed exams are offered within a reasonable time span following the regular exam. The student is responsible for registering for a new/postponed exam within the time limits set by OsloMet. The Regulations for new or postponed examinations are available in Regulations relating to studies and examinations at OsloMet.

In the event of resit and rescheduled exams, another exam form may also be used or a new assignment given with a new deadline. If oral exams are used, the result cannot be appealed.

No aids are permitted

Grade scale A-F.

Two internal examiners. External examiner is used periodically.

Professor Olav Lysne

Specification for students’ laptop

It is recommended that students come with laptops that can support the lab sessions during lectures.

Laptops should have enough hard disk, memory and CPUs to run at least one Kali Linux and one Ubuntu or Windows virtual machines at the same time.

Minimum laptop specification

PC

4 cores CPU

8GB of RAM

100-120 GB of free hard disk space

MacBook

M1 or 4 cores CPU

8GB of RAM

100-120 GB of free hard disk space

In addition, students are expected to be familiar with Linux operating system. For example, they should be able to install packages and run basic Linux commands.