Fractal mechanics

ID: 1278
Course type: theoretical and methodological
Course coordinator: Matija R. Lidija
Lecturers: Matija R. Lidija
Contact: Matija R. Lidija
Level of studies: M.Sc. (graduate) Academic Studies – Mechanical Engineering
ECTS: 6
Final exam type: written
Department: Department of Biomedical Engineering

Lectures

Biomedical Engineering, Semester 1, position 5

Goal

The goal of this subject is to teach a student to apply fractal and multi-fractal system theory in a field of biomedical engineering; to learn to use mathematical apparatus of fractal analysis and modelling; to master fractal image processing and fractal signal analysis; to learn to define diagnostic parameters, algorithms and instruments for determining functional conditions of organs and organism (normal conditions and pathological conditions).

Outcome

Upon successful completion of this course, students will be able to: •Assess whether the objects have fractal properties and describe the fractal behavior of the systems by properly chosen method of fractal analysis •Create fractal algorithms for image analysis and signal analysis •Perform calculation of the fractal dimension using modern methods •Define diagnostic parameters for determining the functional states of tissues, organs and organism based on fractal dimension

Theoretical teaching

Fundamentals of classic and quantum physics. Fundamentals of classical and quantum information. Cantor's diad-triad set. Laws of big numbers. Deterministic chaos. Mathematical basis of fractal and multifractal theory. Fractals and fractal dimensions. Fractal analysis of signals and images. Applications of fractal analysis in biomedical engineering. Applications of fractal analysis in cancer diagnostics. Applications of fractal analysis in mechanical engineering.

Practical teaching

Fractal dimension and lacunarity calculus for mathematically generated fractal object. Fractal dimension and lacunarity calculus applications for medical images of skin lesions.

Attendance requirement

Defined by the study curriculum of Biomedical engineering module learning resources

Resources

Koruga,Dj., Matija, L., Munćan, J., Written course material (handouts)

Assigned hours

Total assigned hours: 75

Active teaching (theoretical)

New material: 25
Elaboration and examples (recapitulation): 5

Active teaching (practical)

Auditory exercises: 14
Laboratory exercises: 6
Calculation tasks: 2
Seminar paper: 4
Project: 2
Consultations: 0
Discussion/workshop: 2
Research study work: 0

Knowledge test

Review and grading of calculation tasks: 0
Review and grading of lab reports: 0
Review and grading of seminar papers: 6
Review and grading of the project: 0
Test: 0
Test: 4
Final exam: 5

Knowledge test (100 points total)

Activity during lectures: 5
Test/test: 30
Laboratory practice: 0
Calculation tasks: 10
Seminar paper: 15
Project: 0
Final exam: 40
Requirement for taking the exam (required number of points): 40

Literature

Koруга, Ђ.,Фрактална механика: Класично-квантни феномени у природи, биологији и инжењерству, DonVas, Београд, 2013; Brown, C., & Liebovitch, L. (2010). Fractal analysis (Vol. 165). Sage.; Manddelbrot, B.B., The Fractal geometry of nature, W.H.Freeman and Co., New York, 1983; Rangayyan, R. M. (2004). Biomedical image analysis. CRC press.; Nonnenmacher, T. F., Losa, G. A., & Weibel, E. R. (Eds.). (2013). Fractals in biology and medicine. Birkhäuser.