To acquire fundamental knowledges on digital operations to analyze discrete signals in biomedical environments. To link different operating blocks in one complex system for analysis and processing. To provide an overview of some typical application of biomedical signals for processing and transmission, by a short description of main operating concepts.
teacher profile teaching materials
Laboratory of numerical examples by MatLab platform.
Further details at: http://host.uniroma3.it/laboratori/sp4te/teaching/sp4bme/program.html
TAMAL BOSE, FRANCOIS MEYER, "DIGITAL SIGNAL AND IMAGE PROCESSING", DECEMBER 2003, WILEY PUBL.
A.V. OPPENHEIM, R.W. SHAFER, J.R. BUCK, "DISCRETE-TIME SIGNAL PROCESSING", PRENTICE-HALL, UPPER SADDLE RIVER, NJ (USA), 1999.
Programme
Discrete signals and systems. Operations between sequences. Scale changes. Digital transforms. Filtering. Linear system analysis. Optimum filters. Digital estimators and performance. Prediction. Spectral estimators. Applications of telemedicine. Digital health systems.Laboratory of numerical examples by MatLab platform.
Further details at: http://host.uniroma3.it/laboratori/sp4te/teaching/sp4bme/program.html
Core Documentation
G. Giunta, Slides of Signal Processing for Biomedical Engineering, edition 2015.TAMAL BOSE, FRANCOIS MEYER, "DIGITAL SIGNAL AND IMAGE PROCESSING", DECEMBER 2003, WILEY PUBL.
A.V. OPPENHEIM, R.W. SHAFER, J.R. BUCK, "DISCRETE-TIME SIGNAL PROCESSING", PRENTICE-HALL, UPPER SADDLE RIVER, NJ (USA), 1999.
Reference Bibliography
B. Fong, A.C.M. Fong, C.K. Li, Telemedicine Technologies, Wiley, 2011.Type of delivery of the course
lectures and exercisesAttendance
optionalType of evaluation
oral with a preliminary written test