IMAGE ANALYSIS AND FUNDAMENTALS OF DOSIMETRY

Academic Year 2020/2021 - 2° Year - Curriculum PHYSICS APPLIED TO CULTURAL HERITAGE, ENVIRONMENT AND MEDICINE
Teaching Staff: Giuseppe STELLA
Credit Value: 6
Scientific field: FIS/07 - Applied physics
Taught classes: 42 hours
Term / Semester:

Learning Objectives

The aim of the course is the achievement by the students of basic physical principles for the formation and analysis of images obtained using different sources and detectors. methodologies. application of the principal methods for the characterization and dating of materials. Particular attention is given to the techniques used in medical imaging and dosimetry.

Knowledge and understanding
Critical understanding of the most advanced developments in Modern Physics in both theoretical and laboratory aspects and their interconnections, even in interdisciplinary fields. Adequate knowledge of advanced mathematical and computer tools of current use in the fields of basic and applied research. High level of competence in the scientific method, and understanding of the nature and methodologies of research in Physics.

Applying knowledge and understanding
Ability to identify the essential elements of a phenomenon, in terms of order of magnitude and level of approximation necessary, and be able to make the required approximations. Ability to use the analogy tool to apply known solutions to new problems (problem solving). Ability to design and implement experimental and theoretical procedures to solve problems of academic and industrial research or to improve existing results. Ability to use analytical and numerical mathematical calculation tools and information technology, including the development of software programs.

Making judgements
Awareness of safety problems in laboratory work. Ability to discuss personal interpretations of physical phenomena, confronting each other in the context of work groups. Development of a sense of responsibility through the choice of optional courses and the subject of the degree thesis.

Communication skills
Ability to communicate in Italian and English in the advanced fields of Physics. Ability to present their research activity or of scientific data review results to both specialist and nonspecialist audiences; Ability to work in an interdisciplinary group, adapting the modalities of expression to interlocutors of different culture.

Learning skills
Ability to acquire adequate cognitive tools for the continuous updating of knowledge. Ability to access specialized literature both in the chosen field and in scientifically close fields. Ability to use databases and bibliographic and scientific resources to extract information and suggestions for better focusing and developing personal study and research work.


Course Structure

Lectures and teaching interactive laboratory classes.

Should the circumstances require online or blended teaching, appropriate modifications to what is hereby stated may be introduced, in order to achieve the main objectives of the course.


Detailed Course Content

Image basics: Image formation. Analog vs digital images. Digital images fundamentals. Spatial and contrast resolution.
Medical imaging: Radiography. Computed Tomography. Magnetic Resonance Imaging. Images in Clinical Nuclear Medicine.
Introduction to radiation dosimetry: Dosimetry quantities and units. Quantities and units in radiation protection. Legislation references.
Dosimetry detectors: Radiochromic films. Matrix detectors. TLD and OSLD. Gel dosimetry.


Textbook Information

Attix F.H., "Introduction to Radiological Physics and Radiation Dosimetry", Wiley, 2007, 598 pp.
Bushberg J.T, Seibert J.A., Leidholdt E.M. Jr., Boone J.M., "The Essential Physics of Medical Imaging", Lippinctto Williams & Wilkins, 2012, 1030
Dowsett D.J., Kenny P.A. and Johnston R. E., "The Physics of Diagnostic Imaging", CRC Press, 2006, 725 pp.
Gonzales R.C. and Woods R. E., "Elaborazione delle immagini digitali", Pearson Pertice Hall, 2008, 820 pp.
Greening J.R., "Fundamentals of Radiation Dosimetry", CRC Press, 1985, 190 pp.
Hendee W. R. and Ritenour E.R., "Medical Imaging Physics", Wiley-Liss, 2002, 512 pp.