Description

At the end of this training, students should be able to interact with biologists/physicians in order to design/develop tools that allow them to respond to clinical or preclinical imaging issues. Students will be trained in imaging techniques from the physicist's point of view (interaction radiation/matter, signal treatment, instrumentation, basics of the main imaging technics, computing and Artificial intelligence). They will thus be able to understand all the processes leading to the formation of an image. A particular focus is placed on MRI and nuclear imaging. The skills acquired will be numerical, theoretical and experimental.

Compétences visées

•    Applying knowledge in physics;

•    Apply methods from mathematics and digital technology;

•    Produce a critical analysis, with hindsight and perspective;

•    Interact with colleagues in physics and other disciplines;

•    Operate an experimental device, including digital aspects, from use to data analysis;

•     Processing a digital signal with or without the help of artificial intelligence;

•    Communicate in writing and orally, including in English;

•    Contribute to research work in physics;

•    Respect ethical, professional and environmental principles in the practice of physics.

Syllabus

I-Introductiont to different types of detector and their usefulness depending on the particles to be detected;

II-Characteristics of a detector (efficiency, solid angle, etc.);

III-The basic principles of image formation using ionizing radiation (example of positron emission imaging).

Contacts

Responsable(s) de l'enseignement

• Patrice Laquerriere

MCC

Les épreuves indiquées respectent et appliquent le règlement de votre formation, disponible dans l'onglet Documents de la description de la formation.

Régime d'évaluation

CT (Contrôle terminal, mêlé de contrôle continu)

Coefficient

1.0

Évaluation initiale / Session principale - Épreuves

Seconde chance / Session de rattrapage - Épreuves