Teaching code

4S012355

Teacher

Andrea Giachetti

Coordinator

Andrea Giachetti

Credits

6

Language

English

Scientific Disciplinary Sector (SSD)

ING-INF/05 - INFORMATION PROCESSING SYSTEMS

Period

2nd semester dal Mar 2, 2026 al Jun 12, 2026.

Courses Single

Authorized

Lessons timetable Moodle Seminars 0

Learning objectives

The course aims to provide theoretical foundations and practical tools to address the problems of estimating the 3D structure of a scene starting from images, the data driven geometric and photometric 3D modeling of scenes, dynamic analysis of scenes. At the end of the course the student will have to demonstrate the ability to apply the acquired knowledge, in particular i) know ho to handle the diverse data structures used to model scenes and objects 3D, also to apply machine learning methods on them, ii) Know the method used for 3D scanning, vision-based tracking, photometric reconstruction. iii) use computational vision methods in various application scenarios, such as robotics or medical image processing; iv) manage issues of efficiency and accuracy of the techniques. At the end of the course the student will also have to show that he is able to continue his studies independently in the field of visual computing and the analysis of three-dimensional data. Must be able to present the results of a computational vision application and deal with professionals in the sector and have the ability to autonomously adapt to technical evolution and the state of the art in the field of computational vision.

Prerequisites and basic notions

Fundamentals of linear algebra, image processing and computer vision, geometry

Program

3D reconstruction: data structures to represent surfaces and volumetric data, point clouds, meshing, surface recovery, implicit representations, light field reconstruction (Nerf, Gaussian Splatting)
From 2D to 3D: structure from motion and SLAM, 3D scanning technologies
Reflectance modeling and materials characterization, Photometric Stereo
3D reconstruction from medical data
Fundamentals of geometry processing, surface analysis
Computational design and digital manufacturing

Didactic methods

Lectures and laboratory exercises in Python or with modeling, photogrammetry and 3D printing software

Learning assessment procedures

Written test on all teaching topics, through open questions and exercises, for a duration of 2 hours (maximum score 24/30) and homework evaluation (max 10/30) replaced by a project for non-attending students. There are no intermediate tests.

Evaluation criteria

To pass the exam, students must demonstrate to:
-have understood the concepts underlying the representation and processing of three-dimensional information, 3D scanning, the extraction and processing of surface geometry, the coding of attributes useful for graphic rendering and visualization, the reconstruction of geometric information for medical diagnosis from volumetric data;
-be able to present your arguments in a precise and organic way; know how to apply the knowledge acquired to solve application problems presented

Criteria for the composition of the final grade

The final grade will be the sum of the written evaluation and the practical test. The test is passed if the grade of the written test is higher than 14 and the grade of the practical test is higher than 4. If the sum of the scores is higher than 30, a score of 30 cum laude will be assigned.

Exam language

Inglese (italiano opzionale)