Studying at the University of Verona
Here you can find information on the organisational aspects of the Programme, lecture timetables, learning activities and useful contact details for your time at the University, from enrolment to graduation.
Type D and Type F activities
This information is intended exclusively for students already enrolled in this course.If you are a new student interested in enrolling, you can find information about the course of study on the course page:
Laurea magistrale in Artificial Intelligence - Enrollment from 2025/2026Type D learning activities are the student's choice, type F activities are additional knowledge useful for job placement (internships, transversal skills, project works, etc.). According to the Teaching Regulations of the Course, some activities can be chosen and entered independently in the booklet, others must be approved by a special committee to verify their consistency with the study plan. Type D or F learning activities can be covered by the following activities.
1. Modules taught at the University of Verona
Include the modules listed below and/or in the Course Catalogue (which can also be filtered by language of delivery via Advanced Search).
Booklet entry mode: if the teaching is included among those listed below, the student can enter it independently during the period in which the curriculum is open; otherwise, the student must make a request to the Secretariat, sending the form to carriere.scienze@ateneo.univr.it during the period indicated.
2. CLA certificate or language equivalency
In addition to those required by the curriculum/study plan, the following are recognized for those matriculated from A.Y. 2021/2022:
- English language: 3 CFUs are recognized for each level of proficiency above that required by the course of study (if not already recognized in the previous course of study).
- Other languages and Italian for foreigners: 3 CFUs are recognized for each proficiency level starting from A2 (if not already recognized in the previous study cycle).
These CFUs will be recognized, up to a maximum of 6 CFUs in total, of type F if the study plan allows it, or of type D. Additional elective credits for language knowledge may be recognized only if consistent with the student's educational project and if adequately justified.
Those enrolled until A.Y. 2020/2021 should consult the information found here.
Method of inclusion in the booklet: request the certificate or equivalency from CLA and send it to the Student Secretariat - Careers for the inclusion of the exam in the career, by email: carriere.scienze@ateneo.univr.it
3. Transversal skills
Discover the training paths promoted by the University's TALC - Teaching and learning center intended for students regularly enrolled in the academic year of course delivery https://talc.univr.it/it/competenze-trasversali
Mode of inclusion in the booklet: the teaching is not expected to be included in the curriculum. Only upon obtaining the Open Badge will the booklet CFUs be automatically validated. The registration of CFUs in career is not instantaneous, but there will be some technical time to wait.
4. Contamination lab
The Contamination Lab Verona (CLab Verona) is an experiential course with modules on innovation and enterprise culture that offers the opportunity to work in teams with students from all areas to solve challenges set by companies and organisations.
Upon completion of a CLab, students will be entitled to receive 6 CFU (D- or F-type credits).
Find out more: https://www.univr.it/clabverona
PLEASE NOTE: In order to be admitted to any teaching activities, including those of your choice, you must be enrolled in the academic year in which the activities in question are offered. Students who are about to graduate in the December and April sessions are therefore advised NOT to undertake extracurricular activities in the new academic year in which they are not enrolled, as these graduation sessions are valid for students enrolled in the previous academic year. Therefore, students who undertake an activity in an academic year in which they are not enrolled will not be granted CFU credits.
5. Internship/internship period
In addition to the CFUs stipulated in the curriculum/study plan (check carefully what is indicated on the Teaching Regulations) here you can find information on how to activate the internship.
Check in the regulations which activities can be Type D and which can be Type F.
Please also note that for traineeships activated after 1 October 2024, it will be possible to recognise excess hours in terms of type D credits limited only to traineeship experiences carried out at host organisations outside the University.
| years | Modules | TAF | Teacher |
|---|---|---|---|
| 1° 2° | Elements of Cosmology and General Relativity | D |
Claudia Daffara
(Coordinator)
|
| 1° 2° | Introduction to quantum mechanics for quantum computing | D |
Claudia Daffara
(Coordinator)
|
| 1° 2° | Introduction to smart contract programming for ethereum | D |
Sara Migliorini
(Coordinator)
|
| 1° 2° | Python programming language [English edition] | D |
Carlo Combi
(Coordinator)
|
| 1° 2° | Mini-course on Deep Learning & Medical Imaging | D |
Vittorio Murino
(Coordinator)
|
| 1° 2° | BEYOND ARDUINO: FROM PROTOTYPE TO PRODUCT WITH STM MICROCONTROLLER | D |
Franco Fummi
(Coordinator)
|
| 1° 2° | APP REACT PLANNING | D |
Graziano Pravadelli
(Coordinator)
|
| 1° 2° | HW components design on FPGA | D |
Franco Fummi
(Coordinator)
|
| years | Modules | TAF | Teacher |
|---|---|---|---|
| 1° 2° | LaTeX Language | D |
Enrico Gregorio
(Coordinator)
|
| 1° 2° | Python programming language [Edizione in italiano] | D |
Carlo Combi
(Coordinator)
|
| 1° 2° | Rapid prototyping on Arduino | D |
Franco Fummi
(Coordinator)
|
| 1° 2° | Programming Challanges | D |
Romeo Rizzi
(Coordinator)
|
| 1° 2° | Protection of intangible assets (SW and invention)between industrial law and copyright | D |
Mila Dalla Preda
(Coordinator)
|
HCI – Intelligent Interfaces (2024/2025)
Teaching code
4S010680
Credits
6
Language
English
Also offered in courses:
- Human-Computer Interaction of the course Master's degree in Computer Science and Engineering
- Human-Computer Interaction of the course Master's degree in Computer Science and Engineering
Scientific Disciplinary Sector (SSD)
ING-INF/05 - INFORMATION PROCESSING SYSTEMS
Courses Single
Authorized
The teaching is organized as follows:
Theory
Laboratory
Learning objectives
The course introduces students to the fundamental theories and concepts of human-computer interaction (HCI), which is an interdisciplinary field that draws from cognitive psychology, computer science, and design. HCI aims to provide both theoretical understanding and hands-on experience in key aspects of human perception, cognition, and learning as they relate to interface design, implementation, and evaluation. Covered topics include interface design, usability evaluation, universal design, and multimodal interfaces (touch, vision, natural language, audio). Special emphasis will be placed on equipping students with foundational knowledge, methodologies, and tools necessary for designing, implementing, and evaluating computer systems capable of capturing, representing, and automatically analyzing user behavior. This encompasses various forms of non-verbal communication, including gestures, movements, facial expressions, and speech. Moreover, students will learn strategies for effectively interacting with users by providing multisensory feedback, utilizing elements such as images, sounds, and control of actuators.
At the end of the course, students will:
- Understand the rationale behind utilizing multimodal interactive systems for specific applications, comprehend the logical architectures defining the main components of such systems, grasp the design and development guidelines for multimodal interactive systems, and recognize the potential application areas for their successful deployment.
- Familiarize themselves with the key devices for capturing user behaviour data, comprehend their functionality, and discern appropriate usage scenarios.
- Acquire knowledge of essential techniques for representing and automatically analysing user behaviour, including those that process data from multiple sensor devices across various sensory channels.
-Demonstrate proficiency in designing and implementing major components of a multimodal interactive system using the development tools introduced in lectures and practical sessions throughout the course.
Prerequisites and basic notions
Basic knowledge of statistics and computer graphics
Program
Theory
Introduction: motivation, aim of the course, professional perspectives, open issues, description of course program and method of exam
Foundation of HCI: human factors, interaction design, usability, gaming and gamification
Visual interaction: camera calibration, structure and motion
Nonverbal behavior in communication: types of nonverbal behavior (facial expressions, gestures, posture, eye gaze), data collection methods, tools and software for nonverbal behavior analysis, annotation tools, e.g., ELAN
Automated analysis of body: movement, gestures, facial expressions, and speech. Data capturing techniques, extracting features, and automatic analysis
Social artificial intelligence: example applications, social psychology, organizational psychology, and social robotics.
Affective computing: theories of emotion, emotion recognition systems, applications of emotion recognition in HCI.
Integration of multimodal nonverbal cues: fusion techniques, e.g., late and early fusion.
Laboratory
Deep Image matching : Python implementation of feature detection and matching
3D Model reconstruction: Structure and motion with Zephyr
Camera pose estimation : C# implementation of Fiore’s method
3D graphics: modelling and rendering in Unity
Model-based AR: implementation of the full AR pipeline integrating python code and Unity
Advanced aspects: deep camera pose estimation, model recognition
Bibliography
Didactic methods
Lectures and lab sessions
Learning assessment procedures
Oral exam and evaluation of lab activity
Evaluation criteria
To pass the exam, students must demonstrate that they:
-have understood the concepts of man-machine interaction and the design of interactive and intelligent systems;
-are able to present their arguments in a precise and organic way;
-know how to apply the acquired knowledge to implement HCI system in practice;
Criteria for the composition of the final grade
50% oral 50% lab activity evaluation
Exam language
Inglese o Italiano (English or Italian)
