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.
Academic calendar
The academic calendar shows the deadlines and scheduled events that are relevant to students, teaching and technical-administrative staff of the University. Public holidays and University closures are also indicated. The academic year normally begins on 1 October each year and ends on 30 September of the following year.
Course calendar
The Academic Calendar sets out the degree programme lecture and exam timetables, as well as the relevant university closure dates..
Period | From | To |
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I semestre | Oct 1, 2018 | Jan 31, 2019 |
II semestre | Mar 4, 2019 | Jun 14, 2019 |
Session | From | To |
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Sessione invernale d'esame | Feb 1, 2019 | Feb 28, 2019 |
Sessione estiva d'esame | Jun 17, 2019 | Jul 31, 2019 |
Sessione autunnale d'esame | Sep 2, 2019 | Sep 30, 2019 |
Session | From | To |
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Sessione di laurea estiva | Jul 22, 2019 | Jul 22, 2019 |
Sessione di laurea autunnale | Oct 15, 2019 | Oct 15, 2019 |
Sessione di laurea autunnale straordinaria | Nov 21, 2019 | Nov 21, 2019 |
Sessione di laurea invernale | Mar 19, 2020 | Mar 19, 2020 |
Period | From | To |
---|---|---|
Sospensione attività didattica | Nov 2, 2018 | Nov 3, 2018 |
Vacanze di Natale | Dec 24, 2018 | Jan 6, 2019 |
Vacanze di Pasqua | Apr 19, 2019 | Apr 28, 2019 |
Vacanze estive | Aug 5, 2019 | Aug 18, 2019 |
Exam calendar
Exam dates and rounds are managed by the relevant Science and Engineering Teaching and Student Services Unit.
To view all the exam sessions available, please use the Exam dashboard on ESSE3.
If you forgot your login details or have problems logging in, please contact the relevant IT HelpDesk, or check the login details recovery web page.
Academic staff
Cordoni Francesco Giuseppe
francescogiuseppe.cordoni@univr.itMagazzini Laura
laura.magazzini@univr.it 045 8028525Zini Giovanni
Zoppello Marta
Study Plan
The Study Plan includes all modules, teaching and learning activities that each student will need to undertake during their time at the University.
Please select your Study Plan based on your enrollment year.
1° Year
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2° Year activated in the A.Y. 2019/2020
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3° Year activated in the A.Y. 2020/2021
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Legend | Type of training activity (TTA)
TAF (Type of Educational Activity) All courses and activities are classified into different types of educational activities, indicated by a letter.
Physics I with laboratory (2018/2019)
Teaching code
4S02750
Credits
12
Language
Italian
Scientific Disciplinary Sector (SSD)
FIS/01 - EXPERIMENTAL PHYSICS
The teaching is organized as follows:
Teoria
Laboratorio
Esercitazioni
Esercitazioni [II° turno]
Esercitazioni [I° turno]
Learning outcomes
The teaching course of Physics I with Laboratory contributes to the achievement of the training objectives of the three year degree in Applied Mathematics by providing: - the basic elements of the scientific method, even with the help of laboratory experiments, in order to show that physics is a quantitative science based on the measurement of physical quantities; - the basic knowledge of classical mechanics of the particle, of the particle systems and of the rigid body; - the guidelines useful for the resolution of exercises and problems of classical mechanics. At the end of the course, the student must demonstrate to: - have adequate abilities to analyse and to abstract typical physical situations of the particle mechanics, of the particle systems and of the rigid body; - be able to produce rigorous proofs, and mathematically formalize problems of the particle mechanics, of the particle systems and of the rigid body formulated in natural language; - have the ability to build and develop mathematical models for physics and analyse their application limits. - be able to set up and perform some simple experiments for the measure of various physical quantities and the subsequent representation (histograms and graphs) as well as the analysis of the collected data.
Program
The teaching course of Physics I with Laboratory consists of two distinct modules, a Theory module (9 CFUs) and a Laboratory module (3 CFUs), delivered in a coordinated and functional way to ensure the student learning within the lesson schedule.
The Theory module provides basic knowledge of Classical Mechanics through the derivation of the laws and principles governing the motion of the bodies, as well as the elements useful for resolving exercises and problems of the particle dynamics, of the dynamics of particle systems and of the rigid body. The main topics covered in this module are: Physical quantities and their measurement. Dimensional analysis. Kinematics of the particle: reference frames, displacement, velocity and acceleration vectors. One- dimensional motion. Motions in two and three dimensions. Relative motions. Principle of classic relativity. Dynamics of the particle. Newton’s law and its applications. Work and energy. Conservation of mechanical energy. Dynamics of particle systems. Collision’s dynamics. Dynamics of rigid body (hints).
The Laboratory module aims at providing the essential elements of the experimental method, demonstrating that physics is a quantitative science based on measurement of physical quantities and on the evaluation of the measurement uncertainties due to instrument resolution and random errors. The main topics covered in this module are the basics of the experimental method and the theory of measurement errors applied to the analysis of experimental data related to some simple experiments (such as measurement with different length tools, oscillation period of a pendulum simple, verification of elastic stretching law).
The recommended reference texts and the bibliography useful to preparing the final exam are:
A) Theory Module:
U. Gasparini, M. Margoni, F. Simonetto
Fisica. Meccanica e Termodinamica
Casa Editrice Piccin, Padova 2019 (I edizione)
ISBN 978-88-299-2972-6
P. Mazzoldi, M. Nigro, C. Voci
Fisica - Vol. 1: Meccanica – Termodinamica
EdiSES s.r.l., Napoli (Seconda edizione, ultima ristampa)
ISBN 88 7959 137 1
G. Mazzoldi, A. Saggion, C. Voci
Problemi di Fisica Generale: Meccanica e Termodinamica
Edizioni Libreria Cortina, Padova 1994 (ultima ristampa)
B) Laboratory Module
John R. Taylor
Introduzione all'analisi degli errori (lo studio delle incertezze nelle misure fisiche) (Edizione 2)
Zanichelli, 1999
Some notes and exercises useful for preparing for the final exam will be available on the web page:
https://intranet.univr.it/group/intranet/dashboarddidattica
The didactic methods of the teaching course of Physics I with Laboratory are differentiated for the two modules.
The Theory module, which is articulated in lessons and frontal exercises, is entirely delivered in the classroom. In order to help the student in the understanding and learning of the laws and principles of classical mechanics, systematic reference to phenomenology will be made during the frontal lessons. The course is supplemented by the solution in classroom of exercises and problems (kinematics and dynamics) in order to help the student to face and pass the written test of the final exam. In addition to the hours of the theory module, a tutorial activity is provided frontally in the classroom and specifically devoted to recalls and complements of analysis and vector geometry as well as to resolution of additional exercises and problems. Finally, in order to allow the student to verify his level of learning, a written test of "in-itinere" assessment, focused on the kinematics and dynamics of particle, is also scheduled.
The Laboratory module is divided into a part of lessons on the chalkboard about the experimental method and theory of the measurement errors, and a second part consisting of the experiments carried out by the students in the laboratory, for which there is a requirement for frequency. Laboratory activities are organized in groups of 4 students each and concern the execution of simple experiments involving the measurement of physical quantities, the analysis of collected data and the processing of related errors as well as the elaboration of a relationship with the discussion of the experiment results.
Bibliography
Activity | Author | Title | Publishing house | Year | ISBN | Notes |
---|---|---|---|---|---|---|
Laboratorio | John R. Taylor | Introduzione all'analisi degli errori (lo studio delle incertezze nelle misure fisiche) (Edizione 2) | Zanichelli | 1999 | 9788808176561 | |
Laboratorio | Paolo Fornasini | The Uncertainty in Physical Measurements (An introduction to data analysis in the Physics Laboratory) | Springer | 2008 | 9780387786490 | |
Esercitazioni | John R. Taylor | Introduzione all'analisi degli errori (lo studio delle incertezze nelle misure fisiche) (Edizione 2) | Zanichelli | 1999 | 9788808176561 | |
Esercitazioni | Paolo Fornasini | The Uncertainty in Physical Measurements (An introduction to data analysis in the Physics Laboratory) | Springer | 2008 | 9780387786490 | |
Esercitazioni | John R. Taylor | Introduzione all'analisi degli errori (lo studio delle incertezze nelle misure fisiche) (Edizione 2) | Zanichelli | 1999 | 9788808176561 |
Examination Methods
The examination of the teaching course of Physics I with Laboratory consists of a series of independent knowledge verifications for the two modules of Theory and of Laboratory, for each of which the evaluation is in thirty and will contribute to determining the overall rating according to the weight criterion based on the CFUs number of the specific module.
A) Theory Course:
The final exam consists of both a written test and an oral interview, to which the student is admitted after having overcome the written test. The written test is considered to be overcome when the related vote achieved by the student is not less than 18/30. Examination methods for the theory module are the same for attending and non-attending students.
The two written and oral tests are aimed at ascertaining the level of knowledge acquired by the student within the theory teaching module:
The written test concerns the resolution of some typical problems of mechanics of the particle, of particle systems, and of the rigid body, which include the application of laws and derived principles (both enunciated and demonstrated) during frontal lessons and systematically recalled during classroom exercises. Part of the written test may be carried out by passing the “in-itinere” assessment test.
The oral examination consists of an interview with questions about the classroom developed program related to the derivation of physical laws and the demonstration of the theorems and conservation principles of the particle dynamics, of particle systems and of the rigid body.
For the theoretical module, a cumulative evaluation is obtained by making the arithmetic mean of the evaluations obtained in both written and oral tests exceeded.
B) Laboratory Course:
For the lab module, an ongoing and a final group’s report on the simple pendulum experiment is evaluated, the evaluation being also expressed in thirty.
The overall assessment of the examination of the teaching course of Physics I with laboratory will be the average, weighted on the number of the module CFUs, of the marks achieved in the assessment tests for each of the two modules (Theory and Laboratory).
Type D and Type F activities
Modules not yet included
Career prospects
Module/Programme news
News for students
There you will find information, resources and services useful during your time at the University (Student’s exam record, your study plan on ESSE3, Distance Learning courses, university email account, office forms, administrative procedures, etc.). You can log into MyUnivr with your GIA login details: only in this way will you be able to receive notification of all the notices from your teachers and your secretariat via email and also via the Univr app.
Graduation
Documents
Title | Info File |
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1. Come scrivere una tesi | pdf, it, 31 KB, 29/07/21 |
2. How to write a thesis | pdf, it, 31 KB, 29/07/21 |
5. Regolamento tesi | pdf, it, 171 KB, 20/03/24 |
List of thesis proposals
theses proposals | Research area |
---|---|
Formule di rappresentazione per gradienti generalizzati | Mathematics - Analysis |
Formule di rappresentazione per gradienti generalizzati | Mathematics - Mathematics |
Proposte Tesi A. Gnoatto | Various topics |
Mathematics Bachelor and Master thesis titles | Various topics |
Attendance modes and venues
As stated in the Teaching Regulations , except for specific practical or lab activities, attendance is not mandatory. Regarding these activities, please see the web page of each module for information on the number of hours that must be attended on-site.
Part-time enrolment is permitted. Find out more on the Part-time enrolment possibilities page.
The course's teaching activities take place in the Science and Engineering area, which consists of the buildings of Ca‘ Vignal 1, Ca’ Vignal 2, Ca' Vignal 3 and Piramide, located in the Borgo Roma campus.
Lectures are held in the classrooms of Ca‘ Vignal 1, Ca’ Vignal 2 and Ca' Vignal 3, while practical exercises take place in the teaching laboratories dedicated to the various activities.
Career management
Student login and resources
Erasmus+ and other experiences abroad
Ongoing orientation for students
The committee has the task of guiding the students throughout their studies, guiding them in their choice of educational pathways, making them active participants in the educational process and helping to overcome any individual difficulties.
It is composed of professors Lidia Angeleri, Sisto Baldo, Marco Caliari, Paolo dai Pra, Francesca Mantese, and Nicola Sansonetto
To send an email to professors: name.surname@univr.it