PHYSICS
Course objectives
- Conoscenza e comprensione Metodo scientifico, fisica classica, cinematica, dinamica, fluidi, termodinamica, elettromagnetismo, onde elettromagnetiche - Applicare conoscenza e comprensione Impostare lo svolgimento di un problema di fisica classica e risolverlo, saper descrivere il mondo fisico classico con le grandezze fisiche opportune e le loro relazioni, saper prevedere correttamente e quantitativamente, lo svolgersi di un processo fisico - Capacità critiche e di giudizio Capacità di individuare, in forma scritta, per un problema, le grandezze fisiche coinvolte, le loro relazioni e i rapporti numerici esatti o approssimati, tramite esempi in aula relazionati alla parte teorica svolta, esercitazioni scritte durante il corso, aiuto del tutor allo svolgimento degli esercizi e prova scritta finale. - Capacità comunicative Tramite domande specifiche su previsioni riguardanti la teoria fisica spiegata, si incoraggiano gli studenti a descrivere il quadro fisico e gli sviluppi della situazione proposta. Prova orale finale dove lo studente è in grado di descrivere a parole e in formule i principali argomenti della materia e le loro implicazioni - Capacità di apprendimento In maniera autonoma lo studente è in grado di riconoscere i termini essenziali di un fenomeno fisico classico, quali sono le grandezze fisiche in gioco, le loro relazioni e l’evoluzione nel tempo del sistema, di ipotizzare eventualmente le modifiche per ottenere un diverso risultato desiderato, impostare e risolvere quantitativamente i problemi fisici che si trova di fronte o che vuole impostare. Relazionarsi costruttivamente agli apparati di misura necessari per lo studio quantitativo del fenomeno stesso.
Channel 1
MASSIMO GERMANO
Lecturers' profile
Program - Frequency - Exams
Course program
Study of some physics systems devoting particular attention to the methodological aspects of observations and measures:
1) mass measurements and lengths; use of tables and graphs
2) geometric optics and angular measurements
3) dynamometer and sonar; kinematic and force measures
4) periodic phenomena: kinematic and dynamic study of the pendulum; use of a photogate
5) periodic phenomena: static and dynamic study of a spring; use of a stopwatch. Introduction to elastic quantities
6) study of damped and forced oscillations by means of signal generators and oscilloscope with variable parameters RLC circuit. Beats, Lissajous figures
7) study of resonance in a vibrating lamina by sonar
8) kinematic and dynamic study of rotary motions: angular sensor and torsion pendulum
9) study of an isothermal transformation (measures of pressure, volume and temperature); display of magnetic field lines (compass) and its measurement (Hall probe)
10) measurement of the specific heat of the water (calorimeter) and determination of time constants of various orders of magnitude
Prerequisites
The course requires no prior knowledge. However, having followed the courses in mathematical analysis and physics allows a better assimilation and effectiveness of the course contents
Frequency
In-person course attendance.
Attendance is not mandatory, but strongly recommended.
Exam mode
The student must be able to pass a written test consisting of solving exercises in mechanics, thermodynamics and electromagnetism.
Upon achieving a satisfactory result in the written examination, the student's evaluation will be completed by an oral test.
Lesson mode
In-person teaching, with lectures at the blackboard and slides.
MASSIMO GERMANO
Lecturers' profile
Program - Frequency - Exams
Course program
Study of some physics systems devoting particular attention to the methodological aspects of observations and measures:
1) mass measurements and lengths; use of tables and graphs
2) geometric optics and angular measurements
3) dynamometer and sonar; kinematic and force measures
4) periodic phenomena: kinematic and dynamic study of the pendulum; use of a photogate
5) periodic phenomena: static and dynamic study of a spring; use of a stopwatch. Introduction to elastic quantities
6) study of damped and forced oscillations by means of signal generators and oscilloscope with variable parameters RLC circuit. Beats, Lissajous figures
7) study of resonance in a vibrating lamina by sonar
8) kinematic and dynamic study of rotary motions: angular sensor and torsion pendulum
9) study of an isothermal transformation (measures of pressure, volume and temperature); display of magnetic field lines (compass) and its measurement (Hall probe)
10) measurement of the specific heat of the water (calorimeter) and determination of time constants of various orders of magnitude
Prerequisites
The course requires no prior knowledge. However, having followed the courses in mathematical analysis and physics allows a better assimilation and effectiveness of the course contents
Frequency
In-person course attendance.
Attendance is not mandatory, but strongly recommended.
Exam mode
The student must be able to pass a written test consisting of solving exercises in mechanics, thermodynamics and electromagnetism.
Upon achieving a satisfactory result in the written examination, the student's evaluation will be completed by an oral test.
Lesson mode
In-person teaching, with lectures at the blackboard and slides.
Channel 2
MASSIMO PETRARCA
Lecturers' profile
Program - Frequency - Exams
Course program
Study of some physics systems devoting particular attention to the methodological aspects of observations and measures:
1) mass measurements and lengths; use of tables and graphs
2) geometric optics and angular measurements
3) dynamometer and sonar; kinematic and force measures
4) periodic phenomena: kinematic and dynamic study of the pendulum; use of a photogate
5) periodic phenomena: static and dynamic study of a spring; use of a stopwatch. Introduction to elastic quantities
6) study of damped and forced oscillations by means of signal generators and oscilloscope with variable parameters RLC circuit. Beats, Lissajous figures
7) study of resonance in a vibrating lamina by sonar
8) kinematic and dynamic study of rotary motions: angular sensor and torsion pendulum
9) study of an isothermal transformation (measures of pressure, volume and temperature); display of magnetic field lines (compass) and its measurement (Hall probe)
10) measurement of the specific heat of the water (calorimeter) and determination of time constants of various orders of magnitude
Prerequisites
The course requires no prior knowledge. However, having followed the courses in mathematical analysis and physics allows a better assimilation and effectiveness of the course contents
Frequency
In-person course attendance.
Attendance is not mandatory, but strongly recommended.
Exam mode
The student must be able to pass a written test consisting of solving exercises in mechanics, thermodynamics and electromagnetism.
Upon achieving a satisfactory result in the written examination, the student's evaluation will be completed by an oral test.
Lesson mode
In-person teaching, with lectures at the blackboard and slides.
MASSIMO PETRARCA
Lecturers' profile
MARCO TOPPI
Lecturers' profile
Program - Frequency - Exams
Course program
Study of some physics systems devoting particular attention to the methodological aspects of observations and measures:
1) mass measurements and lengths; use of tables and graphs
2) geometric optics and angular measurements
3) dynamometer and sonar; kinematic and force measures
4) periodic phenomena: kinematic and dynamic study of the pendulum; use of a photogate
5) periodic phenomena: static and dynamic study of a spring; use of a stopwatch. Introduction to elastic quantities
6) study of damped and forced oscillations by means of signal generators and oscilloscope with variable parameters RLC circuit. Beats, Lissajous figures
7) study of resonance in a vibrating lamina by sonar
8) kinematic and dynamic study of rotary motions: angular sensor and torsion pendulum
9) study of an isothermal transformation (measures of pressure, volume and temperature); display of magnetic field lines (compass) and its measurement (Hall probe)
10) measurement of the specific heat of the water (calorimeter) and determination of time constants of various orders of magnitude
Prerequisites
The course requires no prior knowledge. However, having followed the courses in mathematical analysis and physics allows a better assimilation and effectiveness of the course contents
Frequency
In-person course attendance.
Attendance is not mandatory, but strongly recommended.
Exam mode
The student must be able to pass a written test consisting of solving exercises in mechanics, thermodynamics and electromagnetism.
Upon achieving a satisfactory result in the written examination, the student's evaluation will be completed by an oral test.
Lesson mode
In-person teaching, with lectures at the blackboard and slides.
MARCO TOPPI
Lecturers' profile
Program - Frequency - Exams
Course program
Study of some physics systems devoting particular attention to the methodological aspects of observations and measures:
1) mass measurements and lengths; use of tables and graphs
2) geometric optics and angular measurements
3) dynamometer and sonar; kinematic and force measures
4) periodic phenomena: kinematic and dynamic study of the pendulum; use of a photogate
5) periodic phenomena: static and dynamic study of a spring; use of a stopwatch. Introduction to elastic quantities
6) study of damped and forced oscillations by means of signal generators and oscilloscope with variable parameters RLC circuit. Beats, Lissajous figures
7) study of resonance in a vibrating lamina by sonar
8) kinematic and dynamic study of rotary motions: angular sensor and torsion pendulum
9) study of an isothermal transformation (measures of pressure, volume and temperature); display of magnetic field lines (compass) and its measurement (Hall probe)
10) measurement of the specific heat of the water (calorimeter) and determination of time constants of various orders of magnitude
Prerequisites
The course requires no prior knowledge. However, having followed the courses in mathematical analysis and physics allows a better assimilation and effectiveness of the course contents
Frequency
In-person course attendance.
Attendance is not mandatory, but strongly recommended.
Exam mode
The student must be able to pass a written test consisting of solving exercises in mechanics, thermodynamics and electromagnetism.
Upon achieving a satisfactory result in the written examination, the student's evaluation will be completed by an oral test.
Lesson mode
In-person teaching, with lectures at the blackboard and slides.
- Lesson code1017400
- Academic year2025/2026
- CourseComputer and Control Engineering
- CurriculumInformatica
- Year1st year
- Semester2nd semester
- SSDFIS/01
- CFU12