Degree Course: Electronic engineering for industry and innovation
A.Y. 2016/2017
Autonomia di giudizio
Nell'ambito delle proprie competenze i laureati saranno in grado di assumere decisioni autonome in progetti anche di grandi dimensioni e di partecipare attivamente alle responsabilità di decisione in contesti multidisciplinari.
Tale obiettivo sarà perseguito tramite i corsi di insegnamento ad orientamento progettuale e la tesi di laurea magistrale e sarà verificato con gli esami di profitto e l'esame di laurea magistrale.Abilità comunicative
I laureati magistrali saranno in grado di comunicare in maniera efficace le proprie idee e interagire su argomenti e tematiche sia strettamente disciplinari che interdisciplinari, anche ad alto livello.
Tale obiettivo sarà perseguito attraverso gli esami, gli eventuali tirocinii e la prova finale di laurea e sarà verificato con gli esami di profitto e l'esame di laurea magistrale.Capacità di apprendimento
I laureati saranno in grado di aggiornarsi professionalmente in maniera autonoma, mentre gli studenti migliori e più motivati potranno procedere anche nel campo della ricerca scientifica.
Tale obiettivo sarà perseguito attraverso l'introduzione di componenti seminariali, di ricerca bibliografica e di elementi di ricerca scientifica all'interno di specifici corsi di insegnamento e attraverso la tesi di laurea magistrale.
Sarà verificato attraverso i relativi esami di profitto e l'esame di laurea magistrale.Requisiti di ammissione
Per l'accesso alla Laurea magistrale in Ingegneria elettronica per l'industria e l'innovazione è richiesto il possesso delle lauree di primo livello nelle Classi dell' Ingegneria dell'Informazione (di cui al D.M.509/1999 o D.M.270/2004) con riconoscimento integrale dei 180 crediti previsti nel piano di studi di primo livello.
Può avvenire anche a partire dalle lauree delle classi L-9 Ingegneria industriale e L-30 Scienze e tecnologie fisiche attraverso un'attenta valutazione del curriculum dello studente.
Le modalità per la verifica delle conoscenze richieste per l'accesso sono definite all'interno del Regolamento Didattico.
E' inoltre richiesto allo studente di essere capace di comunicare
efficacemente, in forma scritta e orale, in almeno una lingua europea diversa dall'italiano.
Il riconoscimento dell'idoneità linguistica è effettuato sulla base del superamento di prove di verifica effettuate presso il Centro Linguistico di Ateneo di Roma Tre o dellAteneo di provenienza, come specificato nel Regolamento Didattico del Corso di laurea Magistrale.Prova finale
La prova finale si realizza attraverso la presentazione e discussione di una relazione scritta avente per oggetto un progetto originale sviluppato dallo studente in modo autonomo sotto la guida di relatori e co-relatori nominati dal collegio didatticoOrientamento in ingresso
Le azioni di orientamento in ingresso sono improntate alla realizzazione di processi di raccordo con la scuola media secondaria.
Si concretizzano in attività di carattere informativo sui Corsi di Studio (CdS) dell’Ateneo ma anche come impegno condiviso da Scuola e Università per favorire lo sviluppo di una maggiore consapevolezza da parte degli studenti nel compiere scelte coerenti con le proprie conoscenze, competenze, attitudini e interessi.
Le attività promosse si articolano in:
a) seminari e attività formative realizzate in collaborazione con i docenti della scuola;
b) incontri e manifestazioni informative rivolte alle future matricole;
c) sviluppo di servizi on line per l’orientamento e l’auto-orientamento.
Tra le attività svolte in collaborazione con le scuole per lo sviluppo di una maggiore consapevolezza nella scelta, il “progetto di auto-orientamento” è un intervento significativo che consente di promuovere un raccordo particolarmente qualificato con alcune scuole medie superiori che insistono sul territorio limitrofo a Roma Tre.
Il progetto, infatti, è articolato in incontri svolti presso le scuole dagli esperti dell’Ufficio Orientamento con la collaborazione di studenti seniores ed è finalizzato a sollecitare nelle future matricole una riflessione sui propri punti di forza e sui criteri di scelta (gli incontri si svolgono nel periodo ottobre-dicembre).
La presentazione dell’offerta formativa agli studenti delle scuole superiori prevede tre eventi principali, distribuiti nel corso dell’anno accademico, ai quali partecipano tutti i CdS.
Salone dello studente “Campus orienta”, si svolge presso la fiera di Roma fra ottobre e novembre e coinvolge tradizionalmente tutti gli Atenei del Lazio e molti Atenei fuori Regione, Enti pubblici e privati che si occupano di Formazione e Lavoro.
Roma Tre partecipa a questo evento con un proprio spazio espositivo e con conferenze di presentazione dell’offerta formativa dell’Ateneo.
Le Giornate di Vita Universitaria (GVU) si svolgono ogni anno da gennaio a marzo e sono rivolte agli studenti degli ultimi due anni della scuola secondaria superiore.
Si svolgono in tutti i Dipartimenti dell’Ateneo e costituiscono una importante occasione per le future matricole per vivere la realtà universitaria.
Gli incontri sono strutturati in modo tale che accanto alla presentazione dei CdS, gli studenti possano anche fare un’esperienza diretta di vita universitaria con la partecipazione ad attività didattiche, laboratori, lezioni o seminari, alle quali partecipano anche studenti seniores che svolgono una significativa mediazione di tipo tutoriale.
Partecipano annualmente oltre 6.000 studenti delle secondarie.
Orientarsi a Roma Tre rappresenta la manifestazione che chiude le annuali attività di orientamento in ingresso e si svolge in Ateneo a luglio di ogni anno.
L’evento accoglie mediamente circa 3.000 studenti romani e non solo, che partecipano per mettere definitivamente a fuoco la loro scelta universitaria.
Oltre all’offerta formativa sono presentati tutti i principali servizi di Roma Tre rivolti agli studenti e le segreterie didattiche sono a disposizione per tutte le informazioni relative alle pratiche di immatricolazione.
In tutte le manifestazioni di presentazione dell’offerta formativa, sono illustrati anche i vari servizi on line che possono aiutare gli studenti nella scelta: dai siti web dei Dipartimenti al sito del POS (Prove di Orientamento Simulate) che consente alle future matricole di autovalutarsi rispetto ai requisiti di accesso per tutti i CdS di Roma Tre.
Infine, in tutte le manifestazioni che si svolgono in Ateneo sono somministrati ai partecipanti questionari di soddisfazione che vengono elaborati ed utilizzati per proporre miglioramenti all’organizzazione degli eventi.Il Corso di Studio in breve
Obiettivo del Corso di Laurea Magistrale in Ingegneria elettronica per l’industria e l’innovazione è la formazione di una figura professionale capace di progettare, sviluppare, programmare e gestire tecnologie, componenti e sistemi elettronici nel vasto campo di applicazioni della moderna Ingegneria elettronica.
La figura professionale è quella di un laureato di alto livello che guarda al futuro ma anche alle necessità correnti dell’Industria elettronica, esperto dei singoli componenti, da cui dipende in modo critico la spinta innovativa, ma con una solida competenza anche a livello di sistema, da cui dipende la capacità di traduzione in applicazioni dei sistemi elettronici analogici e digitali quali parti indivisibili di una catena di regolazione, ottimizzazione e supporto ai processi industriali.
Il Corso di Laurea si propone quindi di formare un ingegnere capace di progettare sistemi embedded a partire dalla definizione delle specifiche fino alla fase realizzativa dei prototipi; collaudare e verificare la sicurezza e l’affidabilità dei componenti e sistemi sviluppati, identificare e risolvere problemi di pianificazione, progettazione, ingegnerizzazione, produzione e monitoraggio delle prestazioni di componenti, dispositivi, apparati, sistemi e servizi in campo elettronico.
Questo ingegnere conosce le tecnologie dei dispositivi e le metodologie finalizzate all’innovazione dei processi produttivi e all’ottimizzazione delle applicazioni proprie dell’Ingegneria elettronica, ma ha anche la capacità di progettare e gestire sistemi e servizi nel settore delle Amministrazioni pubbliche e delle imprese private.
L’ingegnere elettronico per l’industria e l’innovazione è dunque preparato ad affrontare gli aspetti scientifici specifici dell’ingegneria moderna che, sempre più interdisciplinari, richiedono la conoscenza di dispositivi, sistemi e metodi basati su una tecnologia e una comprensione scientifica d’avanguardia oltre la padronanza delle relative metodologie di analisi e realizzazione.
Lo studente espliciterà le proprie scelte al momento della presentazione,
tramite il sistema informativo di ateneo, del piano di completamento o del piano di studio individuale,
secondo quanto stabilito dal regolamento didattico del corso di studio.
FIRST YEAR
First semester
|
Course
|
Credits
|
Scientific Disciplinary Sector Code
|
Contact Hours
|
Exercise Hours
|
Laboratory Hours
|
Personal Study Hours
|
Type of Activity
|
Language
|
|
20801707 -
CHEMISTRY OF TECHNOLOGY
(objectives)
The course has the task of increasing the knowledge in chemical process technology related to electronics, both well-established industrially but also more innovative ones.
|
6
|
CHIM/07
|
48
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
Optional Group:
1 INSEGNAMENTO OBBLIGATORIO - (show)
|
9
|
|
|
|
|
|
|
|
|
20801720 -
THEORY OF MEASUREMENT AND METROLOGY
(objectives)
From the structure of philosophical and scientific method and results of the theoretical definition of absolute measure, one searches the operation of measurement technique involving the definition of standard in metrology. The scope of the international system of measurement, with definition of roles of bodies regulators and for those of primary metrology, is explored looked by the representational theory point of view. A special attention is given in the handling uncertainty and its components and accuracy of rightness.
|
9
|
ING-INF/07
|
54
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20801862 -
ANTENNAS AND PROPAGATION
|
Also available in another semester or year
|
|
20810068 -
ELECTRONIC DESIGN
|
Also available in another semester or year
|
|
|
20802050 -
CIRCUITS AND ELECTRICAL SYSTEMS
(objectives)
The course aims at providing students of the master degree the basic concepts of analysis methods of systems for the generation, the conversion and the transmission of electrical energy. The guiding principles of the design of systems and equipment for power electrical distribution and for hv and lv electrical installations are also treated.
|
9
|
ING-IND/31
|
72
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
|
20810065 -
OPTICS AND QUANTUM ELECTRONICS
(objectives)
- to make the student familiar with the principal experimental results who led to the reformulation of physics needed in order for atomic phenomena to be adequately described;
- to introduce students to the concept wave function and to Schroedinger's equation;
- to provide those mathematical tools needed to solve some problems concerning simple quantum systems (potential well, harmonic oscillator);
- to provide a quantum interpretation about the behaviour of some complex systems (like for instance
hydrogen-like atoms, spin, field quantization, band theory, effective mass)
|
|
|
20810065-1 -
QUANTUM ELECTRONICS
(objectives)
- to make the student familiar with the principal experimental results who led to the reformulation of physics needed in order for atomic phenomena to be adequately described;
- to introduce students to the concept wave function and to Schroedinger's equation;
- to provide those mathematical tools needed to solve some problems concerning simple quantum systems (potential well, harmonic oscillator);
- to provide a quantum interpretation about the behaviour of some complex systems (like for instance
hydrogen-like atoms, spin, field quantization, band theory, effective mass)
|
6
|
FIS/03
|
36
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
|
20810065-2 -
OPTICS
(objectives)
- to make the student familiar with the principal experimental results who led to the reformulation of physics needed in order for atomic phenomena to be adequately described;
- to introduce students to the concept wave function and to Schroedinger's equation;
- to provide those mathematical tools needed to solve some problems concerning simple quantum systems (potential well, harmonic oscillator);
- to provide a quantum interpretation about the behaviour of some complex systems (like for instance
hydrogen-like atoms, spin, field quantization, band theory, effective mass)
|
6
|
FIS/03
|
48
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
|
Optional Group:
Opzionali - (show)
|
9
|
|
|
|
|
|
|
|
|
Second semester
|
Course
|
Credits
|
Scientific Disciplinary Sector Code
|
Contact Hours
|
Exercise Hours
|
Laboratory Hours
|
Personal Study Hours
|
Type of Activity
|
Language
|
|
20801696 -
MICROWAVES
(objectives)
The propagation of electromagagnetic waves in guiding structures in the frequency region of microewaves is presented and deeply studied. Moreover an introduction to microwave networks and to linear antennas is done
|
9
|
ING-INF/02
|
72
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20801888 -
POWER ELECTRONICS
(objectives)
Understanding configurations and operating characteristics of static power apparatus that use semiconductor devices for achieving the controlled conversion of electric energy. Learning how to use of electronic power converters in the main areas of application such as electrical drives, uninterrupted power supply (ups) systems, distributed generation of electric power from renewable sources and improved management of energy storage systems.
|
9
|
ING-IND/32
|
72
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
|
20802093 -
PROGRAMMABLE ELECTRONIC SYSTEMS
(objectives)
The course allows the students to acquire the knowledge and the ability to apply design techniques for digital systems in general and in particular with programmable platforms. The course analyzes the typical structure and the technology of modern programmable electronic components, develops the ability to design a digital electronic system from specifications to implementation and experimental verification of the behavior, the ability to draft a technical report on the design and characterization of a component or digital electronic system.
|
9
|
ING-INF/01
|
72
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20810069 -
SOLID STATE MEASURING DEVICES
(objectives)
The student is expected to develop an understanding of the basic processes at the foundation of the solid-state devices, in order to understand the appropriate use and limitations of several families of measuring devices.
The course introduces the basic properties of metals, semiconductors, dielectrics etc. that are at the heart of the correct operation of many solid-state sensors and measuring devices. On the basis of these general properties, the prominent features of solid-state sensors (for magnetic field, temperature, radiation,...) are described. Finally, some solid-state devices of interest to metrology are introduced.
|
9
|
ING-INF/07
|
72
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
Optional Group:
OPZIONALE - (show)
|
12
|
|
|
|
|
|
|
|
|
SECOND YEAR
First semester
|
Course
|
Credits
|
Scientific Disciplinary Sector Code
|
Contact Hours
|
Exercise Hours
|
Laboratory Hours
|
Personal Study Hours
|
Type of Activity
|
Language
|
|
Optional Group:
1 INSEGNAMENTO OBBLIGATORIO - (show)
|
9
|
|
|
|
|
|
|
|
|
20801720 -
THEORY OF MEASUREMENT AND METROLOGY
|
Also available in another semester or year
|
|
20801862 -
ANTENNAS AND PROPAGATION
(objectives)
The course aims to complete training on antennas received in previous courses, particularly in relation to the study and design of aperture antennas, planar antennas and arrays of antennas. It also introduces the problem of electromagnetic scattering from structures present in the air or in the soil. Areas of application: biomedical industry, electrical, electronics and telecommunications.
|
9
|
ING-INF/02
|
72
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20810068 -
ELECTRONIC DESIGN
|
Also available in another semester or year
|
|
|
Optional Group:
Opzionali - (show)
|
9
|
|
|
|
|
|
|
|
|
20801862 -
ANTENNAS AND PROPAGATION
(objectives)
The course aims to complete training on antennas received in previous courses, particularly in relation to the study and design of aperture antennas, planar antennas and arrays of antennas. It also introduces the problem of electromagnetic scattering from structures present in the air or in the soil. Areas of application: biomedical industry, electrical, electronics and telecommunications.
|
9
|
ING-INF/02
|
72
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20801912 -
METAMATERIALS
|
Also available in another semester or year
|
|
20802052 -
FUNDAMENTALS OF PHOTOVOLTAICS
|
Also available in another semester or year
|
|
20802122 -
Sensors and transducers
(objectives)
The aim of the course is to describe the principles of operation of the main ultrasonic sensors and transducers. They will be provided to students the basic knowledge of the acousto-electronic, in order to give the tools for the analysis and simulation of transduction systems. Particular emphasis will be given to the capacitive micromachined transducers on silicon, which represent the state of the art of the microsensors integrated technology. During the course there is a part of practice in the laboratory.
|
6
|
ING-INF/01
|
36
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20802051 -
Electromagnetic sensing of the environment
|
Also available in another semester or year
|
|
20810026 -
MICROWAVE COMPONENTS
(objectives)
The student will learn how to understand properties and design of various microwave components (both passive and active), circuits, used in basic rf/microwave frontend functional blocks and learn how to apply these properties for particular designs. The student will learn how to design basic rf/microwave frontend functional blocks using both analytical tools and advanced computer-aided design tools. The student will, through the lab sessions, develop an intuition and physical feeling for microwave phenomenon and to get first hands-on experience with microwaves components and equipment.
|
6
|
ING-INF/02
|
36
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20810063 -
IMAGE PROCESSING
|
Also available in another semester or year
|
|
20810064 -
ELECTRONICS OF SOLID STATE DEVICES
(objectives)
The course is designed to illustrate the operation of major semiconductor devices based on homo and heterojunctions; their connection to the outside world, the formation of ohmic and schottky contacts used in micro and nanoelectronics. The student will study the characteristics at low and high frequency of mesfet, mosfet, bjt, hbt, and those most advanced structures using quantum confinement of charge carriers as hemt, phemt and modfet based on gaas / algaas e gan / algan. .
|
6
|
ING-INF/01
|
36
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20810067 -
ELECTRONICS LABORATORY
|
Also available in another semester or year
|
|
20810068 -
ELECTRONIC DESIGN
|
Also available in another semester or year
|
|
20801720 -
THEORY OF MEASUREMENT AND METROLOGY
|
Also available in another semester or year
|
|
|
Optional Group:
OPZIONALE - (show)
|
12
|
|
|
|
|
|
|
|
|
Second semester
|
Course
|
Credits
|
Scientific Disciplinary Sector Code
|
Contact Hours
|
Exercise Hours
|
Laboratory Hours
|
Personal Study Hours
|
Type of Activity
|
Language
|
|
Optional Group:
1 INSEGNAMENTO OBBLIGATORIO - (show)
|
9
|
|
|
|
|
|
|
|
|
20801720 -
THEORY OF MEASUREMENT AND METROLOGY
|
Also available in another semester or year
|
|
20801862 -
ANTENNAS AND PROPAGATION
|
Also available in another semester or year
|
|
20810068 -
ELECTRONIC DESIGN
(objectives)
The aim of this course is to provide the fundamentals of electronic design in terms of both synthesis and analysis methodologies. The course is focused on electronic system architecture for the processing of signals coming from front-end amplifiers and directed to output stages, after suitable analog to digital (A/D) and digital to analog (D/A) conversion. Special attention will be given to the definition of design specifications, including DC and AC, distortion and noise, as well as A/D and D/A conversion techniques. The course includes a detailed analysis of a set of projects with applications in consumer electronics, telecommunications, industrial and medical electronics.
|
9
|
ING-INF/01
|
54
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
|
Optional Group:
Opzionali - (show)
|
9
|
|
|
|
|
|
|
|
|
20801862 -
ANTENNAS AND PROPAGATION
|
Also available in another semester or year
|
|
20801912 -
METAMATERIALS
(objectives)
The course aim at giving the student the tools for the analysis and the design of innovative micro- and nano-electronics devices based on the employment of metamaterials.
|
9
|
ING-INF/02
|
54
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20802052 -
FUNDAMENTALS OF PHOTOVOLTAICS
(objectives)
The course provides basic understanding of physics and technology of photovoltaic devices, from first generation silicon solar cells (crystalline, polycrystalline, amorphous) to second (thin-films technology) and third generation (multi-junction) solar cells. The course deals with devices, modules and systems and includes an introduction to storage and distribution of solar energy. The objective is to provide the specific knowledge for the design, analysis and characterization of solar cells and systems. The course includes a number of laboratory experiments on solar cells and SPICE simulations
|
6
|
ING-INF/01
|
36
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20802122 -
Sensors and transducers
|
Also available in another semester or year
|
|
20802051 -
Electromagnetic sensing of the environment
(objectives)
1) indoor/outdoor electromagnetic field evaluation; 2) antenna characterization (far-field, near-field); 3) electromagnetic field mesaurement; 4) use of electromagnetic cad; 5) normatives.
|
6
|
ING-INF/02
|
48
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20810026 -
MICROWAVE COMPONENTS
|
Also available in another semester or year
|
|
20810063 -
IMAGE PROCESSING
(objectives)
This course aims at providing the students with the fundamentals techniques of representation, processing and communications of digital images.
|
6
|
ING-INF/01
|
36
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20810064 -
ELECTRONICS OF SOLID STATE DEVICES
|
Also available in another semester or year
|
|
20810067 -
ELECTRONICS LABORATORY
(objectives)
Electronics Laboratory is an experimental lab course that provides the fundamentals of electronic design, simulation, construction, test and debugging of analog and digital electronic circuits. Lectures will be devoted to design strategies and methods. The intensive use of PSpice simulation will allow fast circuit verification before its fabrication. The course will include several measurement techniques to perform the experimental tests. Expected results are the ability to design electronic circuits for both analog and digital signal processing, the knowledge of the characteristics of the major electronic components and skills in the use of PSpice simulator, combined with the ability to measure electrical quantities with laboratory instrumentation.
|
6
|
ING-INF/01
|
36
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20810068 -
ELECTRONIC DESIGN
(objectives)
The aim of this course is to provide the fundamentals of electronic design in terms of both synthesis and analysis methodologies. The course is focused on electronic system architecture for the processing of signals coming from front-end amplifiers and directed to output stages, after suitable analog to digital (A/D) and digital to analog (D/A) conversion. Special attention will be given to the definition of design specifications, including DC and AC, distortion and noise, as well as A/D and D/A conversion techniques. The course includes a detailed analysis of a set of projects with applications in consumer electronics, telecommunications, industrial and medical electronics.
|
9
|
ING-INF/01
|
54
|
-
|
-
|
-
|
Core compulsory activities
|
ITA |
|
20801720 -
THEORY OF MEASUREMENT AND METROLOGY
|
Also available in another semester or year
|
|
|
Optional Group:
OPZIONALE - (show)
|
12
|
|
|
|
|
|
|
|
|
20802142 -
Optimization and Scientific Computing
(objectives)
The course objective is to provide to students suitable lectures about deterministic and stochastic optimization methods regarding, in particular, evolutionary computation and softcomputing at large. During the course several applications on circuits and power systems are described for inverse problem as well.
|
6
|
ING-IND/31
|
36
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
|
20802094 -
SUPERCONDUCTIVITY WITH APPLICATIONS
|
Also available in another semester or year
|
|
20801749 -
ELECTRICAL ENERGETICS
(objectives)
The course provides to supply the students the basic knowledge of the energy technologies related to electric energy generation taking into account the energy needs in the industrial and civil sector. Basic instruments and information will be supplied to better understand problems related the distributed energy generation particulary concerning electricity produced by renewable energy sources (photovoltaic, wind, fuelcell – hydrogen, etc.) Including energy storage systems. For the above mentioned energy systems will be analyzed and discussed the problems related to the grid connection and all active components and systems to assure the best quality of the energy distributed.
|
6
|
ING-IND/32
|
48
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
|
20801920 -
STATIC POWER CONVERTORS DESIGN
(objectives)
The lessons will present dynamic modeling and methodologies for power electronic converters design. The students will face design problems with reference to technical specifications and required performances.
|
9
|
ING-IND/32
|
54
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
|
20810070 -
SUSTAINABILITY AND ENVIRONMENTAL IMPACT
|
Also available in another semester or year
|
|
20810066 -
ELECTROTECHNICS FOR ENERGY SYSTEMS
(objectives)
The aim of the course is to discuss the main energy conversions to deliver, to manage and to storing electrical energy. The optimization of the different systems for enhancing efficiency and the environmental impact as weel as Renewable energies and the energy storage will be widely analyzed.
|
6
|
ING-IND/31
|
36
|
-
|
-
|
-
|
Related or supplementary learning activities
|
ITA |
|
20801923 -
ELECTRICAL SAFETY
|
Also available in another semester or year
|
|
|
20802015 -
TRAINING
|
3
|
|
-
|
-
|
-
|
-
|
Per stages e tirocini presso imprese, enti pubblici o privati, ordini professionali (art.10, comma 5, lettera e)
|
ITA |
|
20802113 -
ART. 10, COMMA 5, LETTERA D
|
3
|
|
-
|
-
|
-
|
-
|
Other activities
|
ITA |
|
20802091 -
FINAL EXAM
|
9
|
|
-
|
-
|
-
|
-
|
Final examination and foreign language test
|
ITA |
|
20810000 -
A SCELTA STUDENTE
|
12
|
|
72
|
-
|
-
|
-
|
Elective activities
|
ITA |
Università Roma Tre