Università di Pisa - Valutazione della didattica e iscrizione agli esami

Learning outcomes

Knowledge

The student who successfully completes the course will have the ability to analyze linear electric networks by using general methods in steady state or in transient behaviour. He or she will be able to describe the behaviour of multiterminal electric components in terms of voltage-current relationship and to manage the equivalent circuits to reduce the computation complexity.

Assessment criteria of knowledge

In the written exam (3 hours), the student must demonstrate his/her ability in solving a number (typically 4) of simple exercises covering the most important topics of the course. During the oral exam the student must be able to demonstrate his/her knowledge of the basic principles of the circuit theory and to discuss them using the appropriate terminology.

Methods:

Final oral exam
Final written exam

Further information:
The final exam consists in a written exam which is a prerequisite for the oral one. The minimum allowed score at the written exam is 18/30. The weighting is: final written exam 33.3%; final oral exam 66.6%.

In the written exam (3 hours), the student must demonstrate his/her ability in solving a number (typically 4) of simple exercises covering the most important topics of the course. During the oral exam the student must be able to demonstrate his/her knowledge of the basic principles of the circuit theory and to discuss them using the appropriate terminology.

Methods:

Final oral exam
Final written exam

Further information:
The final exam consists in a written exam which is a prerequisite for the oral one. The minimum allowed score at the written exam is 18/30. The weighting is: final written exam 33.3%; final oral exam 66.6%.

Teaching methods

Delivery: face to face

Learning activities:

attending lectures
individual study

Attendance: Advised

Teaching methods:

Lectures

Delivery: face to face

Attendance: Advised

Learning activities:

attending lectures
individual study

Teaching methods:

Lectures

Syllabus

Electric two-terminal components and their interconnection; Kirchhoff’s laws; substitution theorem; superposition theorem; Thevenin and Norton theorem; graph theory elements; network analysis methods: tableau, node voltage, mesh current. Sinusoidal waveforms; complex representation of sinusoidal signals; phasorial representation of voltage-current relationship; power theorems. Transient phenomena in circuits; Laplace transform; voltage-current relationship in Laplace domain; circuit response in Laplace domain; analysis of switching circuits. Multiterminal and multiport components; two-port components. Transformers. Electro-mechanical energy conversion. DC motor. Step motor.

Electric two-terminal components and their interconnection; Kirchhoff’s laws; substitution theorem; superposition theorem; Thevenin and Norton theorem; graph theory elements; network analysis methods: tableau, node voltage, mesh current. Sinusoidal waveforms; complex representation of sinusoidal signals; phasorial representation of voltage-current relationship; power theorems. Transient phenomena in circuits; Laplace transform; voltage-current relationship in Laplace domain; circuit response in Laplace domain; analysis of switching circuits. Multiterminal and multiport components; two-port components. Transformers.

Bibliography

Textbooks: Marco Raugi, Lezioni di Elettrotecnica. Edizioni Plus, Pisa Francesco Bertoncini, Eserciziario di Elettrotecnica. Edizioni Plus, Pisa. Recommended reading includes the following works: C.A. Desoer, E. S. Kuh, Basic circuit theory. McGrawHill. A. E. Fitzgerald, C. Kingsley Jr., S. Umans, Electric Machinery. McGrawHill. A. Longo, Analisi dei circuiti lineari, TEP, Pisa