IDENTIFYING DATA 2023_24
Subject (*) PHYSICS Code 17234013
Study programme
Bachelor's Degree in Computer engineering (2010)
 Cycle 1st
Descriptors Credits Type Year Period
6 Basic Course First 1Q
Language
Català
Department Electronic, Electric and Automatic Engineering
Physical and Inorganic Chemistry
Coordinator
FERRÉ BORRULL, JOSÉ
 E-mail lluis.marsal@urv.cat
josep.ferre@urv.cat
francois.lime@urv.cat
xavier.batista@urv.cat
mariadelpilar.montero@urv.cat
Lecturers
MARSAL GARVÍ, LUIS FRANCISCO
FERRÉ BORRULL, JOSÉ
LIME , FRANÇOIS GILBERT MARIE
BATISTA CASANELLES, XAVIER
MONTERO RAMA, MARIA DEL PILAR
Web http://https://campusvirtual.urv.cat/
General description and relevant information <div>GENERAL DESCRIPTION OF THE SUBJECT:This subject will be taught in flipped classrooms. That is to say, theoretical classes will be taught online and face-to-face classes will be used to reinforce the more complex theoretical concepts and to carry out the more practical classes. Course about fundamental concepts on Physics related with Information Technologies Engineering </div>

Competences
Type A Code Competences Specific
 A2 Have knowledge of taking measurements, calculations, evaluations, valuations, surveys, studies, reports, work plans and other similar studies in IT.
 FB2 Understand and master the basic concepts of fields, waves and electromagnetism, theory of electric circuits, electronic circuits, the physical principles of semiconductors and logic families, electronic and photonic devices, and their application in solving problems inherent in engineering.
Type B Code Competences Transversal
 B2 Have knowledge in basic and technological subjects, which gives them the ability to learn new methods and theories, and the versatility to adapt to new situations.
Type C Code Competences Nuclear

Learning outcomes
Type A Code Learning outcomes
 A2 Measure physical magnitudes.
Estimate the error in the results of measurements.
Know and apply Coulomb's law.
Understand the concept of electrical capacity.
Knows how to apply the partnership laws of capacities.
Analyse basic DC circuits.
Know how to apply the laws of Kirchhoff and Thevenin and Norton theorems to analyze complex circuits.
Analyse basic circuits in a permanent sinusoidal system.
Understand the operation of basic electronic devices (diodes, LEDs and MOSFETs)
Know how to analyse and design basic electronic circuits.
Know, apply and design digital circuits such as logic gates or programmable digital circuits.
 FB2 Understand the concepts of electric fields and electric potential.
Analyse basic circuits in sinusoidal steady state.
Know how to apply the partnership laws of capacities.
Know how to apply Kirchhoff's laws and the theorems of Thevenin and Norton to analyze complex circuits
Analyze basic circuits in a permanent sinusoidal system
Understand the operation of basic electronic devices (diodes, LEDs and MOSFETs)
Know how to analyze and design basic electronic circuits
Know, apply and design digital circuits such as logic gates or programmable digital circuits
Measure physical magnitudes.
Estimate errors in measurement results
Know and apply the Coulomb Law.
Understand the concept of electric field and electric potential
Learn about the concept of electrostatic energy
Know the characteristics of the drivers
Distinguishes a dielectric material from another conductor
Understand the concept of electrical capacity
Know the basic concepts of electrocinetics.
Analyses basic circuits of DC.
Know the elements of electrical circuits capable of temporarily storing energy.
Understand the concept of electrical circuit transfer function and electrical resonance
Know the characteristics of semiconductor materials.
Understand the physical principle of electronic devices.
Type B Code Learning outcomes
 B2 Measure physical magnitudes.
Estimate the error in the results of measurements.
Know and apply Coulomb's law.
Understand the concepts of electric fields and electric potential.
Know the concept of electrostatic energy.
Know the characteristics of conductors.
Distinguish a dielectric material from another conductor.
Know the operating characteristics of the main electronic power devices.
Know how to apply the partnership laws of capacities.
Know the basic concepts of electrokinetics.
Know how to apply the laws of Kirchhoff and Thevenin and Norton theorems to analyze complex circuits.
Understand the concepts of electric circuit transfer and electrical resonance function.
Know the characteristics of semiconductor materials.
Understand the physical principle of electronic devices.
Know, apply and design digital circuits such as logic gates or programmable digital circuits.
Type C Code Learning outcomes

Contents
Topic Sub-topic
Electrostatics Electric Field
Electrostatic Energy and Potential
Conductor and Dielectric Materials
Capacitors
Direct Electric Current Electric Circuits
Kirchhoff Laws
Node Voltage method and Grid Current Method
Thévenin and Norton Laws
Steady Sinusoidal Regime Elements with Time Response
Transfer Function
Resonance
Fundamentals of Semiconductors Semiconducting Materials
Semiconductor Devices
Junction Diode and Light Emitting Diode
Field-Effect Transistor
Semiconductor Devices Applications Logical Families with CMOS Technology
Logic Programmable Devices

Planning
Methodologies  ::  Tests
  Competences (*) Class hours
 Hours outside the classroom
 (**) Total hours
Introductory activities
FB2
B2
 1 0 1
Lecture
FB2
B2
 28 30 58
Problem solving, exercises in the classroom
FB2
B2
 13 15 28
Laboratory practicals
A2
FB2
B2
 24 24 48
Previous study
A2
FB2
B2
 0 5 5
Personal attention
5 0 5
 
Mixed tests
FB2
B2
 4 0 4
Practical tests
A2
FB2
B2
 1 0 1
 
(*) On e-learning, hours of virtual attendance of the teacher.
(**) The information in the planning table is for guidance only and does not take into account the heterogeneity of the students.

Methodologies
Methodologies
  Description
Introductory activities Introdution to the Course
- Learning Objectives
- Methodologies
- Laboratory Practice Accomplishment
- Grading
- Bibliography
Lecture Explanation of the concepts related with the different course contents.
Problem solving, exercises in the classroom Practical class about the resolution of excercises related with the course contents.
Laboratory practicals Practical realization of different laboratory experiments where the different course concepts are applied and where instrumentation and measurement techniques are learnt.
Previous study Student previous work at home for the subsequent laboratory practice realization.
Personal attention Professor assistance within official hours

Personalized attention
Description
The student will have the opportunity to receive personalized attention within a published time frame in order to clarify any question it may arise.

Time reserved for individual attention and doubt solving with students. Due to the health emergency, this attention can be carried out through online meetings, previously appointed by e-mail, or with other online tools.