Type A
|
Code |
Competences Specific | | A1 |
Integrate the fundamental technology, applications, services and systems of Computer Security and Artificial Intelligence,in a broader, multidisciplinary context.
|
| A3 |
Understand and know how to apply the functioning and organisation of the Internet, the technology and protocols of new-generation networks, the models of components, intermediate software and services.
|
| A4 |
Design, develop, manage and evaluate mechanisms to certify and guarantee security in handling information and access to it in a local or distributed processing system.
|
| A5 |
Analyse the information needs considered in an environment and execute all stages of the construction process of a secure information system.
|
| G1 |
Project, calculate and design products, processes and installations in the areas of Computer Security and Artificial Intelligence
|
| G2 |
Perform mathematical modelling, calculation and simulation in company technology and engineering centres, particularly in tasks of research, development and innovation in the areas of Computer Security and Artificial Intelligence
|
Type B
|
Code |
Competences Transversal | | CT2 |
Forming opinions on the basis of the efficient management and use of information |
| CT3 |
Solve complex problems critically, creatively and innovatively in multidisciplinary contexts. |
| CT4 |
Work in multidisciplinary teams and in complex contexts. |
| CT5 |
Communicate complex ideas effectively to all sorts of audiences |
| CT7 |
Apply ethical principles and social responsibility as a citizen and a professional. |
Type C
|
Code |
Competences Nuclear |
Type A
|
Code |
Learning outcomes |
| A1 |
Analyse the problems and their causes from a global focus in the medium and long term.
| | A3 |
Design network protocols and private services for computer and telematic applications.
| | A4 |
Design technology to guarantee privacy for scenarios of IT and telematics applications.
| | A5 |
Identify the components of a decision-making problem and know how to decide the most suitable decision-making model.
| | G1 |
Integrate theoretical knowledge into the realities to which it may apply.
| | G2 |
Apply the techniques learned in a specific context.
|
Type B
|
Code |
Learning outcomes |
| CT2 |
Master the tools for managing their own identity and activities in a digital environment.
Search for and find information autonomously using criteria of importance, reliability and relevance, which is useful for creating knowledge
Organise information with appropriate tools (online and face-to-face) so that it can be updated, retrieved and processed for re-use in future projects.
Produce information with tools and formats appropriate to the communicative situation and with complete honesty.
Use IT to share and exchange the results of academic and scientific projects in interdisciplinary contexts that seek knowledge transfer.
| | CT3 |
Recognise the situation as a problem in a multidisciplinary, research or professional environment, and take an active part in finding a solution.
Follow a systematic method with an overall approach to divide a complex problem into parts and identify the causes by applying scientific and professional knowledge.
Design a new solution by using all the resources necessary and available to cope with the problem.
Draw up a realistic model that specifies all the aspects of the solution proposed.
Assess the model proposed by contrasting it with the real context of application, find shortcomings and suggest improvements.
| | CT4 |
Understand the team’s objective and identify their role in complex contexts.
Communicate and work with other teams to achieve joint objectives.
Commit and encourage the necessary changes and improvements so that the team can achieve its objectives.
Trust in their own abilities, respect differences and use them to the team’s advantage.
| | CT5 |
Use the techniques of non-verbal communication and the expressive resources of the voice to make a good oral presentation.
Construct a discourse that is structured, clear, cohesive, rich and of the appropriate length, and which can transmit complex ideas.
Produce a persuasive, consistent and precise discourse that can explain complex ideas and effectively interact with the audience.
| | CT7 |
Be aware of gender and other inequalities in their activity as a URV student.
Analyse the major environmental problems from the perspective of their field of expertise in their student and/or professional activity.
Be able to give arguments based on social values and make proposals for the improvement of the community.
Be personally and professionally committed to applying the ethical and deontological concepts of their field of expertise.
|
Type C
|
Code |
Learning outcomes |
Topic |
Sub-topic |
1. Introduction |
a. Basic concepts of privacy
b. Legal principles
c. Privacy by design
d. Design strategies for privacy
|
2. Data privacy techniques |
a. Authentication
b. Attribute-based Credentials.
c. Secure and private communications
d. Anonymity and pseudo-anonymity in communications.
e. Privacy in data storages
f. Privacy-preserving computations.
g. Techniques for improving transparency.
h. Intervenability-enhancing techniques |
3. Privacy in data bases |
a. Owner's privacy del propietari (Privacy-preserving data mining).
b. User's privacy (private information retrieval).
c. Respondent's privacy (anonymization).
|
4. User's privacy |
a. Issues of private information retrieval (PIR).
b. Modifications to PIR based on single users.
c. Modifications to PIR based on p2p networks (P2P PIR).
d. Rational behaviour in P2P PIR.
|
5. Anonymization in data bases |
a. Basic concepts
b. Privacy models
c. Protection of tables
d. Protection of interactive data bases.
e. Protection of microdata
g. Evaluation of statistical disclosure control methods.
h. Anonymizing software |
Methodologies :: Tests |
|
Competences |
(*) Class hours
|
Hours outside the classroom
|
(**) Total hours |
Introductory activities |
|
1 |
1.5 |
2.5 |
Lecture |
|
26 |
38.5 |
64.5 |
Presentations / oral communications |
|
1 |
1.5 |
2.5 |
Problem solving, exercises in the classroom |
|
4 |
6 |
10 |
IT-based practicals |
|
10 |
15 |
25 |
Personal attention |
|
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
|
Description |
Introductory activities |
Difusió de l'actualitat sobre privadesa reflectida als mitjans |
Lecture |
Sessions de teoria |
Presentations / oral communications |
Presentacions a l'aula per part de grups de 2 o 3 alumnes de temes especialitzats concrets que els encarrega el professor. |
Problem solving, exercises in the classroom |
Resolució a l'aula per part de grups de 2 o 3 alumnes de problemes relacionats amb cada tema. |
IT-based practicals |
Implementació d'una tecnologia de preservació de la privadesa per part de cada grup de 2 o 3 alumnes. |
Personal attention |
Atenció al despatx prèvia visita concertada |
Description |
Students can request personal interviews with the teach as soon as they wish. |
Methodologies |
Competences
|
Description |
Weight |
|
|
|
|
Presentations / oral communications |
|
Presentations in the classroom by groups of 2 or 3 students on specialized subjects proposed by the teacher. |
15% |
Problem solving, exercises in the classroom |
|
Problem resolution in the classroom by groups of 2 or 3 students. |
5% |
IT-based practicals |
|
Implementation of a privacy-enhancing technology by each group of 2 or 3 students. |
20% |
Others |
|
Individual written examination |
60% |
|
Other comments and second exam session |
|
Basic |
|
o G. D’Acquisto, J. Domingo-Ferrer, P. Kikiras, V.
Torra, Y.-A. De Montjoye i A. Bourka (2015) Privacy by Design in Big Data –
An overview of privacy enhancing technologies in the era of big data analytics,
European Union Agency for Network and Information Security-ENISA. o G. Danezis, J. Domingo-Ferrer, M. Hansen, J.-H.
Hoepman, D. Le Métayer, R. Tirtea i S. Schiffner (2015) Privacy and Data
Protection by Design: From Policy to Engineering, European Union Agency for
Network and Information Security-ENISA. o J. Domingo-Ferrer, D. Sánchez i J. Soria-Comas
(2016) Database Anonymization: Privacy Models, Data Utility and Microaggregation-Based
Inter-Model Connections, Morgan & Claypool. o A. Hundepool, J. Domingo-Ferrer, L. Franconi, S.
Giessing, E. Schulte-Nordholt, K. Spicer i P.-P. de Wolf (2012) Statistical
Disclosure Control, Wiley. |
Complementary |
|
|
(*)The teaching guide is the document in which the URV publishes the information about all its courses. It is a public document and cannot be modified. Only in exceptional cases can it be revised by the competent agent or duly revised so that it is in line with current legislation. |
|