Study programme competencies |
Code
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Study programme competences / results
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A28 |
Capacidade de identificar e analizar problemas, e deseñar, desenvolver, implementar, verificar e documentar solucións sóftware sobre a base dun coñecemento adecuado das teorías, modelos e técnicas actuais. |
B1 |
Capacidade de resolución de problemas |
B3 |
Capacidade de análise e síntese |
C2 |
Dominar a expresión e a comprensión de forma oral e escrita dun idioma estranxeiro. |
C3 |
Utilizar as ferramentas básicas das tecnoloxías da información e as comunicacións (TIC) necesarias para o exercicio da súa profesión e para a aprendizaxe ao longo da súa vida. |
C6 |
Valorar criticamente o coñecemento, a tecnoloxía e a información dispoñible para resolver os problemas cos que deben enfrontarse. |
C7 |
Asumir como profesional e cidadán a importancia da aprendizaxe ao longo da vida. |
C8 |
Valorar a importancia que ten a investigación, a innovación e o desenvolvemento tecnolóxico no avance socioeconómico e cultural da sociedade. |
Learning aims |
Learning outcomes |
Study programme competences / results |
Ability to identify and analyse problems, and design, develop, implement, validate and document software solutions on the basis of a deep and broad knowledge of modern theories, models, and techniques.
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A28
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B1 B3
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C2 C3 C6 C7 C8
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Contents |
Topic |
Sub-topic |
Part I: Software Testing
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I.1 Test specification, design, and execution
I1.1. Levels and types of tests
I1.2. Properties and traceability of requirements
I.2 Test management: planning, assessment, metrics and reviews |
Part II: Formal methods and automatic reasoning
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II.1 Introduction: natural deduction and calculus of sequences
II.2 Automatic proof using PVS
II.3 What is a theorem prover and what is it used for?
II.4 PVS specification language: types, expressions, theories, subtyping
II.5 PVS prover: tactics, recursion, ecuational reasoning |
Part III: Model checking |
III.1 Introduction to modal temporal logic
III.2 Properties specification: deadlocks, safety, liveness, fairness
III.3 How a model checker works
III.4 Introduction to the use of a model checking tool |
Planning |
Methodologies / tests |
Competencies / Results |
Teaching hours (in-person & virtual) |
Student’s personal work hours |
Total hours |
Guest lecture / keynote speech |
B3 C2 C7 C8 |
21 |
26.25 |
47.25 |
Laboratory practice |
A28 B1 B3 C2 C3 C6 |
14 |
35 |
49 |
Supervised projects |
A28 B1 B3 C2 C3 C6 |
7 |
7 |
14 |
Objective test |
B1 B3 C6 |
3 |
31.5 |
34.5 |
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Personalized attention |
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5.25 |
0 |
5.25 |
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(*)The information in the planning table is for guidance only and does not take into account the heterogeneity of the students. |
Methodologies |
Methodologies |
Description |
Guest lecture / keynote speech |
Master class where the theoretical aspects of the subject are presented. |
Laboratory practice |
Hands-on student assigment in the lab. |
Supervised projects |
Student assigments during reduced-group classes. |
Objective test |
Written test. |
Personalized attention |
Methodologies
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Guest lecture / keynote speech |
Laboratory practice |
Supervised projects |
Objective test |
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Description |
Questions/answers sessions about theoretical/practical aspects, student assigments, etc. during the office hours of each teacher. |
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Assessment |
Methodologies
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Competencies / Results |
Description
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Qualification
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Laboratory practice |
A28 B1 B3 C2 C3 C6 |
Hand in and presentation of student assigments, up to a maximum of 4 points in the final score. These are not compulsory to pass. |
40 |
Supervised projects |
A28 B1 B3 C2 C3 C6 |
Student assigments presented during reduced-group classes, up to a maximum of 2 points in the final score. These are not compulsory to pass. |
20 |
Objective test |
B1 B3 C6 |
Written test, up to a maximum of 4 points in the final score. A minimum of 2 points is required to pass. |
40 |
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Assessment comments |
Those students who do not reach the minimum in the objective test, will be qualified with the qualification they obtain in that objective test. In the second opportunity, the objective test may include a specific evaluation of the laboratory practice. In compliance with the academic rules at UDC that apply to part-time students, physical presence in the classroom/laboratory will not be regarded as qualification element. That is to say, students may officially apply to be dismissed from attending lectures and laboratory practices. All in all, part-time students will still need to comply with deadlines established for supervised projects and laboratory projects.
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Sources of information |
Basic
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Peter Farrell-Vinay (2008). Manage software testing. Auerbach
Mordechai Ben-Ari (2012). Mathematical Logic for Computer Science. Springer
Mordechai Ben-Ari (2001). Mathematical Logic for Computer Science. Springer
Ron Patton (2001). Software testing. Sams
Kent Beck (2002). Test Driven Development (By Example). Addison-Wesley
Gerard J. Holzmann (2003). The SPIN model checker: primer and reference manual. Addison-Wesley
Zohar Manna and Amir Pnueli (1995). The Temporal Logic of Reactive and Concurrent Systems. Safety. Springer
Zohar Manna and Amir Pnueli (1991). The Temporal Logic of Reactive and Concurrent Systems. Specification. Springer |
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Complementary
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Recommendations |
Subjects that it is recommended to have taken before |
Software Design/614G01015 | Concurrency and Parallelism/614G01018 | Software Process/614G01019 | Software Architecture/614G01221 | Requirements Engineering/614G01222 | Quality Assurance/614G01223 |
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Subjects that are recommended to be taken simultaneously |
Knowledge Representation and Automatic Reasoning/614G01036 | Theoretical Computer Science/614G01039 | Development Methodologies/614G01051 |
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Subjects that continue the syllabus |
Software Development Projects/614G01226 |
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