Studying at the University of Verona
Here you can find information on the organisational aspects of the Programme, lecture timetables, learning activities and useful contact details for your time at the University, from enrolment to graduation.
Study Plan
This information is intended exclusively for students already enrolled in this course.If you are a new student interested in enrolling, you can find information about the course of study on the course page:
Laurea magistrale in Ingegneria e scienze informatiche - Enrollment from 2025/2026The Study Plan includes all modules, teaching and learning activities that each student will need to undertake during their time at the University.
Please select your Study Plan based on your enrollment year.
1° Year
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2° Year activated in the A.Y. 2016/2017
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Due insegnamenti a scelta
Legend | Type of training activity (TTA)
TAF (Type of Educational Activity) All courses and activities are classified into different types of educational activities, indicated by a letter.
Automated reasoning (2016/2017)
Teaching code
4S02796
Teacher
Coordinator
Credits
6
Language
Italian
Scientific Disciplinary Sector (SSD)
INF/01 - INFORMATICS
Period
I sem. dal Oct 3, 2016 al Jan 31, 2017.
Learning outcomes
The class presents problems, methods and systems in automated reasoning. The treatment combines theoretical foundations with algorithmic and practical issues, emphasizing mechanization throughout. The student learns how to design, apply, and evaluate methods and systems for automated reasoning, with attention to applications in fields
such as analysis, verification, synthesis of systems, artificial intelligence, mathematics, robotics
Program
Foundations of automated reasoning: theorem proving and model building. Inference systems. Instance-based inference systems (e.g., hyper-linking). Ordering-based inference systems (e.g., resolution and paramodulation/superposition). Subgoal-reduction based inference systems (e.g., model elimination). Search plans. Algorithmic reasoning in specific fields, such as: decision procedures for satisfiability (SAT) and satisfiability modulo theories (SMT); reasoning about constraints. Design and use of general-purpose or special-purpose reasoners.
Author | Title | Publishing house | Year | ISBN | Notes |
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Ricardo Caferra, Alexander Leitsch, Nicolas Peltier | Automated Model Building (Edizione 1) | Kluwer Academic Publishers | 2004 | 1-4020-265 | |
Rolf Socher-Ambrosius, Patricia Johann | Deduction Systems (Edizione 1) | Springer Verlag | 1997 | 0387948473 | |
Raymond M. Smullyan | First-order logic | Dover Publications | 1995 | 0486683702 | |
Allan Ramsay | Formal Methods in Artificial Intelligence (Edizione 1) | Cambridge University Press | 1989 | 0521424216 | |
John Harrison | Handbook of Practical Logic and Automated Reasoning (Edizione 1) | Cambridge University Press | 2009 | 9780521899574 | |
Chin-Liang Chang, Richard Char-Tung Lee | Symbolic Logic and Mechanical Theorem Proving (Edizione 1) | Academic Press | 1973 | 0121703509 | |
Aaron R. Bradley, Zohar Manna | The Calculus of Computation - Decision Procedures with Applications to Verification (Edizione 1) | Springer | 2007 | 9783540741 | |
Alexander Leitsch | The Resolution Calculus (Edizione 1) | Springer | 1997 | 3540618821 | |
Martin Davis | The Universal Computer. The Road from Leibniz to Turing. Turing Centenary Edition. | Taylor and Francis Group | 2012 | 978-1-4665-0519-3 |
Examination Methods
Exams (First take): The grade is given by 30% C1 + 30% C2 + 40% P, where C1 is the midterm exam, C2 is the final exam, and P is a project.
Exams (Later takes): The grade is given by 100% E, where E is a written exam, as hard as midterm, final, and project combined.
There is no difference between students who attend and students who do not attend.