Department of Mathematics and Computer Science

Department of Physics, Informatics and Mathematics

Department of Mathematical, Physical and Computer Sciences

The PhD program in Mathematics is organized within a close collaboration between the three universities of Ferrara, Modena-Reggio Emilia and Parma, and represents a consolidated reality at regional and national level since 2013. The students of PhD programs benefit both from the educational offers of the three campuses in the various fields of Mathematics, and from the plurality of skills in the teaching staff. Through a capillary network of national and international contacts and the high level qualification of its teaching staff, the program offers an educational path of the highest level in each specific sector of mathematical sciences.

The main objective of this program is to train highly qualified professionals in the field of Mathematics, with advanced skills on mathematical models and methodologies, which can also be used in application contexts of interdisciplinary type is achieved through series of lectures, seminars, participation in workshops and research periods in third-party institutions which, on the one hand, introduce PhD students into the academic and non-academic research mode and, on the other hand, allow them to establish business contacts that will accompany them in the years following graduation. Alongside the periods of study, presentations at conferences and workshops of international importance are organized to help the doctoral student in subsequent insertion into the working way. The training is therefore specifically aimed at the ability to recognize significant research problems in the field mathematician, to formulate solutions to such problems and to pass on the results to others through oral presentations or written work.

PhD candidates, at the end of the program, must be able to: carry out a research activity independently, produce original and relevant results and enter the international scientific community. Graduates will be in possession the skills necessary not only to work in universities and research institutes, but also in industry, in administration public and private commercial enterprises.

News

On September 27- 30 and October 2-4-7-9-11 2024, Prof. Valentina Mini and Prof. Patrizio Bianchi will hold the course Transdisciplinary for a global vision (4 CFU). All the information are in this poster.

On September  11-12-17-19, 2024  from 16:00 to 18:00,  Prof. Prof. Daniel Bulacu from the University of Bucarest will hold the  course: The quasi-Hopf analogue of the Drinfeld-Jimbo quantum groups (2 CFU) (onsite and online). For information  contact Prof. Claudia Menini. (Description of the course)

On Novembre 7-9-14-16-21-23-28-30,  2023: from 14:30 to 16:30;  Prof. Franz Chouly  from the Université de Bourgogne will hold the " Numerical approximation of contact and friction problems" course ((both in presence at the University of Parma and remote). The Prof. Chouly is an INdAM visiting. For information and enrolment please refer to the page describing the couses held at the University of Parma  and/or contact Prof. Alessandra Aimi (alessandra.aimi@unipr.it)..

On July 4-13, 2023, Prof. Daniel Bulacu from the University of Bucarest will hold the "Galois Theory: from groups and forms to descent theory and extensions" course (both in presence at the University of Ferrara and remote). For information and enrolment please refer to the page describing the couses held at the University of Ferrara and/or contact Prof. Claudia Menini.

On December 2-3, 2022, Prof. Sebastien Motsch from University of Arizona will hold the "Around neural Network and tumor growth: modeling, analysis and numerics" course (both in presence at the University of Ferrara and remote). For information and enrolment please refer to the course description document.

From November 15 to December 13, 2022, Prof. Paolo Boero from University of Genova, Ferdinando Arzarello from University of Turin, Federica Ferretti from University of Ferrara, Andrea Maffia from University of Bologna, Francesca Martignone from University of Western Piedmont, and Eugenia Taranto from University of Catania will hold the "Primi approcci alla ricerca in didattica della matematica" course (in Italian; both in presence at the University of Ferrara and remote). For information and enrolment please refer to the course description document.

Further Information

For further information, please contact the Ph.D. program coordinator: Prof. Valeria Ruggiero of the University of Ferrara.

Teacher: Alberto Calabri

Syllabus: Rational and birational maps of the complex projective plane. Fundamental points and exceptional curves of a plane Cremona transformation. Quadratic transformations and De Jonquières maps. Properties like equations of conditions and Noether's inequality. Factorization of transformations and proofs of Noether-Castelnuovo theorem, Cremona equivalence of plane curves. Properties of the varieties parametrizing plane Cremona maps of fixed degree. Lengths in the plane Cremona group.

Dates 2023/2024: 24h lectures +  home assignments, February-March 2024.

Title and Credits: Geometry of principal frequencies (4 CFU)

Teacher: Lorenzo Brasco

Syllabus: The first eigenvalue of the Laplacian on an open set, and more generally of a second order elliptic operator, is an important object both from an applied and theoretical point of view. In Mathematical Physics, it usually plays the role of the ground state energy of a physical system. Despite its importance, for general sets it is not easy to explicitly compute it: thus, we aim at finding estimates in terms of simple geometric quantities of the sets, which are the sharpest possible. The most celebrated instance of this kind of problems is the so-called Faber-Krahn inequality.
This course offers an overview of the methods and results on sharp geometric estimates for the first eigenvalue of the Laplacian and more generally of sharp Poincaré-Sobolev embedding constants (sometimes called "generalized principal frequencies"). In particular, we will present: supersolutions methods, symmetrization techniques, convex duality methods, the method of interior parallels, conformal transplantation techniques.

Dates 2023/24: the precise dates will be decided together with the interested PhD students, who are encouraged to contact the teacher in advance.

Title and Credits: Introduction to mathematical fuzzy logic (2 CFU)

Teacher: Carles Noguera

Syllabus: Originating as an attempt to provide solid logical foundations for fuzzy set theory,and motivated also by philosophical and computational problems of vagueness and imprecision, mathematical fuzzy logic (MFL) has become a significant subfield of mathematical logic. Research in this area focuses on many-valued logics with linearly ordered truth theories and challenging problems, thus continuing to attract an ever increasing number of researchers. The goal of this course is to provide an up-to-date introduction to MFL. Starting with the motivations and historical origins of the area, we present MFL, its main methods, and its core agenda. In particular, we focus on some of its better known logic systems ( Lukasiewicz and Godel–Dummett logics, BL, MTL) and present a general theory of fuzzy logics. Finally, we give an overview of several currently active lines of research in the development and application of fuzzy logics.

Dates : 1-5 July 2024, lectures of 2 hours from Monday to Friday .

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Title and Credits: An introduction to uncertainty quantification for PDEs (4 CFU)

Teacher:  Giulia Bertaglia, Elisa Iacomini

Dates: 18-19-20 April, 2024 :

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Title: internet Seminar on Harmonic Analysis (ISEM27), edition 27

Dates: october 2023- february 2024, local coordinator Prof. Michele Miranda

At the end of the course  (project phase (3CFU)), in-depth topics are proposed. Small groups of students from different universities are formed with the aim to study these topics and prepare a communication for the Final Workshop to be held in Luminy (Marseille, France).

https://moodle-guest.hrz.tu-darmstadt.de/login/index.php

PhD students cycle XXXIX:

1. AWAIS Muhammad , muhammad02.awais@edu.unife.it, wsammm@unife.it- tutor prof. Giacomo Dimarco - sede Ferrara
2. CIBIEN Maria Chiara, mariachiara.cibien@edu.unife.it, cbnmch@unife.it - tutor prof.ssa Federica Ferretti, sede Ferrara
3. GALIMBERTI Pietro, pietro.galimberti@edu.unife.it, glmptr@unife.it- tutor prof.ssa Stefania Gatti, sede Modena e Reggio Emilia
4. GILIBERTI Giovanni, giovanni.giliberti@edu.unife.it,  glbgnn@unife.it - tutor  prof.ssa Luisa Malaguti, cotutor prof. Duccio Papini,  sede Modena e  Reggio Emilia
5. GRASSI Gianluca, gianluca01.grassi@edu.unife.it, grsglc@unife.it, tutor prof. Alex Massarenti, cotutor prof. Alberto Calabri, sede Ferrara
6. LO GIUDICE Ettore, ettore.logiudice@edu.unife.it, lgdttr@unife.it- tutor prof.ssa Paola Cristofori, cotutor prof.ssa Michela Zedda, sedi Modena e Reggio Emilia, Parma
7. MACALUSO Anna, anna.macaluso@edu.unife.it, mclnna@unife.it - tutor prof.ssa Maria Groppi, cotutor prof.ssa Marzia Bisi, sede Parma
8. MAY CUSTODIO Victor Gustavo, victorgu.maycustodio@edu.unife.it, glmptr@unife.it- tutor prof. Leonardo Biliotti, sede Parma
9. MEHRAB Aneeqa, aneeqa.mehrab@edu.unife.it, mhrnqa@unife.it- tutor prof.ssa Cinzia Bisi, cotutor prof.ssa Rita Fioresi, sede Ferrara
10. MIGLIACCIO Alessandra, alessand.migliaccio@edu.unife.it, mgllsn@unife.it - tutor prof. Sergio Polidoro, cotutor prof. Paolo Baroni. sede Modena e Reggio Emilia, Parma
11. PAPARELLA Alberto, alberto.paparella@edu.unife.it, pprlrt@unife.it- tutor prof. Guido Sciavicco, sede Ferrara
12. SOPIO Cristian, cristian.sopio@edu.unife.it, spocst@unife.it - tutor Alberto Saracco, sede Parma
13. KOFLER Theresa, theresa.kofler@edu.unife.it, theresakofler@unife.it - tutor Lorenzo Pareschi, sede Ferrara (DATAHYKING project)
14. BLONDEEL Frédéric, frederic.blondeel@unife.it, frederic.blondeel@edu.unife.it, - tutor Lorenzo Pareschi, sede Ferrara (DATAHYKING project)
15. VENERUSO Sara, sara.veneruso@unife.it, tutor Lorenzo Pareschi, sede Ferrara (DATAHYKING project)
16. CAPARELLO Domenico, domenico.caparello@unife.it, tutor Lorenzo Pareschi, sede Ferrara (DATAHYKING project)

PhD students cycle XXXVIII:

1. ALESSI Chiara, chiara.alessi@edu.unife.it - tutor prof. Michele Miranda – sede: Ferrara
2. ALI Abu Safan, abusafyan.ali@unife.it - tutor prof. Giacomo Dimarco - sede: Ferrara
3. BERTAZZONI Giacomo, giacomo.bertazzoni@unife.it - tutor prof.ssa Michela Eleuteri – sede: Modena-Reggio
4. CAMELLINI Filippo, filippo.camellini@unife.it - tutor prof. Marco Prato – sede: Modena-Reggio
5. LUCCHIN Enrico, enrico01.lucchin@edu.unife.it – tutor prof.ssa Maria Groppi – sede: Parma
6. MARAMOTTI Riccardo,  riccardo.maramotti@unife.it - tutor prof.ssa Silvia Bonettini – sede: Modena-Reggio
7. MINUZZO Alessandro, alessandro.minuzzo@unife.it – tutor prof. Leonardo Biliotti – sede: Parma
8. MISURATI Matteo, matteo.misurati@unife.it – tutor prof.ssa Claudia Menini – sede: Ferrara
9. PECORELLA Giulio, giulio.pecorella@unife.it – tutor prof. Sergio Polidoro – sede: Modena-Reggio
10. PISATI Arrigo, arrigo.pisati@unife.it – tutor prof.ssa Alessandra Fiocca, cotutor prof.ssa M. Giulia Lugaresi – sede: Ferrara
11. SOLIANI Eridano, eridano.soliani@unife.it– tutor prof. Federico Bergenti – sede: Parma
12. VIOLA Giada, giada.viola@unife.it– tutor prof.ssa Federica Ferretti – sede: Ferrara

PhD students cycles XXXV-XXXVII (Università di Parma)

PhD students cycle XXXIV (Università di Modena e Reggio Emilia)

PhD students cycle XXXIII (Università di Modena e Reggio Emilia)

PhD students cycle XXXII (Università di Modena e Reggio Emilia)

PhD students cycle XXIX-XXXI (Università di Ferrara)

Title and Credits: Numerical approximation of contact and friction problems, 6 CFU

Teacher: Franz Chouly (Université de Bourgogne, INdAM visiting)

Syllabus:

1-Introduction

2-Fractional Sobolev spaces

3-Signorini problem and a naïve finite element approximation

4-New approximation techniques and optimal error bounds

5-Extension to friction (Tresca, Coulomb)

6-Extension to elastodynamics and impact of elastic bodies

Bibliography

Chouly, P. Hild, and Y. Renard, Finite element approximation of contact and friction in elasticity, no. 48 inAdvances in Continuum Mechanics, Birkhäuser, Springer, 2023. ISBN 978-3-031-31422-3

Dates 7-9-14-16-21-23-28-30 november 2023: 14:30-16:30;  16h lectures +  home assignment; the students who are interested to follow lectures online, are asked to contact in advance alessandra.aimi@unipr.it

Title and Credits: Morse Theory 4 CFU

Teacher: Leonardo Biliotti

Syllabus:non-degenerate smooth functions on manifold, homotopy thype  in terms of critical values, morse inequalies, the existence of non-degenerate functions, the Lefschets Theorem on Hyperplena sections, the calculus of variations applied to geodesic.

References: ''Morse Theory '', Milnor, ''An invitation to Morse Theory'', Nicolaescu

Dates 2023/2024:  reading course.

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Title and Credits: Complex surfaces and their automorphisms 5 CFU

Teacher: Andrea Cattaneo

Syllabus: the aim of the course is to introduce the main techniques used in complex and algebraic geometry to study the geometry of compact complex surfaces. We will review the main results of the theory: the Riemann—Roch theorem with its implications, the effects of a blow up on the topology and the cohomology of a surface and Castelnuovo’s contraction theorem, the concept of minimal surface and the problem of classification (Castelnuovo’s rationality criterion and Enriques—Kodaira classification). Finally, we will focus on automorphisms of surfaces, focussing on what is known about their automorphism groups in particular for surfaces of Kodaira dimension 0.

Dates: 8 weeks, starting mid January 2024

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Title and credits: Topics in Representation Theory 6 CFU

Teacher: Andrea Appel

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Title and Credits: Normal Families Format 6 CFU

Teacher: Anna Miriam Benini

Syllabus:  Consider a family of holomorphic maps from a complex manifold M to a compact complex manifold X. It is natural to ask oneself under which hypothesis such a family is precompact in Hol(M, X), i.e. every sequence has a converging subsequence. A precompact family is called normal. When M=C the complex plane, and X is the Riemann sphere, there is a famous criterion by Montel which claims that precompactness follows if the family omits 3 points in the Riemann sphere. The theory of normal families plays a crucial role in holomorphic iteration and more generally in functional analysis. We will study normal families of holomorphic/meromorhpic maps from C to the sphere and also give some information on normal families in higher dimensions.

Bibliography:

1)Schiff, Joel L. Normal families. Springer-Verlag, New York, 1993. xii+236 pp.ISBN: 0-387-97967-0

2)Lyubich, Mikhail, Conformal Geometry and Dynamics of Quadratic Polynomials, vol I-II

Dates will be decided with students; Individual Reading + Presentations + Exercises + 12 hours lectures.

Title and Credits: Numerical methods for Boundary Integral Equations, 6 CFU
Teacher: Alessandra Aimi

Syllabus: The course is principally focused on Boundary Element Methods (BEMs).
Lectures involve: Boundary integral formulation of elliptic, parabolic and hyperbolic problems - Integral operators with weakly singular, strongly singular and hyper-singular kernels - Approximation techniques: collocation and Galerkin BEMs - Quadrature formulas for weakly singular integrals, Cauchy principal value integrals and Hadamard finite part integrals -
Convergence results - Numerical schemes for the generation of the linear system coming from Galerkin BEM discretization.

Knowledge of basic notions in Numerical Analysis and in particular in numerical approximation of partial differential equations is required.

References will be provided directly during the course.

Dates Lectures will take place in II semester at the University of Parma for an amount of 24 hours. Precise dates will be decided together with the interested PhD students, who are encouraged to contact the teacher in advance

Title and Credits: Fourier and Laplace transforms and some applications, 4 CFU
Teacher: Marzia Bisi

Syllabus: Fourier transform: from Fourier series to Fourier transform, definition of inverse transform, transformation properties, convolution theorem, explicit computation of some transforms, applications to ODEs and PDEs of some physical problems. Laplace transform: definition, region of convergence, transformation properties, Laplace transform of Gaussian distribution, applications to some Cauchy problems. Definite integrals by means of residue theorem: integrals of real functions, and integrals of Fourier and Laplace useful to evaluate inverse transforms; theorems (with proofs) and examples.

Dates: February-March 2024 reading course; pdf slides and videos of all lectures are available on-line, number of expected hours: 24 + individual project.

Title and Credits: Extended kinetic theory and recent applications, 6 CFU
Teachers: Marzia Bisi, Maria Groppi

Syllabus: The course is intended to provide an introduction to classical kinetic Boltzmann approach to rarefied gas dynamics, and some recent advances including the generalization of kinetic models to reactive gas mixtures and to socio-economic problems.
Possible list of topics:

●        distribution function and Boltzmann equation for a single gas: collision operator, collision invariants, Maxwellian equilibrium distributions;

●        entropy functionals and second law of thermodynamics;

●        hydrodynamic limit, Euler and Navier-Stokes equations;

●        kinetic theory for gas mixtures: extended Boltzmann equations and BGK models;

●        kinetic models for reacting and/or polyatomic particles;

●        Boltzmann and Fokker-Planck equations for socio-economic phenomena, as wealth distribution or opinion formation.

Bibliography:

●        C. Cercignani, The Boltzmann Equation and its Applications, Springer, New York, 1988.

●        M. Bisi, M. Groppi, G. Spiga, Kinetic Modelling of Bimolecular Chemical Reactions, in “Kinetic Methods for Nonconservative and Reacting Systems” edited by G. Toscani, Quaderni di Matematica 16, Dip. di Matematica, Seconda Università di Napoli, Aracne Editrice, Roma, 2005.

●        L. Pareschi, G. Toscani, Interacting Multiagent Systems: Kinetic Equations and Monte Carlo Methods, Oxford University Press, Oxford, 2014.

Dates February 2024; the interested  students are asked to contact the teachers in advance to define the calendar.

Title and Credits: Numerical methods for option pricing, 2 CFU (50 ore)
Teacher: Chiara Guardasoni

Syllabus:

●        Introduction to differential model problems for option pricing in the Black-Scholes framework

●        Analysis of peculiar troubles and advantages in application of standard numerical methods for partial differential problems: Finite Difference Methods, Finite Element Methods, Boundary Element Method

Dates 2023/24: reading course always available.

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Title and Credits: Basic theory of the Riemann zeta-function, 3 CFU
Teacher: Alessandro Zaccagnini

Syllabus: Elementary results on prime numbers. The Riemann zeta-function and its basic properties: analytic continuation, functional equation, Euler product  and connection with prime numbers, the Riemann-von Mangoldt formula, the explicit formula, the Prime Number Theorem. Prime numbers in all and "almost all" short intetvals.

Dates 2023/2024;: the interested  students are asked to contact the teachers in advance to define the calendar.

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Title and Credits: Semigroups of bounded linear operators and applications to PDEs, 6 CFU.

Teacher: Luca Lorenzi

Syllabus: In this course we present the theory of semigroups of bounded operators in Banach spaces, paying particolar attention to analytic semigroups. Applications are given to the analysis of partial differential equations of parabolic type.

Dates: February-May 2024.

Title and Credits: Introduction to Geometric Measure Theory, 6 CFU
Teacher: Massimiliano Morini

Syllabus: The course covers the following topics: review and complements of Measure Theory; covering theorems and their application to the proof of the Lebesgue and Besicovitch Differentiation Theorems; rectifiable sets and rectifiability criteria; the theory of sets of finite perimeter;  applications to geometric variational problems; the isoperimetric problem; the partial  regularity theory for quasi-minimiser of the perimeter.

Hand-written notes of the whole course are available in Italian on the Elly platform.

Further references:

• L.C Evans and R.F. Gariepy: "Measure Theory and Fine Properties of Functions"
• F. Maggi: "Sets of Finite Perimeter and Geometric Variational Problems: An Introduction to Geometric Measure Theory"

Dates 2023/2024: reading course.

Title and Credits: Several complex variables, 6CFU
Teacher: Alberto Saracco

Syllabus: Theory of several complex variables. Hartogs theorem, Cartan-Thullen theorem, Kontinuitatsatz. Domains of holomorphy, Levi convexity and plurisubharmonic functions. Cauchy-Riemann equation. Sheaves and cohomology (Cech cohomology). The course will be mainly based on Chapters 1-6 of the book by Giuseppe Della Sala, Alberto Saracco, Alexandru Simioniuc and Giuseppe Tomassini: "Lectures on complex analysis and analytic geometry", Appunti. Scuola Normale Superiore di Pisa (Nuova Serie) [Lecture Notes. Scuola Normale Superiore di Pisa (New Series)] 3, Edizioni della Normale, Pisa (2006).

Dates 2023/2024:  reading course.

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Title and Credits: Introduction to Elliptic partial differential equations 6 CFU

Teacher: Paolo Baroni

Syllabus: the course aims at introducing basic problems and classic existence and regularity techniques for uniformly elliptic PDEs with linear growth. In particular, the following topics will be analyzed, more or less in detail according to the students’ interest:
- Harmonic functions, weak formulation and Weyl's Lemma.
- Second order regularity for the Poisson equation via Calderon-Zygmund decomposition and singular integrals.
- Second order Sobolev regularity for equations with constant coefficients.
- Linear equations with variable coefficients: W^{1,q} estimates for continuous coefficients.
- Campanato spaces and Schauder theory for linear equations with Holder coefficients and data.
- De Giorgi theory (Holder regularity of solutions for measurable coefficients).
- Harnack inequalities, expansion of positivity for equations with measurable coefficients.
- Gehring theory (higher integrability of the gradient).

Dates: The course is intended to span approximatively two consecutive months (to be decided) between October 2023 and February 2024. Students are encouraged to contact the lecturer as soon as possible in order to fix a timetable.

The main objective of the PhD program in Mathematics is to provide training in the development of skills research in mathematics and its possible applications. This main objective is accompanied by improvement teaching of mathematics in upper secondary school and universities. The program includes the training of mathematicians able to fully exploit the potential of mathematical and statistical tools and methods to address the intrinsic complexity of the problems posed by applied sciences and industry. The first year program includes lectures
advanced theoretical and workshops held by international scholars chosen by the teaching staff to offer students the opportunity to establish direct contacts with the international scientific community. These courses can be chosen from a wide range educational offer in both pure and applied mathematics. In addition, they will be accompanied by courses related to transversal skills such as computer science and programming, and the drafting of research projects within the community.

Doctoral students will also follow personalized courses under the guidance of a tutor in order to introduce them to the topics specifics of their research. Once the required courses and exams are completed, students will predominantly focus on the chosen research project. Students are evaluated annually based on their research progress leads to the drafting of the PhD thesis, to which the PhD program in Mathematics dedicates a great deal of attention.

Employment Opportunities

The high qualification in pure and applied research that will be provided will allow work placement in research centers and sectors technologically advanced services and production. In addition to the founding core of solid mathematical foundations aimed at giving tools to produce innovation, computational-computer-statistical skills must be emphasized immediately expendable from a professional point of view and highly demanded by the labor market.

Specifically, the expected employment opportunities are:

• Researchers to be included in the university career (Italy or abroad) or in public / private research institutions;
• Experts in the areas of development of EU research programs also for public / private study centers;
• People with advanced skills on mathematical models / methods (high-level analysis in industries, financial institutions, companies insurance companies, biomedical and pharmacological centers, managers in public and private entities, public administration managers,service company, professional consultancy);
• Qualified upper secondary school teachers / managers.

In addition to the classic fields of scientific research, also in other fields (industry, public administration, service companies and consultancy), there is a need for highly qualified professionals in the mathematical sector, able to carry out activities of specific and qualified research and / or able to conceive and implement applied research and innovation projects.

Program XXXIX cycle

Program XXXVIII cicle

Syllabus:  The course will present the duality approach to the study of Markov processes. This will combine, in a joint effort, probabilistic and algebraic tools. In particular we will consider several interacting particle systems that are used in (non-equilibrium) statistical mechanics, we will discuss "integrable probability", we will show how (stochastic) PDE arise by taking scaling limits.

Dates: 2023/24 the interested. students are asked to contact the teachers in advance.

Title and credits: Topological and comparison-type methods for the study of boundary value problems in differential equations,  4CFU

Teacher: Luisa Malaguti

Syllabus: the course deals with some important methods for the study of boundary value problems to ordinary and partial differential equations. The Leray-Schauder topological degree will be briefly introduced, and its applications discussed in the study of periodic solutions and solutions satisfying Cauchy multi-point conditions in parabolic equations. The upper and lower solutions technique for ordinary differential equations will be then proposed and its application given to the study of traveling wave solutions of reaction-diffusion equations with degenerate diffusivities.

Dates February-March 2024 for an amount of 18 hours. Precise dates will be decided together with the interested PhD students, who are encouraged to contact the teacher in advance.

Title and credits: Selected topics on algebraic curves over finite fields (20 hours)
Teacher: Giovanni Zini

Syllabus:the course will consider some selected topics in the theory of algebraic curves over finite fields. Useful previous knowledge: elementary theory of algebraic curves. The topics will be selected among the following ones.

●        Maximal curves over finite fields: properties, classical examples (Hermitian, Suzuki and Ree curves), recent families (GK curve, GGS curve, BM curve, Skabelund curves).

●        Automorphism groups of curves, and quotient curves: bounds on the size, examples. Automorphism and quotients of the Hermitian curve: classification.

●        Rational points of curves over finite fields: criteria and methods for the analysis of absolutely irreducible rational components of curves, in particular for what concerns plane curves.

●        Applications of the study of rational points to some remarkable families of polynomials over finite fields which are of interest in cryptography.

Dates: Lectures will take place from  March 2024 to May 2024; the interested students, are encouraged to contact the teacher in advance.

Title and credits: Hodge Theory (20hours, 6CFU)
Teacher: Camilla Felisetti

Syllabus: Hodge theory is a powerful tool to understand the topology of Riemannian Manifolds. The aim of this course is to give an introduction to the theory together with applications to complex algebraic geometry. In particular we will treat the following topics:

●        Recap on differentiable manifolds, differential forms and vector bundles

●        Compact Kähler manifolds

●        Hodge theory for Kähler manifolds

●        Hodge theory for algebraic projective varieties

Dates: Lectures will take place from 15 November 2023 to 15 December 2023 at the University of Modena and Reggio Emilia for an amount of 20 hours. Precise dates will be decided together with the interested PhD students, who are encouraged to contact the teacher in advance.

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Syllabus: Design Theory is a rich branch of Combinatorics that deals with the existence and construction of discrete structures

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Title: Variational Methods and Data-Driven Approaches for Imaging (6 CFU 16h)

Teachers: Alessandro Benfenati, Simone Rebegoldi

Syllabus: In the first part of the course, we introduce first order iterative methods suited for the minimization of the sum of a differentiable (possibly non-convex) function plus a convex (possibly non-differentiable) term, with particular attention to forward-backward methods. Convergence of these methods will be analyzed, both in the convex and non-convex setting. Furthermore, we discuss some popular acceleration strategies, such as the introduction of variable metrics, or the use of inertial steps in the iterative procedure. Finally, we present numerical results obtained on some image restoration problems, assessing the impact of acceleration techniques and hinting at possible future developments in this field.

The second part of the course is devoted to presenting data-driven approaches for solving imaging problems; we work in the MatLab environment, using the Deep Learning Toolbox. We address classification problems using deep learning techniques under supervised frameworks, i.e. when large datasets containing the ground truths for neural network training are available. Under the Deep Image Prior (DIP) framework we employ neural network architectures for solving image restoration problems, where one has to recover images corrupted by linear operators (e.g. Gaussian or motion blur) and by the presence of noise (e.g. Poisson noise). We also address semantic segmentation tasks, both in a supervised and unsupervised fashion.

Course plan:

1. The image formation model: forward and inverse problems.
2. Statistical approach for Gaussian and Poisson noisy data.
3. Forward-backward methods in differentiable and non-differentiable optimization.
4. Applications in image restoration problems arising from astronomy and microscopy.
5. Task 1: classification problem of MNIST database.
6. Task 2: image restoration under Deep Image Prior framework for Poisson data. Creation of custom functions for the neural network training in the MatLab environment.
7. Task 3: supervised semantic segmentation of retina images.
8. Task 4: unsupervised semantic segmentation of natural images.

References:

1. M. Bertero, P. Boccacci, V. Ruggiero, Inverse Imaging with Poisson Data, IOP Publishing, 2053—2563, 2018.

1. S. Bonettini, F. Porta, M. Prato, S. Rebegoldi, V. Ruggiero, L. Zanni, Recent Advances in Variable Metric First-Order Methods, in Computational Methods for Inverse Problems in Imaging, Springer INdAM Series 36, 1—31, 2019.
2. A. Chambolle, T. Pock, An Introduction to Continuous Optimization for Imaging, Acta Numer. 25, 161—319, 2016.
3. P. Combettes, J.-C. Pesquet, Proximal Splitting Methods in Signal Processing, in Fixed-Point Algorithms for Inverse Problems in Science and Engineering, Springer Optim. Appl., 185—212, 2011.
4. Y. Nesterov, Introductory lectures on convex optimization: a basic course, Applied Optimization, Kluwer Academic Publ., Boston, Dordrecht, London, 2004.
5. Ulyanov, D., Vedaldi, A. & Lempitsky, V. Deep Image Prior. Int J Comput Vis 128, 1867–1888 (2020).
6. A. Benfenati, A. Catozzi, G. Franchini and F. Porta, Piece-wise Constant Image Segmentation with a Deep Image Prior Approach, Scale Space and Variational Methods in Computer Vision. SSVM 2023. Lecture Notes in Computer Science, vol 14009.
7. S. Minaee, Y. Boykov, F. Porikli, A. Plaza, N. Kehtarnavaz and D. Terzopoulos, "Image Segmentation Using Deep Learning: A Survey," in IEEE Transactions on Pattern Analysis and Machine Intelligence, vol. 44, no. 7, pp. 3523-3542, 1 July 2022

Dates: February 2024 ; 16 h lectures; the interested. students are asked to contact the teachers in advance.

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Title: Inexact and stochastic optimization methods for big data applications (6 CFU, 16h)

Teachers: Giorgia Franchini, Federica Porta

Syllabus: Over the past few years, machine learning and deep learning techniques have emerged as cutting-edge methodologies in several domains, representing promising alternatives to traditional approaches. Learning techniques usually require solving minimization problems which are characterized by both large scale datasets and many parameters to be optimized. Due to their very low cost per iteration, inexact and stochastic gradient-based methods represent effective tools to address these problems. The aim of this course is to introduce the optimization models which typically arise in machine learning and deep learning applications and several inexact and stochastic optimization methods suitable to deal with these models. Convergence results and practical implementation aspects of such algorithms will be provided.

Course plan:

1. Formal optimization problem statements in machine and deep learning applications
2. Stochastic gradient methods: standard and advanced approaches
3. Neural architecture search techniques
4. Algorithms unrolling
5. Inexact gradient methods in a data driven framework
6. Implementation issues of stochastic and inexact optimization methods for large-scale training

References:

1. L. Bottou, F. E. Curtis, and J. Nocedal. Optimization methods for large-scale machine learning. SIAM Review, 60(2):223–311, 2018
2. G. Franchini, F. Porta, V. Ruggiero, and I. Trombini. A line search based proximal stochastic gradient algorithm with dynamical variance reduction. Journal of Scientific Computing, 94:23, 2023
3. G. Garrigos, and R. M. Gower, Handbook of convergence theorems for (stochastic) gradient methods, arXiv:2301.11235, 2023
4. V. Monga, Y. Li, and Y. C. Eldar, Algorithm Unrolling: Interpretable, Efficient Deep Learning for Signal and Image Processing, IEEE Signal Processing Magazine, 38(2):18-44, 2021
5. S. J. Wright,  and B. Recht, Optimization for data analysis, Cambridge University Press, 2022

Dates: March 2024; 16 h lectures; the interested. students are asked to contact the teachers in advance

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Title: Hypoelliptic Partial Differential Equations (6 CFU)
Teachers: Sergio Polidoro, Maria Manfredini

Syllabus: The subject of the course is linear second order Partial Differential Equations with non-negative characteristic form satisfying the Hormander's hypoellipticity condition. Maximum principle, local regularity, boundary value problem will be discussed for several examples of equations. Some open research problems will be described. The course will focus on the following topics:
-Bony's maximum principle for degenerate second order PDEs, propagation set and Hormander's hypoellipticity condition.
-Perron method for the boundary value problem in a bounded open set of the Euclidean space.
-Boundary regularity, barrier functions. Boundary measure, Green function.
-Fundamental solution. Mean value formulas. Harnack inequalities.
-Degenerate Kolmogorov equations. Applications to some financial problems.
The program may be modified in accordance with the requirements of the students.

Reference text: A. Bonfiglioli, E. Lanconelli, F. Uguzzoni, Stratified Lie Groups and Potential Theory for Their Sub-Laplacians (Springer Monographs in Mathematics - 2007). Further references and lecture notes will be given during the course..

Dates: May-June 2024, 15h lectures + 3 h of  autonomous work;  the interested. students are asked to contact the teachers in advance

Lectures take place at “Edificio Matematica”, via Campi 213/c, 41125 Modena.

Title and Credits: Duality Theory of Markov Processes, 3 CFU
Teacher: Cristian Giardinà, Gioia Carinci

Syllabus:  The course will present the duality approach to the study of Markov processes. This will combine, in a joint effort, probabilistic and algebraic tools. In particular we will consider several interacting particle systems that are used in (non-equilibrium) statistical mechanics, we will discuss "integrable probability", we will show how (stochastic) PDE arise by taking scaling limits.

Dates 2022/2023: Reading course, beginning of 2023 (precise schedule will be decided together with the students).

Title and credits: Optimization methods for machine learning

Teachers: Federica Porta, Giorgia Franchini, Alessandro Benfenati

Syllabus: Introduction to machine learning. Supervised Learning: loss functions, empirical risk minimization, regularization approaches. Gradient descent approaches: deterministic and stochastic frameworks, also with reduced variance. Hyperparameters choice in the stochastic gradient method. Stochastic Optimization in learning methodologies: topics and perspectives in constrained and
unconstrained fields. Implementation issues for large-scale learning. Link between stochastic gradient and Deep learning. Neural architecture search techniques.

Dates: 13-14-15 February 2023, all day long (9:30-13:00 and 14:00-17:30).

Title and Credits: Geometry of Deep Learning, 4 CFU

Teacher: Rita Fioresi

Syllabus:

• Introduction to Deep Learning, basic steps of the algorithm analogies with the human visual systems and its mathematical models.
• The geometry of the space of data and the space of parameters; KL divergence and its information geometry interpretation.
• Geometric Deep Learning: the algorithm of Deep Learning on Graphs.
• Message passing and GATs: a geometrical modelling via heat equation and laplacian on graphs.

This course will be self-contained as much as possible. The necessary differential geometric concepts (manifolds, Frobenius theorem, Cartan formalism) will be introduced and explained. The necessary programming skills will NOT be assumed, but a part of the course will be "hands on" illustrating key examples on colab.
The exam will consist in a brief exposition of some concepts and the students can choose the part of the
program they like the most and present a focused exposition on one argument.

Six lectures of approximately 2.5 hours each.

Dates 2022/2023: 15h lectures + reading course + home assignments

Title and Credits: New Directions in Designs and Graphs, 6 CFU

Teachers: Simona Bonvicini, Giuseppe Mazzuoccolo, Anita Pasotti, Tommaso Traetta.

Syllabus: The course will present some advanced topics and recent results in Design Theory and in Graph Theory.They include (but are not limited to) decompositions and factorizations of graphs and their symmetries, and the study of several classes of arrays.Open problems and applications will be presented too. Interested students are requested to send an email to: anita.pasotti@unibs.it

Dates 2022/2023: Reading course, beginning of 2023 (the precise schedule will be decided together with the students).

Title and credits: Topological and comparison-type methods for the study of boundary value problems in differential equations,  4CFU

Teacher: Luisa Malaguti

Syllabus: The Course deals with some important methods for the study of boundary value problems to ordinary and partial differential equations. The Leray-Schauder topological degree will be briefly introduced, and its applications discussed in the study of periodic solutions and solutions satisfying Cauchy multi-point conditions in parabolic equations. The upper and lower solutions technique for ordinary differential equations will be then proposed and its application given to the study of traveling wave solutions of reaction-diffusion equations with degenerate diffusivities.

Dates 2022/2023: Lectures will take place from March to June 2023 at the University of Modena and Reggio Emilia for an amount of 18 hours. Precise dates will be decided together with the interested PhD students, who are encouraged to contact the teacher in advance.

Title and credits: Selected topics on algebraic curves over finite fields (20 hours)
Teacher: Giovanni Zini

The course will consider some selected topics in the theory of algebraic curves over finite fields. Useful previous knowledge: elementary theory of algebraic curves. The topics will be selected among the following ones.

• Maximal curves over finite fields: properties, classical examples (Hermitian, Suzuki and Ree curves), recent families (GK curve, GGS curve, BM curve, Skabelund curves).
• Automorphism groups of curves, and quotient curves: bounds on the size, examples. Automorphism and quotients of the Hermitian curve: classification.
• Rational points of curves over finite fields: criteria and methods for the analysis of absolutely irreducible rational components of curves, in particular for what concerns plane curves.
• Applications of the study of rational points to some remarkable families of polynomials over finite fields which are of interest in cryptography.

Title and credits: Hodge Theory (20hours, 6CFU)
Teacher: Camilla Felisetti

Hodge theory is a powerful tool to understand the topology of Riemannian Manifolds. The aim of this course is to give an introduction to the theory together with applications to complex algebraic geometry. In particular we will treat the following topics:

• Recap on differentiable manifolds, differential forms and vector bundles
• Compact Kähler manifolds
• Hodge theory for Kähler manifolds
• Hodge theory for algebraic projective varieties

Dates 2023: Lectures will take place from September to October 2023 at the University of Modena and Reggio Emilia for an amount of 20 hours. Precise dates will be decided together with the interested PhD students, who are encouraged to contact the teacher in advance.

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PhD Program Coordinator

Prof. Valeria Ruggiero, Università di Ferrara

Faculty Members

• Cristina Acciarri, Università di Modena e Reggio Emilia

• Alessandra Aimi, Università di Parma

• Alessia Ascanelli, Università di Ferrara

• Andrea Bandini, Università di Pisa

• Paolo Baroni, Università di Parma
• Anna Benini , Università di Parma
• Federico Bergenti, Università di Parma

• Leonardo Biliotti, Università di Parma

• Cinzia Bisi, Università di Ferrara

• Marzia Bisi, Università di Parma

• Chiara Boiti, Università di Ferrara
• Silvia Bonettini, Università di Modena e Reggio Emilia

• Simona Bonvicini, Università di Modena e Reggio Emilia

• Walter Boscheri, Università di Ferrara

• Lorenzo Brasco, Università di Ferrara
• Alberto Calabri, Università di Ferrara
• Gioia Carinci, Università di Modena e Reggio Emilia

• Maria Rita Casali, Università di Modena e Reggio Emilia

• Andrea Cattaneo, Università di Parma

• Andrea Corli, Università di Ferrara

• Vincenzo Coscia, Università di Ferrara

• Paola Cristofori, Università di Modena e Reggio Emilia

• Giacomo Dimarco, Università di Ferrara
• Michela Eleuteri, Università di Modena e Reggio Emilia
• Federica Ferretti, Università di Ferrara

• Alessandra Fiocca, Università di Ferrara

• Rita Fioresi, Università di Bologna
• Rouven Frassek, Università di Modena e Reggio Emilia

• Stefania Gatti, Università di Modena e Reggio Emilia

• Carlo Giannelli, Università di Ferrara
• Cristian Giardinà, Università di Modena e Reggio Emilia

• Claudio Giberti, Università di Modena e Reggio Emilia

• Maria Groppi, Università di Parma

• Chiara Guardasoni, Università di Parma

• Claudia Landi, Università di Modena e Reggio Emilia

• Lucaﾠ Francesco Giuseppe Lorenzi, Università di Parma

• Maria Giulia Lugaresi, Università di Ferrara

• Alessandra Lunardi, Università di Parma

• Luisa Malaguti, Università di Modena e Reggio Emilia
• Alex Massarenti, Università di Ferrara
• Giuseppe Mazzuoccolo, Università di Modena e Reggio Emilia
• Costantino Medori , Università di Parma

• Massimiliano Mella, Università di Ferrara

• Claudia Menini, Università di Ferrara

• Carlo Mercuri, Università di Modena e Reggio Emilia

• Michele Miranda, Università di Ferrara

• Massimiliano Morini, Università di Parma

• Lorenzo Nicolodi, Università di Parma

• Giampiero Palatucci, Università di Parma
• Lorenzo Pareschi, Università di Ferrara
• Anita Pasotti, Università di Brescia
• Arianna Passerini, Università di Ferrara

• Cristina Patria, Università di Ferrara

• Sergio Polidoro, Università di Modena e Reggio Emilia

• Federica Porta, Università di Modena e Reggio Emilia

• Marco Prato, Università di Modena e Reggio Emilia

• Gloria Rinaldi, Università di Modena e Reggio Emilia

• Massimiliano Rosini, Università di Chieti-Pescara
• Elena Rossi, Università di Modena e Reggio Emilia

• Valeria Ruggiero, Università di Ferrara

• Andrea Sacchetti, Università di Modena e Reggio Emilia

• Alberto Saracco, Università di Parma

• Guido Sciavicco, Università di Ferrara
• Elisa Sovrano, Università di Modena e Reggio Emilia

• Valentina Taddei, Università di Modena e Reggio Emilia

• Cecilia Vernia, Università di Modena e Reggio Emilia

• Alessandro Zaccagnini, Università di Parma

• Luca Zanni, Università di Modena e Reggio Emilia

• Michela Zedda, Università di Parma
• Giovanni Zini, Università di Modena e Reggio Emilia