PhD students have to attend at least 140 hours of courses overall in 3 years (the earlier the better).
Each PhD student is expected to:
Each PhD student is expected to:
- attend and take the exam of three or more courses involving at least 80 hours of lectures in total;
- attend at least additional 60 hours of training activities without exam;
- attend one PhD school organized by PhD-AI.it (the corresponding hours are included in the 60 hours above)
The additional 60 hours of training activities may include:
- cycles of seminars and doctoral schools with specific indication that they are aimed exclusively or mainly at doctoral students;
- (up to 20 hours) activities on soft skills, research management, European and international research systems, entrepreneurship, intellectual property, etc. See e.g., the PhD+ and CyB+ courses offered by the University of Pisa program Contamination Lab, and the cross-curricular educational activities (open science, soft skills, etc.) offered at the University of Pisa.
The courses with exams and training activities without exams should be selected among the ones made available by:
- our PhD program (see below) and by the other 4 PhD programs of PhD-AI.it (links to be added);
- by the PhD program in Computer Science at the University of Pisa or by PhD programs at the host University.
- by the Italian and International universities or research institutions (subject to approval by the PhD Board).
The list of curses of the previous Academic Years are available: 2023-2024, 2022-2023, 2021-2022.
Ph.D. Courses – Academic Year 2024-2025
The list below might be expanded soon with additional courses.
3D Geometry Representation and Processing for Deep Learning
Institution: Consiglio Nazionale delle Ricerche
Location: Pisa – Department of Computer Science
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Paolo Cignoni, Massimiliano Corsini, Daniela Giorgi, Luigi Malomo
Email: paolo.cignoni@isti.cnr.it
Academic Year: 2024/2025
Semester: 2
Hours: 32
Abstract: Computer Graphics and Geometry Processing are the main disciplines dealing with 3D data such as meshes and point clouds. In turn, Artificial Intelligence and Deep Learning are fundamental paradigms to manage visual data. Nevertheless, applying traditional learning paradigms on 3D data requires rethinking architectural building blocks designed for 2D images.
In this course, we will introduce different representations for 3D data, and basic geometry processing techniques that intervene in deep learning pipelines (discrete differential geometry, sampling, remeshing, conversion, …). Then, we will introduce methods able to learn tasks on 3D data. We will describe different architectures to process complex geometric domains, and the novel mechanisms introduced in the literature to preserve by design their intrinsic properties. Examples include graph learning techniques, augmented with geometric and topological information; attention modules to process unordered point sets and mesh data; transformer-like architectures for unstructured data.
Learning based, radiance oriented approaches for 3D objects representation and rendering, (like NERF, Gaussian Splatting and variants) will be also introduced and discussed.
In the final part of the course, we will present different applications where the interplay between Computer Graphics/Geometry Processing and Deep Learning is opening up to exciting results, including Computational Fabrication, Assisted Design, Architectural Geometry, and Environmental Monitoring.
In this course, we will introduce different representations for 3D data, and basic geometry processing techniques that intervene in deep learning pipelines (discrete differential geometry, sampling, remeshing, conversion, …). Then, we will introduce methods able to learn tasks on 3D data. We will describe different architectures to process complex geometric domains, and the novel mechanisms introduced in the literature to preserve by design their intrinsic properties. Examples include graph learning techniques, augmented with geometric and topological information; attention modules to process unordered point sets and mesh data; transformer-like architectures for unstructured data.
Learning based, radiance oriented approaches for 3D objects representation and rendering, (like NERF, Gaussian Splatting and variants) will be also introduced and discussed.
In the final part of the course, we will present different applications where the interplay between Computer Graphics/Geometry Processing and Deep Learning is opening up to exciting results, including Computational Fabrication, Assisted Design, Architectural Geometry, and Environmental Monitoring.
Syllabus: – 3D Data Representation
– Discrete Differential Geometry
– Differentiable Rendering
– Radiance based representations (NERF & Gaussian Splatting)
– ML for Geometric Representations
– Geometric Deep Learning
– Generative Models for 3D
– Discrete Differential Geometry
– Differentiable Rendering
– Radiance based representations (NERF & Gaussian Splatting)
– ML for Geometric Representations
– Geometric Deep Learning
– Generative Models for 3D
Available for CircleU students: Yes
Advanced Laboratory of Complex Network Analysis
Institution: Università di Pisa, Consiglio Nazionale delle Ricerche
Location: University of Pisa, Largo Bruno Pontecorvo
Level: Master level
Type: Advanced course
Attendance Mode: In person
Exam: Yes
Lecturers: Giulio Rossetti, Barbara Guidi
Email: giulio.rossetti@isti.cnr.it, barbara.guidi@unipi.it
Academic Year: 2024/2025
Semester: 2
Hours: 48
Abstract: Delving deep into the intricacies of complex systems—be they social, biological, or technological—is vital for accurately modeling and effectively tackling the pressing issues that define our world today. Take, for instance, the need to diminish polarization and radicalization in online discussions, predict high-frequency financial transactions or understand the dynamic interactions among proteins.
This laboratory course aims to equip students with the tools to construct robust pipelines for analyzing complex systems derived from real-world data and represented as graphs. It will introduce key methodologies for data collection and preprocessing for graph analysis, delve into models designed to enhance the graph’s descriptive capabilities and practical applications and explore techniques for evaluating experimental outcomes. The course emphasizes hands-on learning, empowering students to gain practical insights into these concepts through the utilization of dedicated Python libraries.
Syllabus: Where to start: Formulating Hypotheses
Modeling Choices: From simple graphs to advanced models
Network Sampling
Data Collection: API & Web Scraping
Graph Transformation
Feature-rich modeling
How to Validate: check the statistical significance of network-based studies
Experiment reproducibility & Open Science
Modeling Choices: From simple graphs to advanced models
Network Sampling
Data Collection: API & Web Scraping
Graph Transformation
Feature-rich modeling
How to Validate: check the statistical significance of network-based studies
Experiment reproducibility & Open Science
Available for CircleU students: No
AI Bearing with the AI Act, research exemptions and other traps: navigating legal and ethical dimensions
Institution: Scuola Superiore Sant’Anna
Location: Scuola Superiore Sant’Anna Piazza Martiri della libertà 33 Pisa
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Prof. Giovanni Comandè
Email: g.comande@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 15
Abstract: The course introduces the candidates to the key elements of the AI Act. It analyses the twists and thorns of the rules “in favor” of research and SME and casts regulation in the framework of compliance needs and ethical constraints.
Syllabus: Will be shared with students thaat enrol writing to the teacher
Link:
Available for CircleU students: Yes
An introduction to large language models
Institution: Università di Firenze
Location: School of Engineering, via di Santa Marta 3, Florence
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Marco Lippi
Email: marco.lippi@unifi.it
Academic Year: 2024/2025
Semester: 2
Hours: 12
Abstract: This course will provide a general introduction to large language models, starting from background concepts in the area of natural language processing and providing key insights to specific topics related to pre-training, fine-tuning, prompt engineering, safety and security issues.
Syllabus: Background and general concepts from NLP: language models, transformers, attention. Pre-training. Prompt engineering: zero-shot, few-shot, chain-of-thought, and the like. Fine-tuning. Retrieval augmented generation. Tasks and performance evaluation. Limitations, safety and security issues.
Available for CircleU students:
Applied Statistical Modelling 1
Institution: Scuola Superiore Sant’Anna
Location: Sant’Anna School
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: In person
Exam: Yes
Lecturers: Chiara Seghieri
Email: chiara.seghieri@santannapisa.it
Academic Year: 2024/2025
Semester: 1
Hours: 20
Abstract: The course aims at providing students with methodological and applied background on statistical models for analysing data with different types of response variables. The course provides a practice-oriented approach with applications in the context of social sciences and practical examples using R software. The course focuses on: linear regression, generalized linear models for binary, ordinal and count responses, multilevel models.
The course assumes prior knowledge of foundations of Probability and Inferential Statistics (point estimates, confidence intervals and hypothesis testing).
The course assumes prior knowledge of foundations of Probability and Inferential Statistics (point estimates, confidence intervals and hypothesis testing).
Syllabus: Introduction to the course and to linear regression
Linear regression:model diagnostics, multiple linear regression
GLM introduction, logit model
Probit model, ordinal logit and probit
Poisson regression and other GLMs
Random effect models
Recap and applications
Linear regression:model diagnostics, multiple linear regression
GLM introduction, logit model
Probit model, ordinal logit and probit
Poisson regression and other GLMs
Random effect models
Recap and applications
Available for CircleU students: No
Bioinformatics
Institution: Scuola Normale Superiore
Location: Scuola Normale Superiore, Piazza dei Cavalieri 7, Pisa
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Francesco Raimondi, post-docs of the Bioinformatics group
Email: francesco.raimondi@sns.it
Academic Year: 2024/2025
Semester: 2
Hours: 40
Abstract: Aim of the course is to provide students with the basic
knowledge of bioinformatics techniques as an easy and
friendly support for their study and research careers. This
will entail: 1) theory of the most common bioinformatics
algorithms and resources: who they are, what they do
and why they are so important and increasingly used in
modern biology research; 2) basic practical experience
through hands-on-sessions on typical problems that can
be answered by using popular online tools.
knowledge of bioinformatics techniques as an easy and
friendly support for their study and research careers. This
will entail: 1) theory of the most common bioinformatics
algorithms and resources: who they are, what they do
and why they are so important and increasingly used in
modern biology research; 2) basic practical experience
through hands-on-sessions on typical problems that can
be answered by using popular online tools.
Syllabus: 1) Introduction to bioinformatics
2) Biological databases
3) Pairwise sequence alignments
4) Basic Local Alignment Search Tool (BLAST)
5) Multiple sequence Alignment
6) Protein analysis and Proteomics
7) Introduction to Protein structure
8) Homology Modeling
9) Fold recognition
2) Biological databases
3) Pairwise sequence alignments
4) Basic Local Alignment Search Tool (BLAST)
5) Multiple sequence Alignment
6) Protein analysis and Proteomics
7) Introduction to Protein structure
8) Homology Modeling
9) Fold recognition
Available for CircleU students: Yes
Causal Inference in Macroeconometrics
Institution: Scuola Superiore Sant’Anna
Location: Sant’Anna School, Piazza Martiri della Libertà 33, Pisa.
Level: Ph.D. level
Type: Advanced course
Attendance Mode: In person
Exam: No
Lecturers: Alessio Moneta
Email: a.moneta@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 12
Abstract: The course aims at addressing the problem of identifying and quantifying causal relationships in macroeconomics. The course will deliver an overview of methods that allow researcher to estimate causal effects from time-series data in a non-experimental setting.
Syllabus:
– A Historical Perspective on Causal Inference in Macroeconometrics
– A Historical Perspective on Causal Inference in Macroeconometrics
– The Structural Vector Autoregressive Model: Identification Strategies
– Causal Inference by Graphical Causal Models (an Introduction)
– Causal Inference by Independent Component Analysis
Available for CircleU students:
Cloud Computing & Big-Data
Institution: Scuola Superiore Sant’Anna
Location: Students should contact the lecturer, and they will receive instructions to attend and/or connect via e-mail
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Prof. Tommaso Cucinotta, Scuola Superiore Sant’Anna
Email: tommaso.cucinotta@santannapisa.it
Academic Year: 2024/2025
Semester: 1
Hours: 30
Abstract: This course provides an overview of the challenges to face, and the technical solutions to embrace, when building large-scale, fault-tolerant, distributed and replicated real-time cloud services. These systems need to be capable of serving millions/billions of requests per second with industrial-grade reliability, availability and performance, and are composed of thousands of components spanning across millions of machines, worldwide. The course focuses on design, development and operations of scalable software systems, including big-data processing and analytics, as used increasingly often for nowadays intensive computations needed to train large machine-learning and artificial intelligence models, where the huge volumes of data to handle mandates the use of heavily distributed algorithms. The course covers also basic concepts on networking architectures for data-centre and cloud computing infrastructures.
Syllabus: -) Cloud Computing
* Basic concepts
* Scalability and elasticity in cloud systems
* Fault-tolerance and replication
* Real-time cloud services
* Operations and devops engineering
-) Big Data and Analytics
* Basic concepts
* Real-time data streaming and analytics
* Distributed file-system
* SQL vs NoSQL data-base systems
* Big-Data and the Internet of Things
-) Platforms
* Overview of public cloud services (AWS EC2, Google GCP, …)
* Apache Hadoop, Storm, Spark
* Map Reduce
* OpenStack
* Basic concepts
* Scalability and elasticity in cloud systems
* Fault-tolerance and replication
* Real-time cloud services
* Operations and devops engineering
-) Big Data and Analytics
* Basic concepts
* Real-time data streaming and analytics
* Distributed file-system
* SQL vs NoSQL data-base systems
* Big-Data and the Internet of Things
-) Platforms
* Overview of public cloud services (AWS EC2, Google GCP, …)
* Apache Hadoop, Storm, Spark
* Map Reduce
* OpenStack
Available for CircleU students: Yes
Cloud Computing & Big-Data Lab
Institution: Scuola Superiore Sant’Anna
Location: Students need to contact the lecturer, who will send them by e-mail attendence and/or connection instructions
Level: Ph.D. level
Type: Advanced course
Attendance Mode: Blended
Exam: Yes
Lecturers: Prof. Tommaso Cucinotta, Scuola Superiore Sant’Anna
Email: tommaso.cucinotta@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 30
Abstract: This is a hands-on and applied course following up on the Cloud Computing & Big-Data course. Here, students will put in practice the theoretical/abstract concepts acquired in the general course on Cloud Computing & Big-Data. During the practical sessions, we’ll have a deep dive on such concepts as: machine virtualization and OS-level virtualization on Linux; virtual networking on Linux; programming abstractions for cloud and distributed computing; elasticity in practice; big-data programming frameworks; command-line interface for major public cloud services; popular open-source cloud platforms.
Syllabus: -) Virtualization Fundamentals
* KVM Command-Line Interface
* libvirt and virtual-manager
-) Virtual Switching on Linux
* brctl and OpenVSwitch
-) Containers
* LXC and netns
-) Public Cloud Services
* AWS EC2, CloudWatch
* AWS S3, DynamoDB
-) Open-source cloud platforms
* OpenStack Nova, Glance, Neutron
* OpenStack Heat/Senlin, Ceilometer/Monasca
* Kubernetes
-) Platforms for Big Data and Analytics
* Map Reduce
* Apache Spark
* KVM Command-Line Interface
* libvirt and virtual-manager
-) Virtual Switching on Linux
* brctl and OpenVSwitch
-) Containers
* LXC and netns
-) Public Cloud Services
* AWS EC2, CloudWatch
* AWS S3, DynamoDB
-) Open-source cloud platforms
* OpenStack Nova, Glance, Neutron
* OpenStack Heat/Senlin, Ceilometer/Monasca
* Kubernetes
-) Platforms for Big Data and Analytics
* Map Reduce
* Apache Spark
Available for CircleU students: Yes
Complexity in ecology
Institution: Scuola IMT Lucca
Location: IMT School for Advanced Studies Lucca (classroom and online link to be confirmed)
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: No
Lecturers: Andrea Perna
Email: andrea.perna@imtlucca.it
Academic Year: 2024/2025
Semester: 2
Hours: 10
Abstract: This short module is designed to provide a basic understanding of the way how ecological systems self-assemble and function, and of the mathematical and computational tools that can be used to characterise these systems.
Syllabus: * Patterns at the individual level: scaling of ontogenetic growth, movement and metabolism.
* Patterns at the level of groups and populations: group-size distribution, collective behaviour.
* Patterns at the level of ecological communities and ecological interactions (size-abundance distribution, ecological networks).
* Ecosystem-level patterns: diversity and productivity, geographic variation.
* Ecosystems through change: multiple stable states and ecological transitions.
* Patterns at the level of groups and populations: group-size distribution, collective behaviour.
* Patterns at the level of ecological communities and ecological interactions (size-abundance distribution, ecological networks).
* Ecosystem-level patterns: diversity and productivity, geographic variation.
* Ecosystems through change: multiple stable states and ecological transitions.
Link:
Available for CircleU students: Yes
Computational Economics
Institution: Scuola Superiore Sant’Anna
Location: Scuola Superiore Sant’Anna
Level: Post graduate Master level
Type: Introductory course (no or few prerequisites)
Attendance Mode: In person
Exam: Yes
Lecturers: Giorgio Fagiolo, Andrea Roventini, Andrea Vandin
Email: giorgio.fagiolo@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 56
Abstract: This course is intended to serve as a broad introduction to the huge literature using agent-based computational approaches to the study of economic dynamics. It is organized in three parts. The first one (“Why?”) will discuss the roots of the critiques to the mainstream paradigm from a methodological, empirical and experimental perspective. We shall briefly review the building blocks of mainstream models (rationality, equilibrium, interactions, etc.) and shortly present some of the evidence coming from cognitive psychology and experimental economics, network theory and empirical studies, supporting the idea that bounded rationality, non-trivial interactions, non-equilibrium dynamics, heterogeneity, etc. are irreducible features of modern economies. In the second part (“What?”) we shall discuss what ACE is and what are its main tools of analysis. We will define an ABM and present many examples of classes of ABMS, from the simplest (cellular automata, evolutionary games) to the most complicated ones (micro-founded macro models).The third part (“How?”) aims at understanding how ABMs can be designed, implemented and statistically analyzed. The course also contains an introduction to programming in Python (Andrea Vandin) and applications of agent-based models to macroeconomics (Andrea Roventini).
Syllabus: Introduction to programming in Python; agent-based computational economics (why? what? how?); applications of agent-based models to macroeconomics.
Available for CircleU students:
Computational fluid dynamics
Institution: Scuola Superiore Sant’Anna
Location: Sant’Anna Pisa sede centrale
Level: Master level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Giovanni Stabile
Email: giovanni.stabile@santannapisa.it
Academic Year: 2024/2025
Semester: 1
Hours: 20
Abstract: The course deals with a list of advanced topics in computational fluid dynamics. In the first part, the governing equations governing fluid dynamics problems are reviewed and derived. Both compressible and incompressible flows are considered. The basics of the finite volume methods for the numerical discretization of fluid dynamics problems are reviewed and discussed starting from the basic example of an advection-diffusion equation. Particular emphasis is given to the treatment of non-orthogonality, convection-dominated flows, time discretization, and order of accuracy. Numerical schemes for the treatment of velocity pressure coupling for the incompressible Navier-Stokes equation such as the SIMPLE and the PISO algorithms are reviewed and a discussion on chequerboard effects on collocated grids is provided. The last part of the course focuses on advanced topics related to turbulent and compressible flows. The various alternatives (RANS, LES) for turbulence modeling are introduced and discussed in detail. Finally, an introduction to numerical methods for compressible flows is provided.
Syllabus: no syllabus
Link:
Available for CircleU students: Yes
Computing Methods for Experimental Physics and Data Analysis
Institution: Università di Pisa
Location: Polo Fibonacci, University of Pisa
Level: Master level
Type: Advanced course
Attendance Mode: In person
Exam: Yes
Lecturers: Andrea Rizzi, Alessandra Retico
Email: andrea.rizzi@unipi.it, alessandra.retico@pi.infn.it
Academic Year: 2024/2025
Semester: 1
Hours: 40
Abstract: The course for PhD students is part of a more extensive MSc course. The latter includes lectures dedicated to best practice in code development with a focus on scientific collaboration, python programming, principles of parallel computing. The lectures for PhD students are focused on: the design of neural networks for scientific data analysis; the development of analysis projects in the context of particle physics or medical physics.
Syllabus: By the end of the course the student will know the following tools for scientific computing and data analysis:
– tools for machine learning and artificial neural network development
– specific data analysis tools for particles physics or medical physics
– tools for machine learning and artificial neural network development
– specific data analysis tools for particles physics or medical physics
Available for CircleU students:
Cycle of Seminars for PhD students on Artificial Intelligence
Institution: Università di Pisa
Location: Dipartimento di Informatica, Università di Pisa, Largo B. Pontecorvo 3, 56125 Pisa, Italy
Level: Ph.D. level
Type: Cycle of seminars
Attendance Mode: Blended
Exam: No
Lecturers: Main contact: Salvatore Ruggieri
Email: salvatore.ruggieri@unipi.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: The aim is to introduce new PhD students to topics that arise in the life of a researcher in AI, including how to search for knowledge and state-of-the-art, how to access computational resources, how to write a scientific paper, how to make an effective presentation in public, how to measure the performance of scientific publications, how to disseminate research, how to collaborate in scientific projects, etc. The seminars will be given by speakers with a specific background on the topic of the seminar.
Syllabus: The list of seminars will be released in January 2025.
Available for CircleU students: Yes
Data Driven Engineering
Institution: Scuola Superiore Sant’Anna
Location: Scuola Superiore Sant’Anna Pisa
Level: Ph.D. level
Type: Advanced course
Attendance Mode: Blended
Exam: Yes
Lecturers: Giovanni Stabile
Email: giovanni.stabile@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: The course deals with the main tools to perform dimensionality reduction and data-driven approximation of engineering problems. Both linear (proper orthogonal decomposition) and nonlinear approaches (autoenconders) will be reviewed in relation to dimensionality reduction. The main aspects of defining and designing experiments to implement a data-driven surrogate model will be reviewed. The main techniques discussed are the dynamic mode decomposition, the proper orthogonal decomposition with interpolation, neural networks, and Gaussian progress regression. The methodology is demonstrated using Python examples in Colab.
Syllabus: no syllabus
Link:
Available for CircleU students: Yes
Dynamic Factor Models
Institution: Scuola Superiore Sant’Anna
Location: Piazza Martiri delle Libertà, 33 Pisa
Level: Ph.D. level
Type: Advanced course
Attendance Mode: In person
Exam: Yes
Lecturers: Matteo Barigozzi
Email: laura.magazzini@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 7
Abstract: The analysis of high-dimensional time series has become one of the most active subjects of modern statistical methodology. To achieve dimension reduction, several new analytical and computational techniques have been developed under the name of machine learning methods. Among these factor models not only are one of the pioneering methods in the field of unsupervised learning (dating back to Spearman, 1904), but up to these days have also been one of the most popular and most employed ones. The aim of this course is to provide an introduction to factor models in time series analysis by teaching students the basic theoretical foundations and by illustrating them some applications to econometric analysis (knownledge of time series analysis is required).
Syllabus: History and Taxonomy.
Representation and identification.
Principal component analysis.
Quasi maximum likelihood.
Expectation Maximization algorithm
Dynamic principal component analysis.
Determining the number of factors.
Impulse response analysis and counterfactuals.
Coincident indicators.
Nowcasting and forecasting.
The case of cointegrated factors.
Representation and identification.
Principal component analysis.
Quasi maximum likelihood.
Expectation Maximization algorithm
Dynamic principal component analysis.
Determining the number of factors.
Impulse response analysis and counterfactuals.
Coincident indicators.
Nowcasting and forecasting.
The case of cointegrated factors.
Available for CircleU students:
Elements of statistical inference and probabilistic models of cognition
Institution: Scuola IMT Lucca
Location: IMT School Lucca. Piazza San Francesco, 19. 55100 Lucca
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: In person
Exam: Yes
Lecturers: Miguel Ibanez
Email: miguel.ibanezberganza@imtlucca.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: A gentle, non-rigorous overview of some topics in statistical inference, often from the point of view of statistical physics, and with a background motivational interest in probabilistic approaches to cognitive science.
Syllabus: – Motivational, introductory notions of probabilistic approaches to cognition. Bayesian estimators. Notions on unsupervised neural network learning. Expectation-Maximisation learning. Elements of Bayesian model selection. The Bayesian Information Criterion. Worked examples of model selection. Dimensionality reduction in Principal Component Analysis. Model selection and clustering. Latent Dirichlet Allocation. Variational inference. The Evidence Lower BOund approximation in ANN learning. The Hierarchical Gaussian Filter. Notions of probabilistic models of cognition.
Link:
Available for CircleU students:
Elements of statistical physics and statistical inference
Institution: Scuola IMT Lucca
Location: IMT School Lucca. Piazza San Francesco, 19. 55100 Lucca
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: In person
Exam: Yes
Lecturers: Miguel Ibanez
Email: miguel.ibanezberganza@imtlucca.it
Academic Year: 2024/2025
Semester: 2
Hours: 15
Abstract:
A gentle, non-rigorous introduction to some notions of statistical inference and information theory, adopting the perspective of statistical physics.
A gentle, non-rigorous introduction to some notions of statistical inference and information theory, adopting the perspective of statistical physics.
Syllabus:
– Statistical ensembles and emergence. Elements of equilibrium and non-equilibrium statistical physics. Sampling and inferring. The Markov Chain Monte Carlo method. Correlations, cumulants, partial correlations, and interactions. The Gaussian and Ising models. [Elements of stochastic processes on graphs.] The inverse problem: Bayesian estimators. Maximum entropy. Examples of maximum likelihood inference (with applications to biology and neuroscience). [Elements of Bayesian model selection. Dimensionality reduction in PCA.] Elements of random matrix ensembles. Inferring correlation and precision matrices. Elements of information theory. Information, entropy, and relevance.
– Statistical ensembles and emergence. Elements of equilibrium and non-equilibrium statistical physics. Sampling and inferring. The Markov Chain Monte Carlo method. Correlations, cumulants, partial correlations, and interactions. The Gaussian and Ising models. [Elements of stochastic processes on graphs.] The inverse problem: Bayesian estimators. Maximum entropy. Examples of maximum likelihood inference (with applications to biology and neuroscience). [Elements of Bayesian model selection. Dimensionality reduction in PCA.] Elements of random matrix ensembles. Inferring correlation and precision matrices. Elements of information theory. Information, entropy, and relevance.
Link:
Available for CircleU students:
Explainable Artificial Intelligence
Institution: Scuola Normale Superiore
Location: Scuola Normale Superiore, Palazzo della Carovana
Level: Ph.D. level
Type: Advanced course
Attendance Mode: Blended
Exam: Yes
Lecturers: Prof. Fosca Giannotti (Instructor), Dr. Roberto Pellungrini, Dr. Gizem Gezici (Teaching Assistants)
Email: fosca.giannotti@sns.it, roberto.pellungrini@sns.it, gizem.gezici@sns.it
Academic Year: 2024/2025
Semester: 2
Hours: 30
Abstract: Black box AI systems for automated decision making, often based on machine learning over (big) data, map a user’s features into a class or a score without exposing the reasons why. This is problematic not only for the lack of transparency, but also for possible biases inherited by the algorithms from human prejudices and collection artifacts hidden in the training data, which may lead to unfair or wrong decisions. The future of AI lies in enabling people to collaborate with machines to solve complex problems. Like any efficient collaboration, this requires good communication, trust, clarity and understanding. Explainable AI addresses such challenges and for years different AI communities have studied such topic, leading to different definitions, evaluation protocols, motivations, and results.
This (30 hours) course provides a reasoned introduction to the work of Explainable AI (XAI) to date, and surveys the literature with a focus on post-hoc and by-design approaches. We motivate the needs of XAI in real-world and large-scale application, while presenting state-of-the-art techniques and best practices, as well as discussing the many open challenges. An XAI platform with collection of many of the recently proposed algorithms will be presented on specific use cases and it will be possible familiarize with some of the methods.
The course is organized as follows in three modules: i) an introductory one providing motivations, main concepts and main methods; ii) an advanced one where the students will actively participate to monographs topics with readings interleaved with interventions of international scholars working on the sector; iii) an hands-on module where the students will be introduced to the usage on XAI methods.
This (30 hours) course provides a reasoned introduction to the work of Explainable AI (XAI) to date, and surveys the literature with a focus on post-hoc and by-design approaches. We motivate the needs of XAI in real-world and large-scale application, while presenting state-of-the-art techniques and best practices, as well as discussing the many open challenges. An XAI platform with collection of many of the recently proposed algorithms will be presented on specific use cases and it will be possible familiarize with some of the methods.
The course is organized as follows in three modules: i) an introductory one providing motivations, main concepts and main methods; ii) an advanced one where the students will actively participate to monographs topics with readings interleaved with interventions of international scholars working on the sector; iii) an hands-on module where the students will be introduced to the usage on XAI methods.
Syllabus: https://docs.google.com/document/d/1JMqjewyvGmcfjZd9l0get0pXep6QSCzX/edit?usp=sharing&ouid=110852127181441456126&rtpof=true&sd=true
Link:
Available for CircleU students: No
Geospatial Analytics
Institution: Università di Pisa, Consiglio Nazionale delle Ricerche, Scuola Normale Superiore
Location: Largo Bruno Pontecorvo, 3, 56127 Pisa. Rooms L1 and C1
Level: Master level
Type: Introductory course (no or few prerequisites)
Attendance Mode: In person
Exam: Yes
Lecturers: Luca Pappalardo, Mirco Nanni
Email: mirco.nanni@isti.cnr.it
Academic Year: 2024/2025
Semester: 1
Hours: 40
Abstract: The analysis of geographic information, such as those describing human movements, is crucial due to its impact on several aspects of our society, such as disease spreading (e.g., the COVID-19 pandemic), urban planning, well-being, pollution, and more. This course will teach the fundamental concepts and techniques underlying the analysis of geographic and mobility data, presenting data sources (e.g., mobile phone records, GPS traces, geotagged social media posts), data preprocessing techniques, statistical patterns, predicting and generative algorithms, and real-world applications (e.g., diffusion of epidemics, socio-demographics, link prediction in social networks). The course will also provide a practical perspective through the use of advanced geoanalytics Python libraries.
Syllabus: Module 1: Spatial and Mobility Data Analysis
Fundamentals of Geographical Information Systems
Geographic coordinates systems
Vector data model
Trajectories
Spatial Tessellations
Flows
Practice: Python packages for geospatial analysis (Shapely, GeoPandas, folium, scikit-mobility)
Digital spatial and mobility data
Mobile Phone Data
GPS data
Social media data
Other data (POIs, Road Networks, etc.)
Practice: reading and exploring spatial and mobility datasets in Python
Preprocessing mobility data
filtering compression
stop detection
trajectory segmentation
trajectory similarity and clustering
Practice: data preprocessing with scikit-mobility
Module 2: Mobility Patterns and Laws
individual mobility laws/patterns
collective mobility laws/patterns
Practice: analyze mobility data with Python
Module 3: Predictive and Generative Models
Prediction
Next-location prediction
Crowd flow prediction
Spatial interpolation
Generation
Trajectory generation
Flow generation
Practice: mobility prediction and generation in Python
Module 4: Applications
Urban segregation models
Routing and navigation apps
Traffic simulation with SUMO
Available for CircleU students:
Intelligent Systems for Pattern Recognition
Institution: Università di Pisa
Location: Polo Fibonacci, L.go Bruno Pontecorvo 3, 56127 Pisa
Level: Master level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Davide Bacciu
Email: davide.bacciu@unipi.it
Academic Year: 2024/2025
Semester: 2
Hours: 72
Abstract: The course introduces students to the analysis and design of advanced machine learning models for modern pattern recognition problems and discusses how to realize advanced applications exploiting computational intelligence techniques.
The course is articulated in four parts. The first part introduces basic concepts and algorithms concerning pattern recognition, in particular as pertains sequence and image analysis. The next two parts introduce advanced models from two major learning paradigms, that are (deep) neural networks and generative models, and their use in pattern recognition applications. The last part will go into the details of the realization of selected recent applications of AI models. Presentation of the theoretical models and associated algorithms will be complemented by introductory classes on the most popular software libraries used to implement them.
The course hosts guest seminars by national and international researchers working on the field as well as by companies that are engaged in the development of advanced applications using machine learning models.
Topics covered – Bayesian learning, graphical models, deep learning models and paradigms, deep learning for machine vision and signal processing, advanced neural network models (recurrent, recursive, etc.), (deep) reinforcement learning, signal processing and time-series analysis, image processing, filters and visual feature detectors, pattern recognition applications (machine vision, bio-informatics, robotics, medical imaging, etc), introduction to machine learning and deep learning libraries.
The course is articulated in four parts. The first part introduces basic concepts and algorithms concerning pattern recognition, in particular as pertains sequence and image analysis. The next two parts introduce advanced models from two major learning paradigms, that are (deep) neural networks and generative models, and their use in pattern recognition applications. The last part will go into the details of the realization of selected recent applications of AI models. Presentation of the theoretical models and associated algorithms will be complemented by introductory classes on the most popular software libraries used to implement them.
The course hosts guest seminars by national and international researchers working on the field as well as by companies that are engaged in the development of advanced applications using machine learning models.
Topics covered – Bayesian learning, graphical models, deep learning models and paradigms, deep learning for machine vision and signal processing, advanced neural network models (recurrent, recursive, etc.), (deep) reinforcement learning, signal processing and time-series analysis, image processing, filters and visual feature detectors, pattern recognition applications (machine vision, bio-informatics, robotics, medical imaging, etc), introduction to machine learning and deep learning libraries.
Syllabus: https://elearning.di.unipi.it/course/view.php?id=278
Available for CircleU students: No
Introduction to Network Science
Institution: Scuola IMT Lucca
Location: IMT School for Advanced Studies Lucca, p.zza San Francesco 19, 55100 Lucca (Italy)
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Tiziano Squartini
Email: tiziano.squartini@imtlucca.it
Academic Year: 2024/2025
Semester: 1
Hours: 20
Abstract: The course offers a panoramic view of network science. Following its historical development, we will review the main concepts and methods of this discipline. Moving from the basic, stylized facts characterizing real-world networks, we will describe the most popular techniques to extract information from them.
Syllabus: Introduction to graph theory. Empirical properties of complex networks (scale invariance of the degree, small-world phenomenon, modularity). Network representations (monopartite, bipartite and multilayer; binary and weighted; undirected and directed networks; unsigned and signed networks; hypergraphs; simplicial complexes). Centrality. Ranking and reputation algorithms. Mesoscale structures (communities, core-periphery and bow-tie structures). A primer on dynamical models: Watts-Strogatz and Barabasi-Albert models. A primer on static models: Erdos-Renyi, Chung-Lu and fitness models.
Available for CircleU students: Yes
Legal issues on AI-Applications for vulnerable groups.
Institution: Scuola Superiore Sant’Anna
Location: Scuola Sant’Anna – Pisa Aula 5 – Sede Centrale 9-13; 14-17 & 10.1.2025 Scuola Sant’Anna Pisa Aula 5 – Sede Centrale 9-14.
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Denise Amram
Email: denise.amram@santannapisa.it
Academic Year: 2024/2025
Semester: 1
Hours: 12
Abstract: The Course focuses on the general legal framework and tailored safeguards applicable to data analysis related to vulnerable individuals/groups and their impact on policy and law-making.
Case studies will be presented in particular on children, patients, workers, consumers.
Case studies will be presented in particular on children, patients, workers, consumers.
Syllabus: 1. Overview on the regulatory framework (EU strategy on data, GDPR, AI-Act) impacting on data-driven and ai-based research life-cycles.
2. Protocols for developers, deployers, and providers of AI-based systems to process general and sensitive data.
3. Case-studies on vulnerable users: consumers, patients, children, workers.
2. Protocols for developers, deployers, and providers of AI-based systems to process general and sensitive data.
3. Case-studies on vulnerable users: consumers, patients, children, workers.
Available for CircleU students: Yes
Machine Learning
Institution: Università di Pisa
Location: Università di Pisa – Polo Fibonacci – Largo Bruno Pontecorvo 3, 56127 Pisa, ITALY
Level: Master level
Type: Introductory course (no or few prerequisites)
Attendance Mode: In person
Exam: Yes
Lecturers: Alessio Micheli
Email: alessio.micheli@unipi.it
Academic Year: 2024/2025
Semester: 1
Hours: 72
Abstract: The course introduces the machine learning principles and models, including basic theory of learning. The course provides the Machine Learning basis for both the aims of building new adaptive Intelligent Systems and powerful predictive models for Intelligent Data Analysis.
The focus is on the critical analysis of the characteristics for the design and use of the algorithms for learning functions from examples and for the rigorous experimental evaluation.
The focus is on the critical analysis of the characteristics for the design and use of the algorithms for learning functions from examples and for the rigorous experimental evaluation.
The student who successfully completes the course will be able to demonstrate a solid knowledge of the main models and algorithms for learning functions from data, with a focus on Neural Networks and related methods. The student will be aware of the general conceptual framework of modern machine learning; of the basic principles of computational learning processes; of rigorous validation techniques; of the critical characteristics for the use of the learning models to design intelligent/adaptive systems and predictive models for data analysis.
Syllabus: Computational learning tasks for predictions, learning as function approximation, generalization concept.
Basic concepts and models: Continuos and discrete hypothesis space, inductive bias, linear and nearest neighbor models (learning algorithms and properties), regularization.
Neural Networks (NN) architectures and learning algorithms: Perceptron. Multi-layers feedforward models. Deep models. Randomized NN. Recurrent NN. Regularization.
Validation: model selection and model assessment.
Principles of learning processes: Elements of Statistical Learning Theory. Bias/variance analysis.
Support Vector Machines and Kernels-based models.
Unsupervised learning: vector quantization, self-organizing map (SOM).
Introduction to benchmarks and applications.
Introduction to advanced approaches (structured domains, learning on graphs).
Available for CircleU students:
Machine Learning and Omics in Epidemiology
Institution: Università di Firenze
Location: Aule del Dipartimento di Statistica, Informatica, Applicazioni “Giuseppe Parenti”, viale Morgagni 59, 50134, Firenze
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Dr. Chiara Marzi and Prof. Gianluca Severi
Email: chiara.marzi@unifi.it
Academic Year: 2024/2025
Semester: 2
Hours: 24
Abstract: This course aims at introducing Ph.D. students to statistical and machine learning methods for the analysis of high-dimensional data in epidemiology – the so-called “omics”. Particular emphasis will be placed on the different types of omics data (e.g., molecular data, metabolomics, genomics, proteomics, radiomics, etc.), as well as on the fundamental steps performed within a Machine Learning analysis to extract useful insights from these data (e.g., data harmonisation, features selection, validation scheme, etc.).
Syllabus: This course aims at introducing Ph.D. students to statistical and machine learning methods for the analysis of high-dimensional data in epidemiology – the so-called “omics”. Particular emphasis will be placed on the different types of omics data (e.g., molecular data, metabolomics, genomics, proteomics, radiomics, etc.), as well as on the fundamental steps performed within a Machine Learning analysis to extract useful insights from these data (e.g., data harmonisation, features selection, validation scheme, etc.). Material will be provided by the teachers and the exam will be a presentation of a paper – interesting from the student’s point of view – including the elements learned during the course.
Link:
Available for CircleU students: Yes
Machine Learning Methods for Physics
Institution: Università degli Studi di Genova
Location: Dipartimento di Fisica – Università di Genova
Level: Post graduate Master level
Type: Introductory course (no or few prerequisites)
Attendance Mode: In person
Exam: Yes
Lecturers: Dr. Riccardo Torre, Dr. Andrea Coccaro, Dr. Francesco Di Bello
Email: riccardo.torre@ge.infn.it
Academic Year: 2024/2025
Semester: 2
Hours: 48
Abstract: What is a machine learning algorithm? Why is machine learning playing a primary role in physics? Which problems can be optimized using it? What is the most suitable algorithm to solve my physics problem?
These are some of the questions that this course aims to answer, providing students with the state-of-the-art knowledge regarding the usage and understanding of artificial intelligence algorithms applied to physics. The course also focuses on developing a critical comprehension of results, exploring the development of future algorithms, and the most promising technologies.
Syllabus: The course aims to:
– Introduce the concepts of minimization algorithms for a scalar functional (the loss function).
– Provide the necessary tools for practical course execution, such as Python, Tensorflow, and Pytorch.
– Cover dense neural networks and examples of their applications in physics.
– Explore convolutional neural networks and examples of their applications in physics.
– Discuss recurrent neural networks and examples of their applications in physics.
– Investigate graph neural networks: inductive bias and examples of their applications in physics.
– Examine attention mechanisms: transformers and examples of their applications in physics.
– Study generative neural networks and examples of their applications in physics.
– Provide an overview of differentiable programming.
The course encompasses these topics to provide students with a comprehensive understanding of machine learning algorithms in the context of physics applications.
Available for CircleU students: No
Maximum-Entropy Models of Complex Systems II
Institution: Scuola IMT Lucca
Location: IMT School for Advanced Studies Lucca, p.zza San Francesco 19, 55100 Lucca (Italy)
Level: Ph.D. level
Type: Advanced course
Attendance Mode: Blended
Exam: Yes
Lecturers: Tiziano Squartini
Email: tiziano.squartini@imtlucca.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: The course heavily focuses on deeper theoretical aspects of maximum-entropy models and their consequences. Particular emphasis will be put on maximum-entropy models to study weighted complex networks.
Syllabus: How to build statistical models in a principled way: a review of maximum-entropy models. From null models to true models: weighted reciprocal configuration models and block-structured models. Bipartite formalism for Exponential Random Graph models. Continuous formalism for Exponential Random Graph models. Conditional framework for discrete and continuous Exponential Random Graph models. Information criteria for model selection (Likelihood Ratio Test, Akaike Information Criterion, Bayesian Information Criterion, Minimum Description Length). Applications to economic and financial systems. The course will include an overview of ongoing research carried out by Networks@IMT, thereby offering directions for possible PhD projects in this area.
Available for CircleU students: Yes
Microeconometrics
Institution: Scuola Superiore Sant’Anna
Location: Piazza Martiri della Libertà 33, Pisa
Level: Ph.D. level
Type: Advanced course
Attendance Mode: In person
Exam: Yes
Lecturers: Laura Magazzini
Email: laura.magazzini@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 21
Abstract: The course aims at providing students the tools for dealing with microeconomic analysis of the behavior of individuals or firms. Regression methods for the study of static and dynamic panel data models and estimation of limited dependent variable models will be considered, including discrete choice models, count data models, censored and truncated data. Besides the theoretical background, students will be exposed to the discussion and the analysis of empirical applications. (the course requires basic knowledge of OLS and IV regression methods and maximum likelihood estimation).
Syllabus: Linear panel data models: static and dynamic framework; Non linear regression models (binary choice, count data, truncation and censoring).
Available for CircleU students:
Network Neuroscience and MEdicine
Institution: Scuola IMT Lucca
Location: Lucca, IMT, Piazza San Francesco 19
Level: Ph.D. level
Type: Advanced course
Attendance Mode: Blended
Exam: Yes
Lecturers: Tommaso Gili
Email: tommaso.gili@imtlucca.it
Academic Year: 2024/2025
Semester: 1
Hours: 20
Abstract: We will discuss modelling brain function and structure using complex networks. It will be shown how passing from neurovascular and electrophysiological measurements to graphs is possible and how a connectome can be obtained. We will present mesoscopic models of communication in the brain and the role of synchronisation. The tools used to study the brain will also be shown to be useful in medicine by discussing the interactome, the diseasome and the foodome.
Syllabus: What is a complex system, and why can the brain be considered complex?
Neurovascular coupling.
The BOLD signal.
From BOLD time-series to a graph.
Molecular diffusion of water in the brain and fiber-tracking,
The structural architecture of the brain.
Electrophysiological signals.
Origin of EEG signal.
Origin of MEG signal.
Definition of functional networks from M/EEG time series.
Topological measures used in neuroscience and their application.
Higher-order interactions in the brain.
Models of communication in the brain.
Communication through synchronisation.
Synchronisation and symmetry.
Coarse-graining network neuroscience.
Higher-order interactions.
Null-models for Network Neuroscience.
Protein-protein interaction networks (interactome).
Human disease networks (diseasome).
Networks in systems pharmacology.
Boolean networks for system biology.
Food-health interaction (foodome).
Neurovascular coupling.
The BOLD signal.
From BOLD time-series to a graph.
Molecular diffusion of water in the brain and fiber-tracking,
The structural architecture of the brain.
Electrophysiological signals.
Origin of EEG signal.
Origin of MEG signal.
Definition of functional networks from M/EEG time series.
Topological measures used in neuroscience and their application.
Higher-order interactions in the brain.
Models of communication in the brain.
Communication through synchronisation.
Synchronisation and symmetry.
Coarse-graining network neuroscience.
Higher-order interactions.
Null-models for Network Neuroscience.
Protein-protein interaction networks (interactome).
Human disease networks (diseasome).
Networks in systems pharmacology.
Boolean networks for system biology.
Food-health interaction (foodome).
Link:
Available for CircleU students: Yes
Network Reconstruction
Institution: Scuola IMT Lucca
Location: IMT School for Advanced Studies Lucca, p.zza San Francesco 19, 55100 Lucca (Italy)
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Tiziano Squartini
Email: tiziano.squartini@imtlucca.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: The course focuses on the topic of network reconstruction. Early attempts to infer missing information about networks will be reviewed, putting particular emphasis on the use of such techniques to reconstruct financial networks.
Syllabus: Literature review about network reconstruction. Early attempts to infer a network structure from partial information (MaxEnt approach; the copula approach; MECAPM; Iterative Proportional Fitting algorithm; Minimum Density algorithm). Monopartite and bipartite financial networks reconstruction via the fitness model. Systemic risk estimation. How to build statistical models in a principled way: maximum-entropy models. Econometric VS maximum-entropy models: a comparison.
Available for CircleU students: Yes
Neural Networks and Deep Learning: Advanced Topics
Institution: Scuola Superiore Sant’Anna
Location: See link at: https://retis.santannapisa.it/~giorgio/courses/neural/nn.html
Level: Ph.D. level
Type: Advanced course
Attendance Mode: Online
Exam: Yes
Lecturers: Giorgio Buttazzo
Email: giorgio.buttazzo@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: This caurse presents recent techniques proposed to improve classical neural netowork models and overcome their limitations. Topics include model compression, semi-supervised learning, contrastive learning, neural networks for object tracking, adversarial attacks and defense methods.
Syllabus: 1. Model compression. Weight quantization. Model pruning. Model distillation.
2. Semi-supervised learning. K-nearest neighbors. Self-training algorithms.
3. Contrastive learning and Supervised Contrastive Learning.
4. Neural networks for object tracking.
5. Trustworthy AI. Safety, security, and predictability issues in deep neural networks.
6. Adversarial attacks and defenses.
7. Explainable AI.
8. Anomaly detection and domain generalization.
9. Attention mechanisms in computer vision and visual transformers.
2. Semi-supervised learning. K-nearest neighbors. Self-training algorithms.
3. Contrastive learning and Supervised Contrastive Learning.
4. Neural networks for object tracking.
5. Trustworthy AI. Safety, security, and predictability issues in deep neural networks.
6. Adversarial attacks and defenses.
7. Explainable AI.
8. Anomaly detection and domain generalization.
9. Attention mechanisms in computer vision and visual transformers.
Available for CircleU students: Yes
Neural Networks and Deep Learning: Deep Networks
Institution: Scuola Superiore Sant’Anna
Location: See link at: https://retis.santannapisa.it/~giorgio/courses/neural/nn.html
Level: Ph.D. level
Type: Intermediate course
Attendance Mode: Online
Exam: Yes
Lecturers: Giorgio Buttazzo
Email: giorgio.buttazzo@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: This module presents the foundations for understanding deep neural networks and deep learning algorithms. Topics include convolutional networks for classification, detection and segmentation, deep reinforcement learning, generative adversarial networks and transformers.
Syllabus: 1. Problems and solutions to extend small networks to deep networks.
2. Convolutional networks.
3. Networks for object classification.
4. Networks for object detection.
5. Networks for image segmentation.
6. Deep Reinforcement Learning.
7. Generative adversarial networks.
8. Recurrent neural networks.
9. Attention mechanism.
10. Transformers
2. Convolutional networks.
3. Networks for object classification.
4. Networks for object detection.
5. Networks for image segmentation.
6. Deep Reinforcement Learning.
7. Generative adversarial networks.
8. Recurrent neural networks.
9. Attention mechanism.
10. Transformers
Available for CircleU students: Yes
Neural Networks and Deep Learning: Implementation Issues
Institution: Scuola Superiore Sant’Anna
Location: See link at: https://retis.santannapisa.it/~giorgio/courses/neural/nn.html
Level: Ph.D. level
Type: Advanced course
Attendance Mode: Online
Exam: Yes
Lecturers: Giorgio Buttazzo
Email: giorgio.buttazzo@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 30
Abstract: The aim of this course is to discuss practical and implementation issues useful to
deploy neural networks on a variety of embedded platforms using different languages and
development environments.
deploy neural networks on a variety of embedded platforms using different languages and
development environments.
Syllabus: 1. Implementing Neural Networks from scratch in C.
2. Development frameworks: Tensorflow, Keras, Caffe, and Pytorch.
3. Functional components in autonomous driving.
4. The Apollo framework for autonomous driving.
5. Simulators for autonomous driving: the CARLA simulator.
6. DNN optimization for embedded platforms.
7. Accelerating deep networks on GPGPUs.
8. Overview of the Nvidia TensorRT framework.
9. Accelerating deep networks on FPGA using Xilinx Deep Processing Unit.
2. Development frameworks: Tensorflow, Keras, Caffe, and Pytorch.
3. Functional components in autonomous driving.
4. The Apollo framework for autonomous driving.
5. Simulators for autonomous driving: the CARLA simulator.
6. DNN optimization for embedded platforms.
7. Accelerating deep networks on GPGPUs.
8. Overview of the Nvidia TensorRT framework.
9. Accelerating deep networks on FPGA using Xilinx Deep Processing Unit.
Available for CircleU students: Yes
Neural Networks and Deep Learning: Theoretical Foundations
Institution: Scuola Superiore Sant’Anna
Location: See channel at: https://retis.santannapisa.it/~giorgio/courses/neural/nn.html
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Online
Exam: Yes
Lecturers: Giorgio Buttazzo
Email: giorgio.buttazzo@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: The aim of the course is to provide key concepts and methodologies to understand
neural networks, explaining how to use them for pattern recognition, image classification, signal prediction, system identification, and adaptive control.
neural networks, explaining how to use them for pattern recognition, image classification, signal prediction, system identification, and adaptive control.
Syllabus: 1. Introduction to neural computing.
2. Fully connected networks.
3. Unsupervised learning.
4. Clustering algorithms.
5. Autoencoders.
6. Reinforcement Learning.
7. Supervised learning
8. The Backpropagation algorithm.
9. Applications of neural networks to classification, signal prediction, and control.
10. Radial basis functions networks.
2. Fully connected networks.
3. Unsupervised learning.
4. Clustering algorithms.
5. Autoencoders.
6. Reinforcement Learning.
7. Supervised learning
8. The Backpropagation algorithm.
9. Applications of neural networks to classification, signal prediction, and control.
10. Radial basis functions networks.
Available for CircleU students: Yes
Numerical Linear Algebra in Python
Institution: Scuola Superiore Sant’Anna
Location: Scuola Superiore Sant’Anna
Level: Master level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Giovanni Stabile
Email: giovanni.stabile@santannapisa.it
Academic Year: 2024/2025
Semester: 1
Hours: 20
Abstract: The course deals with the theory and practical implementation of numerical methods for linear algebra problems. Specific topics include the solution of linear systems of equations using both direct and iterative methods, numerical methods for the approximation of eigenvalues and eigenvectors, numerical solution of nonlinear equations and systems of nonlinear equations. Particular emphasis is devoted to the implementation aspects using the python programming language.
Syllabus: no syllabus
Link:
Available for CircleU students: Yes
OpenFOAM laboratory
Institution: Scuola Superiore Sant’Anna
Location: Scuola Superiore Sant’Anna Pisa
Level: Master level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Giovanni Stabile
Email: giovanni.stabile@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 10
Abstract: This course introduces the open source toolbox, OpenFOAM a widely used library for computational fluid dynamics. It provides a foundation for all aspects of OpenFOAM, from running cases to programming, so is useful to both new users and existing users wishing to broaden their basic knowledge of OpenFOAM.
Syllabus: no syllabus
Link:
Available for CircleU students: Yes
Predictive Models for Time Series Analysis
Institution: Università di Pisa
Location: Pisa, Largo B. Pontecorvo, Building C, Room Seminari Est, Dept. C.S.
Level: Post graduate Master level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Riccardo Guidotti
Email: riccardo.guidotti@unipi.it
Academic Year: 2024/2025
Semester: 2
Hours: 24
Abstract: This course on Time Series Analytics is designed to equip students with comprehensive knowledge and skills to analyze, interpret, and build predictive models for time series data. The course covers fundamental concepts, including time series components, normalizations, stationarity, autocorrelation, approximation and various forms of time series transformations, while delving into predictive models passing from DTW based kNN to state-of-the-art kernel-based and dictionary-based approaches. Emphasis is placed on both the theoretical underpinnings and practical applications of these techniques in general-purpose domains. By the end of the course, participants will have developed the analytical acumen and technical expertise necessary to conduct independent research and contribute novel insights to the field of time series analysis. This course is essential for aspiring data scientists, quantitative analysts, and researchers seeking to deepen their understanding and application of time series methods.
Syllabus: 1. Introduction & Preprocessing (4 hours)
2. Distances, Approximation & Global Features (4 hours)
3. Classification & Regression Part 1 (4 hours)
4. Classification & Regression Part 2 (4 hours)
5. Forecasting (4 hours)
6. In-class Project
2. Distances, Approximation & Global Features (4 hours)
3. Classification & Regression Part 1 (4 hours)
4. Classification & Regression Part 2 (4 hours)
5. Forecasting (4 hours)
6. In-class Project
Available for CircleU students: Yes
Programming & Data Analytics & Process-oriented Data Science for non-computer scientists (PDAI1 & PDAI2-PM)
Institution: Scuola Superiore Sant’Anna
Location: Piazza Martiri della Liberta’ 33, Pisa
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Andrea Vandin, Daniele Giachini
Email: andrea.vandin@santannapisa.it
Academic Year: 2024/2025
Semester: 1, 2
Hours: 40
Abstract: This course is structured in three modules of 20-hours each (PDAI1, PDAI2-ML, PDAI2-PM) that students can attend in different years. PDAI1 is offered each year, while the other two alternate. PDAI1 is preparatory to the other two, which can be taken independently of each other. In this A.Y., PDAI1 and PDAI2-PM will be offered.
The course provides a well-structured introduction to the fundamentals of (object-oriented) programming (PDAI1), data processing and artificial intelligence (PDAI2-ML), and process-oriented data science (process mining, PDAI2-PM). The course will focus on how to create good quality software (PDAI1), on how to carry out good quality data analysis and artificial intelligence projects (PDAI2-ML), and on research-oriented aspects related to process-oriented data science, in particular on process mining, where the aim is to analyse and optimise the data-generating process (PDAI2-PM). The student who has achieved the course objectives will gain an understanding of the problems and tasks related to structured programming, data analysis and machine learning in order to be able to make informed decisions. The student will be able to write Python programmes of various kinds, with a focus on complex data analysis and AI tasks, and process mining.
Syllabus: • PDAI 1 introduces students to the fundamental principles of structured programming, with basic applications to data processing. It starts from basic notions of programming (variables, data types, collections, control & repetition structures, functions & modules), and progresses to basic data processing functionalities (loading, manipulation, and visualization of CSV data).
• PDAI 2-ML introduces students to the components of typical data analysis processes and machine learning pipelines. It first builds the necessary toolset by introducing popular Python libraries for data manipulation/visualization (NumPy, Pandas, Seaborn, scikit-learn) with simple applications. The toolset is then applied to a more complex case study on the classification of benign and malignant breast cancer, including aspects of data preprocessing, dimensionality reduction, clustering, and classification. The course will conclude with one research-driven topics like process-oriented data science (Process Mining).
• PDAI 2-PM introduces students to recent data-driven techniques where the main component is the process that generated the data (the data generating process). This is a particularly hot topic, with many companies and researchers involved (see, e.g., the list of industrial that sponsored the reference conference in 2023 https://icpmconference.org/2023/sponsor-and-exhibition/). We will consider techniques known as Process Mining, in which logs generated during the execution of a process (e.g., an industrial production process, business processes, social system ‘processes’) are used to infer the structure of the process. Questions of interest are, e.g.: What is the actual process being executed? Are there possibilities for improvement? Does the actual process conform to the intended reference process?
• PDAI 2-ML introduces students to the components of typical data analysis processes and machine learning pipelines. It first builds the necessary toolset by introducing popular Python libraries for data manipulation/visualization (NumPy, Pandas, Seaborn, scikit-learn) with simple applications. The toolset is then applied to a more complex case study on the classification of benign and malignant breast cancer, including aspects of data preprocessing, dimensionality reduction, clustering, and classification. The course will conclude with one research-driven topics like process-oriented data science (Process Mining).
• PDAI 2-PM introduces students to recent data-driven techniques where the main component is the process that generated the data (the data generating process). This is a particularly hot topic, with many companies and researchers involved (see, e.g., the list of industrial that sponsored the reference conference in 2023 https://icpmconference.org/2023/sponsor-and-exhibition/). We will consider techniques known as Process Mining, in which logs generated during the execution of a process (e.g., an industrial production process, business processes, social system ‘processes’) are used to infer the structure of the process. Questions of interest are, e.g.: What is the actual process being executed? Are there possibilities for improvement? Does the actual process conform to the intended reference process?
Available for CircleU students: Yes
Responsible Generative AI
Institution: Scuola Normale Superiore
Location: Scuola Normale Superiore, Palazzo della Carovana
Level: Ph.D. level
Type: Advanced course
Attendance Mode: Blended
Exam: Yes
Lecturers: Prof. Fosca Giannotti, Dr. Gizem Gezici
Email: gizem.gezici@sns.it, fosca.giannotti@sns.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: The rapid development and deployment of generative AI models and applications has the potential to revolutionise various domains which brings about the urgency to use these models in a responsible manner. Generative AI refers to creating new content in different modalities of digital text, images, audio, code and other artefacts based on already existing content. Text generator models such as GPT-4, and its chat version, ChatGPT as well as text to image models such as DALL-E 3 and Stable Diffusion are popular generative AI models. Although these models have significant implications for a wide spectrum of domains, there are several ethical and social considerations associated with generative AI models and applications. These concerns include the existence of bias, lack of interpretability, privacy, fake and misleading content such as hallucinations. Thus, it is very crucial to discuss these risks with their corresponding potential safeguards (if any) in addition to the technical details of these powerful models.
The course is organized as follows in three modules: i) an introductory one presenting main motivations as well as main concepts in NLP and further generative AI; ii) an advanced module providing technical details about the building blocks of foundation models with the main focus on the text generation models which also includes an hands-on session on LLMs; iii) an advanced module providing the main risks of generative AI with the corresponding technical considerations and challenges to establish responsible generative AI models in practice which includes a hands-on session as well.
The course is organized as follows in three modules: i) an introductory one presenting main motivations as well as main concepts in NLP and further generative AI; ii) an advanced module providing technical details about the building blocks of foundation models with the main focus on the text generation models which also includes an hands-on session on LLMs; iii) an advanced module providing the main risks of generative AI with the corresponding technical considerations and challenges to establish responsible generative AI models in practice which includes a hands-on session as well.
Syllabus: https://docs.google.com/document/d/1XURfLr725RcIXdoBHiaLdrwmPI-Awy3N/edit
Link:
Available for CircleU students: No
Social network analysis
Institution: Università di Pisa, Consiglio Nazionale delle Ricerche
Location: University of Pisa, Largo Bruno Pontecorvo
Level: Master level
Type: Introductory course (no or few prerequisites)
Attendance Mode: In person
Exam: Yes
Lecturers: Dino Pedreschi, Giulio Rossetti
Email: giulio.rossetti@isti.cnr.it, dino.pedreschi@unipi.it
Academic Year: 2024/2025
Semester: 2
Hours: 48
Abstract: Over the past decade there has been a growing public fascination with the complex “connectedness” of modern society. This connectedness is found in many contexts: in the rapid growth of the Internet and the Web, in the ease with which global communication now takes place, and in the ability of news and information as well as epidemics and financial crises to spread around the world with surprising speed and intensity. These are phenomena that involve networks and the aggregate behavior of groups of people; they are based on the links that connect us and the ways in which each of our decisions can have subtle consequences for the outcomes of everyone else. This course is an introduction to the analysis of complex networks, with a special focus on social networks and the Web – their structure and function, and how it can be exploited to search for information. Drawing on ideas from computing and information science, applied mathematics, economics and sociology, the course describes the emerging field of study that is growing at the interface of all these areas, addressing fundamental questions about how the social, economic, and technological worlds are connected. Data-driven analysis of complex networks using a variety of models and software tools.
Syllabus: Real-world network characterization:
Big graph data and social, information, biological and technological networks
The architecture of complexity and how real networks differ from random networks: node degree and long tails, social distance and small worlds, clustering, and triadic closure.
Comparing real networks and random graphs. The main models of network science: small world and preferential attachment.
Assortativity and homophilic behaviors.
Strong and weak ties, community structure, and long-range bridges.
Network beyond pairwise interactions: high-order network modeling.
Applications:
Robustness of networks to failures and attacks.
Dynamic Network modeling.
Dynamic Community Discovery.
Link Prediction
Cascades and spreading.
Network models for opinion dynamics and epidemics.
Big graph data and social, information, biological and technological networks
The architecture of complexity and how real networks differ from random networks: node degree and long tails, social distance and small worlds, clustering, and triadic closure.
Comparing real networks and random graphs. The main models of network science: small world and preferential attachment.
Assortativity and homophilic behaviors.
Strong and weak ties, community structure, and long-range bridges.
Network beyond pairwise interactions: high-order network modeling.
Applications:
Robustness of networks to failures and attacks.
Dynamic Network modeling.
Dynamic Community Discovery.
Link Prediction
Cascades and spreading.
Network models for opinion dynamics and epidemics.
Available for CircleU students: No
Statistical Learning and Large Data (SLLD)
Institution: Scuola Superiore Sant’Anna
Location: Piazza Martiri della Libertà, 33 56127 Pisa (Italia)
Level: Post graduate Master level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Francesca Chiaromonte
Email: francesca.chiaromonte@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 40
Abstract: This course will introduce the students to various topics in contemporary Statistical Learning and to methods used to analyze the large, complex datasets that are increasingly common in many scientific fields. The content will be organized in two Modules that the students can attend in different years. Compared to traditional courses, the focus will be on analyzing actual datasets of interest to the students through group projects and Practicum sessions associated to each lecture.
Syllabus: Module 1
– Unsupervised classification; Clustering methods
– Unsupervised dimension reduction; Principal Components Analysis and related techniques
– Supervised classification methods
– Non-parametric regression methods
– Resampling methods, Cross Validation, the Bootstrap and permutation-based techniques.
Prerequisites: a working knowledge of basic statistical inference (point estimation, confidence intervals, testing) and linear and generalized linear models. This may be obtained, or refreshed, through Applied Statistics.
Evaluation: Group project with final presentation and written report.
Materials: An Introduction to Statistical Learning – with Applications in R (James, Witten, Hastie, Tibshirani; Springer). Links to further material will be provided as needed.
– Unsupervised classification; Clustering methods
– Unsupervised dimension reduction; Principal Components Analysis and related techniques
– Supervised classification methods
– Non-parametric regression methods
– Resampling methods, Cross Validation, the Bootstrap and permutation-based techniques.
Prerequisites: a working knowledge of basic statistical inference (point estimation, confidence intervals, testing) and linear and generalized linear models. This may be obtained, or refreshed, through Applied Statistics.
Evaluation: Group project with final presentation and written report.
Materials: An Introduction to Statistical Learning – with Applications in R (James, Witten, Hastie, Tibshirani; Springer). Links to further material will be provided as needed.
Module 2
– Feature selection and regularization techniques for high-dimensional Linear and Generalized Linear Models
– Feature screening algorithms for ultra-high dimensional supervised problems
– Supervised dimension reduction; Sufficient Dimension Reduction and related techniques
– Subsampling/partitioning approaches for ultra-high sample sizes
– Under- and oversampling approaches for data rebalancing
Prerequisites: a working knowledge of the methods comprised in Module 1.
Evaluation: Group project with final presentation and written report.
Materials: An Introduction to Statistical Learning – with Applications in R (James, Witten, Hastie, Tibshirani; Springer). Computer Age Statistical Inference (B. Efron, T. Hastie). Links to further material will be provided as needed.
Available for CircleU students: No
Statistics for Machine Learning
Institution: Università di Pisa
Location: Dipartimento di Informatica, Università di Pisa, Largo B. Pontecorvo 3, 56125 Pisa, Italy
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Salvatore Ruggieri
Email: salvatore.ruggieri@unipi.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: The student who completes successfully the course will have a solid knowledge on the main concepts and tools of statistical analysis, including the definition of a statistical model, the inference of its parameters with confidence intervals, the use of hypothesis testing, bayesian and causal inference, with specific applications to problems and models useful in (supervised) machine learning.
Syllabus: The program covers the basic methodologies, techniques and tools of statistical analysis. This includes basic knowledge of probability theory, random variables, convergence theorems, statistical models, estimation theory, hypothesis testing, bayesian inference, causal reasoning. Other topics covered include bootstrap, expectation-maximization, and applications to machine learning problems.
Available for CircleU students:
The use of AI in criminal justice: theoretical, social and legal implications
Institution: Scuola Superiore Sant’Anna
Location: Piazza Martiri della Libertà, 33, Pisa
Level: Ph.D. level
Type: Introductory course (no or few prerequisites)
Attendance Mode: Blended
Exam: Yes
Lecturers: Gaetana Morgante, Gaia Fiorinelli
Email: Gaia.Fiorinelli@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 10
Abstract: The course focuses on the use of artificial intelligence (AI) in criminal justice, covering all phases from policing to risk assessment, sentencing and detention. It aims to provide students with a critical understanding of the theoretical, social and legal implications of the use of AI in these contexts, with reference to AI regulations, fundamental rights, and criminal law principles. Particular attention will be devoted to recent international, European and national frameworks and policies, such as the AI Act, the Council of Europe Framework Convention on AI, and EU/CoE recommendations and resolutions on AI in criminal justice. In addition, the course will explore how AI challenges and potentially reshapes traditional criminal law concepts related to risk assessment and responsibility. No prior knowledge of criminal law is required, as the course is intended to foster interdisciplinary dialogue among students from different academic backgrounds.
Syllabus: – The use of AI in predictive policing: applications, risks and legal safeguards.
– AI in criminal risk assessment and the evolving notions of dangerousness and recidivism.
– The use of AI in sentencing: criminal justice between fairness and bias.
– AI in prisons and probation and its impact on detainees’ fundamental rights and rehabilitation.
– The use of AI for corporate criminal compliance: opportunities and risks.
– AI in criminal risk assessment and the evolving notions of dangerousness and recidivism.
– The use of AI in sentencing: criminal justice between fairness and bias.
– AI in prisons and probation and its impact on detainees’ fundamental rights and rehabilitation.
– The use of AI for corporate criminal compliance: opportunities and risks.
Link:
Available for CircleU students: No
Time Series Analysis
Institution: Scuola Superiore Sant’Anna
Location: Piazza Martiri della Libertà 33, Pisa
Level: Ph.D. level
Type: Advanced course
Attendance Mode: In person
Exam: Yes
Lecturers: Matteo Barigozzi
Email: laura.magazzini@santannapisa.it
Academic Year: 2024/2025
Semester: 2
Hours: 20
Abstract: The course aims to cover basic topics in time-series with focus on macroeconomic and financial applications. It will cover univariate and multivariate time serieswith a focus on linear models and their estimation. Such tools are essential for PhD students who aspire to conduct careful, state-of-the-art empirical research. In addition, the course will provide general guidance on formulating and executing (empirical) research ideas.
Syllabus: – Stationarity of univariate time series
– ARMA
– Unit roots
– Forecasting
– Non linear models for volatiltiy ARCH GARCH
– Stationarity of multivariate time series
– Wold representation
– VAR
– Unit roots and cointegration
– VECM
– Impulse response analysis
– Structural time series models
– Kalman filter
– ARMA
– Unit roots
– Forecasting
– Non linear models for volatiltiy ARCH GARCH
– Stationarity of multivariate time series
– Wold representation
– VAR
– Unit roots and cointegration
– VECM
– Impulse response analysis
– Structural time series models
– Kalman filter
Available for CircleU students:
Visual analytics
Institution: Università di Pisa, Consiglio Nazionale delle Ricerche
Location: University of Pisa. Location to be announced
Level: Master level
Type: Intermediate course
Attendance Mode: Blended
Exam: Yes
Lecturers: Salvatore Rinzivillo
Email: rinzivillo@isti.cnr.it
Academic Year: 2024/2025
Semester: 2
Hours: 48
Abstract: The module aims at preparing students to the approprieted presentation of data and knowledge extracted from them through visualization tools and narratives that exploit multimedia.
The module first presents the basic visualization techniques for the effective presentation of information from several different sources: structured data (relational, hierarchies, trees), relational data (social networks), temporal data, spatial data and spatio-temporal data.
The module first presents the basic visualization techniques for the effective presentation of information from several different sources: structured data (relational, hierarchies, trees), relational data (social networks), temporal data, spatial data and spatio-temporal data.
Syllabus: -Metaphors of information visualization.
* Hierarchical and structural
* Relational
* Temporal
* Spatial
* Temporal space
* Unstructured information (text)
– Methods and Tools.
* Overview of existing visualization environments and libraries.
– Visual Analytics Processes.
* Definition of a knowledge discovery process.
* Integrated environments for Visual Analytics.
* Exploratory visual analytics of data and models.
* Examples and case studies
* Hierarchical and structural
* Relational
* Temporal
* Spatial
* Temporal space
* Unstructured information (text)
– Methods and Tools.
* Overview of existing visualization environments and libraries.
– Visual Analytics Processes.
* Definition of a knowledge discovery process.
* Integrated environments for Visual Analytics.
* Exploratory visual analytics of data and models.
* Examples and case studies
Available for CircleU students: Yes