CODE 80107 ACADEMIC YEAR 2024/2025 CREDITS 8 cfu anno 1 MATEMATICA 8760 (L-35) - GENOVA 8 cfu anno 1 STATISTICA MATEM. E TRATTAM. INFORMATICO DEI DATI 8766 (L-35) - GENOVA 4 cfu anno 1 FISICA 8758 (L-30) - GENOVA SCIENTIFIC DISCIPLINARY SECTOR MAT/03 LANGUAGE Italian TEACHING LOCATION GENOVA SEMESTER 2° Semester MODULES Questo insegnamento è un modulo di: LINEAR ALGEBRA AND GEOMETRY TEACHING MATERIALS AULAWEB AIMS AND CONTENT LEARNING OUTCOMES The aim of the course is to introduce students to the basic elements of linear algebra, affine and Euclidean geometry. These topics are part of the fundamentals of the study of modern mathematics and will be used in all subsequent courses. In addition, it is not a secondary objective to show students a theory that is strongly motivated by concrete problems, and that can be treated in a comprehensive and rigorous manner. AIMS AND LEARNING OUTCOMES The purpose of this course is to consolidate the techniques already learned in the previous module of the same course. In particular, the aims are the followings: Diagonalizability and diagonalization of linear applications: definitions and properties of diagonalizable endomorphisms; eigenvalues, eigenvectors, eigenspaces; characteristic polynomial of an endomorphism, properties and relation to eigenvalues; diagonalizability criterion. Triangulability and triangulation of endomorphisms: definition and properties of triangulable endomorphisms; triangulability criterion; characteristic spaces, Lemma of cores and Cayley-Hamilton Theorem; nilpotent endomorphisms and their triangulation by completion of the bases and by Jordan decomposition; triangulation of endomorphisms in general. Bilinear applications: dual vector space, dual basis, transposed linear application; bilinear forms and applications and properties, matrix of a bilinear form and properties (symmetric bilinear forms, nondegenerate bilinear forms), congruence of matrices. Defining character of a symmetric bilinear form on a real vector space, Euclidean vector spaces, norms and angles, orthogonality, orthogonal projections; orthonormal bases Gram-Schmidt theorem, orthogonal complement of a subspace. Endomorphisms between Euclidean vector spaces: isometries and their characterizations, orthogonal and special orthogonal matrices, properties, description of plane isometries; self-adjoint endomorphisms and their characterizations, symmetrical matrices, real spectral theorem, diagonalization of self-adjoint endomorphisms by means of orthonormal bases. Signature of a real symmetric matrix, Sylvester's inertia theorem. Conics and quadrics: definition of a quadric, matrix associated with a quadric and quadratic form matrix. Classification of quadrics by affine transformations, geometric properties of conics and quadrics, bundles of conics. Affine and projective spaces: definition of affine space over a field, and Euclidean affine space, and their properties. Lines, planes, hyperplanes in an affine space, Euclid's five postulates; affine transformations, coordinate systems and coordinate changes. Projective spaces: motivations, models of projective spaces. Straight lines, planes, hyperplanes in a projective space, Euclid's fifth postulate does not apply in projective geometry. Homogeneous coordinates, equations of lines and planes, affine maps, points at infinity. Projectivity: definition, properties, characterization of fixed points, fixed lines, fixed point lines using linear algebra. At the end of the course the students will be able to: Determine whether an endomorphism is diagonalizable and diagonalize it. Determine whether an endomorphism is triangulable and determine its canonical Jordan form. Work with bilinear forms. Classify projective and affine conics and quadrics. TEACHING METHODS Standard Frontal Lesson SYLLABUS/CONTENT Diagonalization and triangulation Euclidean vector spaces Isometries and self-adjoint endomorphisms Conics and quadrics Affine and projective spaces RECOMMENDED READING/BIBLIOGRAPHY M.E. Rossi, Algebra lineare, Dispense disponibili nella pagina del corso F. Odetti - M. Raimondo, Elementi di Algebra Lineare e Geometria Analitica, ECIG Universitas. Marco Abate, Algebra Lineare , ed. McGraw-Hill E. Sernesi, Geometria vol 1, ed Bollati-Boringhieri. A.Bernardi, A.Gimigliano, Algebra Lineare e Geometria Analitica, Citta'Studi Edizioni. TEACHERS AND EXAM BOARD ELEONORA ANNA ROMANO Ricevimento: Office hours to be decided with the Professor, by writing to her e-mail address: romano@dima.unige.it MATTEO PENEGINI Ricevimento: By appointment. MARIA ROSARIA PATI Exam Board EMANUELA DE NEGRI (President) VICTOR LOZOVANU MARIA ROSARIA PATI (President Substitute) MATTEO PENEGINI (President Substitute) ELEONORA ANNA ROMANO (President Substitute) FABIO TANTURRI (President Substitute) LESSONS Class schedule The timetable for this course is available here: Portale EasyAcademy EXAMS EXAM DESCRIPTION The examination consists of a written and an oral part. Students with a certified DSA, disability or other special educational needs are advised to contact the lecturer at the beginning of the course in order to agree on teaching and examination methods that, while respecting the teaching objectives, take into account individual learning methods and provide suitable compensatory tools. ASSESSMENT METHODS In the written test, the student is asked to solve exercises covering the entire course syllabus. In the oral test, students in Mathematics and SMID are required to know and be able to present the definitions, statements of theorms and their proofs seen throughout the course. Exam schedule Data appello Orario Luogo Degree type Note 27/06/2025 09:00 GENOVA Scritto 22/07/2025 09:00 GENOVA Scritto 01/09/2025 09:00 GENOVA Scritto FURTHER INFORMATION Students who have valid certification of physical or learning disabilities on file with the University and who wish to discuss possible accommodations or other circumstances regarding lectures, coursework and exams, should speak both with the instructor and with Professor Sergio Di Domizio (sergio.didomizio@unige.it), the Department’s disability liaison. Agenda 2030 - Sustainable Development Goals Quality education Gender equality