MATHEMATICAL ANALYSIS II

Course objectives

GENERAL OBJECTIVES The student must be able to study and use - curves and surfaces, - partial and directional derivatives of functions of several variables - two-dimensional and three-dimensional domains, - curvilinear coordinates (polar, spherical, cylindrical), - multiple, surface and line integrals, - vector fields and differential forms; line integrals and circulations; irrotational fields; conservative fields and their potentials, - the various differential operators and apply the Divergence and Curl Theorems to the calculation of flows, - power, Taylor and Fourier series.   SPECIFIC OBJECTIVES: KNOWLEDGE AND UNDERSTANDING. The course will provide in-depth knowledge and understanding of the fundamental concepts and tools of Analysis in several variables, in particular the use of differentiation and integration in several variables; curves and surfaces; differential operators, such as the gradient, divergence, curl, Laplacian; sequences and series of functions, with particular attention to Taylor and Fourier series. APPLYING KNOWLEDGE AND UDERSTANDING. The student will be able to apply the tools learned in this course to practical problems, which arise from Physics and Engineering, such as the study of Partial Differential Equations, the study of vector fields, the calculation of centers of mass, moments of inertia, work of conservative and non- conservative forces, the applications of Gauss’ and Stokes’ Theorems and the study of Maxwell's Equations. CRITICAL AND JUDGMENT SKILLS. The course will allow the student to choose, given a physical or engineering problem, the best resolution methodology, through a deep understanding of the requirements and constraints imposed by the context. COMMUNICATION SKILLS. At the end of the course the student will be able to illustrate the importance of the tools learned in the lessons, in order to apply them to problems of Physics and Engineering, such as the reconstruction of signals, the study of problems of fluid dynamics, electromagnetism, hydrodynamics and in general problems that involve the use of the tools of differential and integral calculus in several variables. LEARNING ABILITY. The student will develop independent study skills, for what concerns the theoretical study of the topics covered by the course and their application to concrete problems in Physics and Engineering.

Channel 1
ALBERTO MARIA BERSANI Lecturers' profile

Program - Frequency - Exams

Course program
Curves. Review of vector calculus. Vector valued functions, limits and continuity. Regular curves and differential vector calculus. Length of a curve arc. arc parameter or arc length. Elements of differential geometry of curves (outline): tangent, normal, curvature, twist, intrinsic triad (10 hours). Differential calculus for real functions of several variables. Graphics and level sets. Limits and continuous functions of several variables. Topology in Rn and properties of continuous functions (10 hours). Partial derivatives, tangent plane, differential, directional derivatives. Higher order derivatives and successive approximations. Partial differential equations and classification of second-order equations (introduction) (10 hours). Unconstrained optimization (5 hours). Differential calculus for vector-valued functions of several variables. Vector-valued functions of several variables: generalities. Surfaces in parametric form. Limits, continuity and differentiability for functions f: Rn → Rm. Smooth surfaces in parametric form. Coordinate transformations and their inverses (10 hours). Constrained optimization (5 hours). Integral calculus for functions of several variables. Double integrals. The calculation of triple integrals (10 hours). Vector fields. Field lines. Gradient, divergence and curl. Differential forms and work. Line integrals of the second kind. Irrotational, solenoidal, conservative fields. Potential. Gauss-Green formula in the plane. Area and surface integrals. Surface integral of a vector field (flux). Divergence (or Gauss) Theorem. Curl (or Stokes) Theorem (10 hours). Sequences of functions. Pointwise and uniform convergence (10 hours). Series of functions and total convergence. Power series and Taylor series. Trigonometric series and Fourier series. Pointwise and total convergence of Fourier series (10 hours).
Prerequisites
Geometry and Mathematical Analysis 1: elements of Linear Algebra (vectors, matrixes, and operations); elements of Plane and Space Geometry (lines, planes, conics, quadrics); elements of theory of linear transformations; Elements of Mathematical Analysis (complex numbers, sequences, series, limits, derivatives, functions and graphs, Taylor polynomials, definite, indefinite and improper integrals, ordinary differential equation).
Books
M. Bramanti, C.D. Pagani, S. Salsa: Analisi Matematica 2. Zanichelli, 2009. M. Amar, A.M. Bersani: ANALISI MATEMATICA I – Esercizi e richiami di teoria. Amazon 2022. M. Amar, A.M. Bersani: ANALISI MATEMATICA II – Esercizi e richiami di teoria. Amazon 2022. D. Andreucci, A.M. Bersani: RISOLUZIONI DI PROBLEMI D’ESAME DI ANALISI MATEMATICA II. Esculapio, 1998. online supplementary educational materials on the web page http://www.dmmm.uniroma1.it/~alberto.bersani/A2.htm
Teaching mode
The courses are based on theoretical lessons and exercises, given by the thacher, together with exercises classes given by a tutor.
Frequency
The attendance is optional, but strongly recommended
Exam mode
At the end of the course, starting from June, the written exam (lasting 2 hours and half) consists of 5 exercises concerning the topics of the programme, with the aim of testing the knowledge level of the several techniques useful to solve the problems of the final test. If the written exam receives an evaluation greater or equal to 15/30, the theory exam (written - 1 hour and half - or oral - 1 hour -, depending on student's request), consists of 2 theory questions (definitions, theorem statements, proofs, examples, counterexamples), starting from the results and mistakes in the written exam, in order to test the knowledge level of the theoretical aspects of the course. The final score is a weighted mean between the scores of the written exam and of the oral exam. In both the tests the student must obtain a score greater or equal to 15/30.
Bibliography
M. Bramanti, C.D. Pagani, S. Salsa: Analisi Matematica 2. Zanichelli, 2009. M. Amar, A.M. Bersani: ANALISI MATEMATICA I – Esercizi e richiami di teoria. LaDotta, 2012. M. Amar, A.M. Bersani: ANALISI MATEMATICA II – Esercizi e richiami di teoria. LaDotta, 2014. D. Andreucci, A.M. Bersani: RISOLUZIONI DI PROBLEMI D’ESAME DI ANALISI MATEMATICA II. Esculapio, 1998. online supplementary educational materials on the web page http://www.dmmm.uniroma1.it/~alberto.bersani/A2.htm
Lesson mode
The courses are based on theoretical lessons and exercises, given by the thacher, together with exercises classes given by a tutor.
ALBERTO MARIA BERSANI Lecturers' profile

Program - Frequency - Exams

Course program
Curves. Review of vector calculus. Vector valued functions, limits and continuity. Regular curves and differential vector calculus. Length of a curve arc. arc parameter or arc length. Elements of differential geometry of curves (outline): tangent, normal, curvature, twist, intrinsic triad (10 hours). Differential calculus for real functions of several variables. Graphics and level sets. Limits and continuous functions of several variables. Topology in Rn and properties of continuous functions (10 hours). Partial derivatives, tangent plane, differential, directional derivatives. Higher order derivatives and successive approximations. Partial differential equations and classification of second-order equations (introduction) (10 hours). Unconstrained optimization (5 hours). Differential calculus for vector-valued functions of several variables. Vector-valued functions of several variables: generalities. Surfaces in parametric form. Limits, continuity and differentiability for functions f: Rn → Rm. Smooth surfaces in parametric form. Coordinate transformations and their inverses (10 hours). Constrained optimization (5 hours). Integral calculus for functions of several variables. Double integrals. The calculation of triple integrals (10 hours). Vector fields. Field lines. Gradient, divergence and curl. Differential forms and work. Line integrals of the second kind. Irrotational, solenoidal, conservative fields. Potential. Gauss-Green formula in the plane. Area and surface integrals. Surface integral of a vector field (flux). Divergence (or Gauss) Theorem. Curl (or Stokes) Theorem (10 hours). Sequences of functions. Pointwise and uniform convergence (10 hours). Series of functions and total convergence. Power series and Taylor series. Trigonometric series and Fourier series. Pointwise and total convergence of Fourier series (10 hours).
Prerequisites
Geometry and Mathematical Analysis 1: elements of Linear Algebra (vectors, matrixes, and operations); elements of Plane and Space Geometry (lines, planes, conics, quadrics); elements of theory of linear transformations; Elements of Mathematical Analysis (complex numbers, sequences, series, limits, derivatives, functions and graphs, Taylor polynomials, definite, indefinite and improper integrals, ordinary differential equation).
Books
M. Bramanti, C.D. Pagani, S. Salsa: Analisi Matematica 2. Zanichelli, 2009. M. Amar, A.M. Bersani: ANALISI MATEMATICA I – Esercizi e richiami di teoria. Amazon 2022. M. Amar, A.M. Bersani: ANALISI MATEMATICA II – Esercizi e richiami di teoria. Amazon 2022. D. Andreucci, A.M. Bersani: RISOLUZIONI DI PROBLEMI D’ESAME DI ANALISI MATEMATICA II. Esculapio, 1998. online supplementary educational materials on the web page http://www.dmmm.uniroma1.it/~alberto.bersani/A2.htm
Teaching mode
The courses are based on theoretical lessons and exercises, given by the thacher, together with exercises classes given by a tutor.
Frequency
The attendance is optional, but strongly recommended
Exam mode
At the end of the course, starting from June, the written exam (lasting 2 hours and half) consists of 5 exercises concerning the topics of the programme, with the aim of testing the knowledge level of the several techniques useful to solve the problems of the final test. If the written exam receives an evaluation greater or equal to 15/30, the theory exam (written - 1 hour and half - or oral - 1 hour -, depending on student's request), consists of 2 theory questions (definitions, theorem statements, proofs, examples, counterexamples), starting from the results and mistakes in the written exam, in order to test the knowledge level of the theoretical aspects of the course. The final score is a weighted mean between the scores of the written exam and of the oral exam. In both the tests the student must obtain a score greater or equal to 15/30.
Bibliography
M. Bramanti, C.D. Pagani, S. Salsa: Analisi Matematica 2. Zanichelli, 2009. M. Amar, A.M. Bersani: ANALISI MATEMATICA I – Esercizi e richiami di teoria. LaDotta, 2012. M. Amar, A.M. Bersani: ANALISI MATEMATICA II – Esercizi e richiami di teoria. LaDotta, 2014. D. Andreucci, A.M. Bersani: RISOLUZIONI DI PROBLEMI D’ESAME DI ANALISI MATEMATICA II. Esculapio, 1998. online supplementary educational materials on the web page http://www.dmmm.uniroma1.it/~alberto.bersani/A2.htm
Lesson mode
The courses are based on theoretical lessons and exercises, given by the thacher, together with exercises classes given by a tutor.
Lecturers' profile
Lecturers' profile
  • Lesson code1015376
  • Academic year2025/2026
  • Coursecorso|33498
  • CurriculumGestionale
  • Year1st year
  • Semester2nd semester
  • SSDMAT/05
  • CFU9
  • Subject areaMatematica, informatica e statistica