Unit GEOMATHEMATICS
 Course
 Geosciences for risk and environment management
 Studyunit Code
 GP004871
 Curriculum
 Geologia applicata alla salvaguardia e alla pianificazione del territorio
 Teacher
 Luca Zampogni
 Teachers

 Luca Zampogni
 Hours
 42 ore  Luca Zampogni
 CFU
 6
 Course Regulation
 Coorte 2024
 Offered
 2024/25
 Learning activities
 Affine/integrativa
 Area
 Attività formative affini o integrative
 Academic discipline
 MAT/05
 Type of studyunit
 Opzionale (Optional)
 Type of learning activities
 Attività formativa monodisciplinare
 Language of instruction
 Italian
 Contents
 First and second order ordinary differential equations. Fouries series and applications. Partial differential equations: traffic equation, and the method of characteristics. The wave equation: Cauchy and CauchyDirichlet problems. Application to geology: the equation of sismology, the Kortevegde Vries equation and the Tsunami equation
 Reference texts
 James Stewart: Calcolo, funzioni di più variabili, ed. Apogeo.
Fabio Scarabotti: Equazioni alle derivate parziali: teoria elementare e applicazioni, ed. Esculapio.  Educational objectives
 The student should acquire a basic knowledge of qualitative analysis of a Cauchy problem and of the theory necessary to deal with simple partial differential equations. The course matter is part of the contents of a standard reformed second level course for Italian master degrees in Geological Sciences. Even the setting is reformed, and the textbooks used are rich of examples and counterexamples, and therefore seem to be optimal to achieve a good understanding of the topics starting from exercises, that is from applications.Main knowledge acquired will be:
 To know the main topics of mathematical analysis and how to apply them to the earth sciences,
 To know the basilar theory of parabolic partial differential equations,
To know several tools to solve elementary and basilar exercises,
 To read and understand basilar texts of Mathematical Analysis,
 To work in teams, but also in autonomy.
The skills listed above are set out in the framework of the professions related to both a traditional Geologist, and a Geologist oriented to technical and/or industrial activities.Main competence (i.e. ability to apply the main knowledge acquired) will be: To apply the theory to the resolution of exercises or problems based on models developed during lessons
 To analyze and treat simple qualitative problems in order to understand the appropriate second level analysis to perform,
 To solve some easy mathematical problems in the field of applied mathematics, indipendently.  Prerequisites
 To understand the topics covered in this course, the student should be familiar with all the contents of the courses Matematica (mod. 1 e mod. 2) included in the first level degree. In particular, a robust knowledge of the main definitions and elementary functions (polynomial functions, exponential function, logarithm and circular functions), a good knowledge in calculating limits and derivatives, and finally good knowledge of direct integrations, of integration of rational functions, of integration by parts and by substitution.
 Teaching methods
 Facetoface and practical training
 Other information
 Optional but recommended attendance
 Learning verification modality
 The exam is written with open answers. In particular the written test consists of solving (generally) 4 exercises on the main topics of the programme.
 Extended program
 A. Some notions about differential calculus on more variables.
B. Ordinary differential equations:
1b. Examples
2b Cauchy problems
3b Existence and uniqueness
4b separation of variables for ordinary equations
5b first order diff. equations
6b second order differential equations
7b varition of constants method
8b the Bernoulli equation
9b the energymethod for some diff. equations
10 examples and applications
C. Fourier series
1c pointwise convergence and uniform convergence. Limit theorems
2c The trigonometric system
3c The Fourier series. Pointwise and uniform convergence, Bessel inequality
4c Total convergence and Parseval relation
5c Asymptotic properties of the Fourier coefficients
D. Partial differential equation (PDE)
1d introduction and general clssification of PDEs
2d the unidirectional wave equation: examples and the genaral formula of the solution with the method of characteristics
4d. First order PDEs in normal form. Sketch of the general method of characteristics.
5d Traffic equation: the continuity equation, velocity field. Burgers equation
6d Wave equation: transversal vibrations of a wire
7d D'Alambert formula for the Cachy problem in the upper halfplane
7e wave equation: separation of variables for the CauchyDirichlet homogeneous problem
E. Examples and applitions
1e wave equation: examples
2e the fundamental equation of sismology: derivation and solutions
3e shallow water waves: the KdV equation and the Tsunami equation  Obiettivi Agenda 2030 per lo sviluppo sostenibile