CALCULUS 2
cod. 1001162

Academic year 2013/14
2° year of course - First semester
Professor
Mario TOSQUES
Academic discipline
Analisi matematica (MAT/05)
Field
Matematica, informatica e statistica
Type of training activity
Basic
42 hours
of face-to-face activities
6 credits
hub:
course unit
in - - -

Learning objectives

Knowledge and understanding:
At the end of the course the student will acquire the ability to understand the concept of limit and continuity for functions of several variables, basic knowledge of differential and integral calculus of several variables, and the theory of resolution of linear ordinary differential equations of order n with constant and continuous coefficients.

Applying knowledge and understanding:
With the acquired skills, the student will be able to calculate the maximum and minimum points of a smooth function of several variables on an n-dimensional closed and bounded set with smooth boundary, to calculate the volume of an n-dimensional bounded set with smooth boundary, to determine the solution of a Cauchy problem for a linear differential equation of order n with continuous coefficients.

Prerequisites

It is required to have passed the examination of Mathematical Analysis 1 and Geometry .

Course unit content

1-Topology on the Euclidean n-dimensional real space.
2-Limit and continuity of vector valued functions of vector variable.
3-Differential calculus for vector valued functions of vector variable.
4-Riemann integral for functions of vector variable.
5-Linear ordinary differential equations with continuous coefficients.

Full programme

1-Topology on the Euclidean n-dimensional real space.
1.1 Euclidean scalar product and its properties.
1.2 Euclidean norm, its properties and Schwarz inequality.
1.3 Euclidean distance, its properties and fundamental system of neighborhoods of a point.
1.4 Definition of the interior point of the inner part of a set, of open set and properties of open sets.
1.5 Definition of closed set and properties of closed sets.
1.6 Definition of accumulation point, isolated point, the closure of a set, of boundary point and boundary of a set.

2-Limit and continuity of vector valued functions of vector variable.
2.1 Definition of limit of a sequence of vectors, of limit of a vector valued function of vector variable, uniqueness of the limit, and property of limits.
2.2 Definition of continuity for a vector valued function of vector variable and properties of continuous functions.
2.3 Compact sets, their characterization and Weierstrass theorem.

3-Differential calculus for vector valued functions of vector variable.
3.1 Partial derivatives and directional derivatives.
3.2 Differentiability of real valued functions of vector variable.
3.3 Theorem of the total differential.
3.4 Differentiability of vector valued functions of vector variable.
3.5 Differentiability of composed functions.
3.6 Partial derivatives of higher order and Schwarz theorem.
3.7 Taylor's formula stopped at the second order.
3.8 Stationary points and necessary condition for a point to be a relative minimum or maximum interior point.
3.9 The Hessian matrix and sufficient condition for a point to be minimum (maximum) internal relative.
3.10 Constrained stationary points.

4-Riemann integral for functions of vector variable.
4.1 Definition of Riemann integrable for function defined on a bounded regular n-dimensional set and properties of the integral.
4.2 Theorem of reduction of multiple integrals.
4.3 Theorem of the change of variables in multiple integrals.

5-Linear ordinary differential equations with continuous coefficients.
5.1 Theorem of characterization of the solutions of ordinary differential linear equations with continuous coefficients of order n.
5.2 Theorem of existence and uniqueness of the solution of the Cauchy problem.
5.3 Method for finding n linearly independent solutions of the homogeneous equation with constant coefficients.
5.4 Method for finding a particular solution of the non homogeneous equation.

Bibliography

Any book of Elements of Mathematical Analysis 2.

Teaching methods

Teaching will consist of lectures conducted by the teacher on the blackboard and in exercises designed to illustrate and apply the theory performed earlier.

Assessment methods and criteria

No test is expected during the course.
There will be a final written exam with answers free, lasting three hours and divided into three or four computational and theoretical questions. The student may accept the evaluation of the written exam, if it is sufficient or possibly improve it with an oral exam.

Other information

It is strongly recommended to attend the lessons.

2030 agenda goals for sustainable development

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Contacts

Toll-free number

800 904 084

Student registry office

E. segreteria.ingarc@unipr.it 

Quality assurance office

Quality Assurance Manager:
Jasmine Salame Younis
T. +39 0521 906045
E. office dia.didattica@unipr.it
E. manager jasmine.salameyounis@unipr.it

Course President

Prof. Andrea Zanini
E. andrea.zanini@unipr.it

Faculty advisor

Prof. Luca Chiapponi
E. luca.chiapponi@unipr.it

Prof.ssa Alice Sirico
E. alice.sirico@unipr.it

Carrier guidance delegate

Prof. Andrea Segalini
E. andrea.segalini@unipr.it

Tutor Professors

Prof. Andrea Maranzoni
E. andrea.maranzoni@unipr.it

Erasmus delegates

Prof.ssa Patrizia Bernardi
E. patrizia.bernardi@unipr.it
Prof.ssa Elena Romeo
E. elena.romeo@unipr.it

Quality assurance manager

Prof. Andrea Segalini
E. andrea.segalini@unipr.it

Tutor students

Matteo Pianforini
E. matteo.pianforini@studenti.unipr.it