GEOMETRY AND COMBINATORICS
(objectives)
The course aims to provide an introduction to those aspects of linear and discrete mathematics needed in science and engineering.
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Code
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20810098 |
Language
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ITA |
Type of certificate
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Profit certificate
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Module: GEOMETRY AND COMBINATORICS
(objectives)
The course aims to provide an introduction to those aspects of linear and discrete mathematics needed in science and engineering.
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Code
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20810098-1 |
Language
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ITA |
Type of certificate
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Profit certificate
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Credits
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6
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Scientific Disciplinary Sector Code
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MAT/03
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Contact Hours
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54
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Type of Activity
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Basic compulsory activities
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Group: CANALE 1
Teacher
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MEROLA FRANCESCA
(syllabus)
Elements of set theory. Maps between sets: invective, surjective, bijective maps. Elements of propositional logic, truth tables. Equivalence and order relations. Combinatorics. Binomial coefficients and binomial theorem. Permutations. The Integers: divisibility, GCD and Euclidean algorithm, Bézout identity, linear congruences. Baiscs of algebraic structures: permutation groups, abstract groups, polynomials and finite fields. Elements of graph theory.Lattices and Boolean algebras
(reference books)
Giulia Maria Piacentini Cattaneo Matematica discreta e applicazioni Zanichelli 2008
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Dates of beginning and end of teaching activities
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From 28/09/2020 to 22/01/2021 |
Delivery mode
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Traditional
At a distance
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Attendance
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not mandatory
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Evaluation methods
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Written test
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Group: CANALE 2
Teacher
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SAMA' MARCELLA
(syllabus)
1. Elements of Set Theory. Union, intersection, Cartesian product, set subtraction, complementary set, cardinality.
2. Set functions. Domain, codomain, Range. Injective, surjective, bijective functions. Inverse function, Identity, Permutations.
3. Elements of logic. Propositional calculus, Operations between propositions.
4. Relations. Reflexive, symmetric, antisymmetric, transitive. Order and equivalence relations. Examples.
5. Partially ordered sets. Equivalence relations and classes. Quotient set.
6. Integer numbers. Division and its properties. Greatest common divisor.
7. Euclidean algorithm. Introduction and application.
8. Prime numbers. Fundamental theorem of arithmetic.
9. Congruence mod n. Basic modular arithmetic. Sum and multiplication in Zn. Linear congruence. Description of linear congruence solutions. Euler's totient function. Small Fermat Theorem, Euler’s Theorem
10. Combinatory algebra. Dispositions and combinations with and without repetitions, binomial coefficient. Properties. Tartaglia's triangle.
11. Partially ordered sets Hasse Diagram. Maximum and minimum, Sup and inf.
12. Reticular formations. Properties of inf e sup.
13. Boolean algebra. Introduction. The Boolean operators AND, OR and NOT.
(reference books)
Giulia Maria Piacentini Cattaneo "Matematica discreta" Edito da Zanichelli.
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Dates of beginning and end of teaching activities
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From 28/09/2020 to 22/01/2021 |
Delivery mode
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Traditional
|
Attendance
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not mandatory
|
Evaluation methods
|
Written test
|
|
|
Module: GEOMETRY AND COMBINATORICS
(objectives)
The course aims to provide an introduction to those aspects of linear and discrete mathematics needed in science and engineering.
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Code
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20810098-2 |
Language
|
ITA |
Type of certificate
|
Profit certificate
|
Credits
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6
|
Scientific Disciplinary Sector Code
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MAT/09
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Contact Hours
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54
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Type of Activity
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Basic compulsory activities
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Group: CANALE 1
Teacher
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D'ARIANO ANDREA
(syllabus)
1. Linear equations and numbers Linear equations systems. Matrix associated with a linear system. Equivalent systems. Natural, integer, rational numbers, real numbers and their property. Recall of set theory: inclusion of sets, difference between sets. 2. Matrices and sets Matrices with real coefficients. Square, triangular, diagonal matrices. Transpose of a matrix and symmetric matrices. Recall of set theory: union and intersection of sets. 3. The vector space of the matrices Addition between matrices and its properties. Multiplying a scalar for a matrix and its properties. 4. Product between matrices Product between matrices with compatible dimensions. Properties of the product: associative property and distributive property. Examples showing that product between matrices does not satisfy the commutative property and the simplification property. Matrices and linear systems. 5. Determinants Definition by induction of the determinant when using the first-row development. Determinant property: development according to any row or column, determinant of the transposed matrix, determinant of a triangular matrix. Binet theorem. 6. Reverse matrix Unit matrix. Reverse matrix. Inverse property. Cramer's theorem. 7. Rank of a matrix Definition. Property of the rank. Minors of a matrix. Theorem of Kronecker. 8. Linear equation systems Definitions. Rouché-Capelli theorem. Rouché-Capelli method for solving a linear system. 9. Gauss method 10. Applications of Gauss method Basic operations. Calculation of the determinant. Calculation of the rank. 11. Geometric vectors Plan vectors. Addition between vectors. Product of a vector for a scalar. Space vectors. Lines and planes for the origin. Average point. 12. Linear combinations of geometric vectors Linear combinations. Linearly dependent and independent vectors. Characterization of linearly independent vectors in V2(O) and V3(O). 13. Vector spaces on the real numbers Definition of vector spaces. Examples of vector spaces. Basic properties of vector spaces. 14. Vector subspaces Definition of vector spaces. Subspaces of V2(O) and V3(O). 15. Generators of vector spaces Linear combinations and generators. 16. Linear dependency and independency 17. Basis of vector spaces Basis. Dimension. Dimension of the set of solutions of a homogeneous system. Dimension of subspaces. Calculation of dimensions and basis. 18. Intersection and sum of subspaces Intersection of vector subspaces. Sum of vector subspaces. Grassmann's formula. 19. Affine subspaces The lines of the plane and of the space. Space planes. Affine subspaces. Set of system solutions. 20. Homomorphisms Homomorphisms between vector spaces. Matrix associated with a homomorphism. Homomorphism associated with a matrix. 21. Image Property of the image of a homomorphism. Calculation of the image of a homomorphism. Condition of surjectivity of a homomorphism. 22. Kernel Property of the kernel of a homomorphism. Calculation of the kernel of a homomorphism. Injectivity condition of a homomorphism. 23. Endomorphisms Matrix associated with an endomorphism. Change of basis. 24. Eigenvalues and eigenvectors Definitions and basic properties. Eigenspaces. Characteristic polynomial. Diagonalizable matrices. 25. Diagonalization Diagonalizability conditions. Diagonalization procedure.
(reference books)
G. Accascina and V. Monti, Geometry* * This book is available for free at the following link: http://www.dmmm.uniroma1.it/accascinamonti/geogest/Geometria.pdf
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Dates of beginning and end of teaching activities
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From 28/09/2020 to 22/01/2021 |
Delivery mode
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Traditional
At a distance
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Attendance
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not mandatory
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Evaluation methods
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Written test
Oral exam
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Group: CANALE 2
Teacher
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SAMA' MARCELLA
(syllabus)
1. Linear equations and numbers Systems of linear equations. Represent linear systems with matrix equations. Equivalent systems. Natural, integers, rational, real numbers and their properties. Pills of Graph Theory: subsets and set subtraction.
2. Matrixes and sets Matrix with real coefficients. Square, triangular, diagonal matrixes. Transposed and symmetric matrix. Pills of Graph Theory: union and intersection.
3. Vector spaces and matrices Matrix addition and scalar product and their properties.
4. Matrix product Matrix product and its mathematical properties: associative and distributive. Example of how matrix product does not satisfy the commutative and simplification properties. Matrices and linear systems
5. Determinants Formal definition of determinant and its properties. Transposed and triangular matrix determinants. Binet’s theorem.
6. Inverse of a matrix Identity matrix. Inverse of a matrix and its properties. Cramer’s theorem.
7. Matrix rank Definition and properties. Minor of a matrix.
8. System of linear equations. Definition. Rouché-Capelli’s theorem. Rouché-Capelli’s method to solve a linear system.
9. Gaussian elimination and how to apply the Gaussian elimination Elementary operation. Determinant and rank computations.
10. Geometric vectors Vectors in 2 dimensions. Sum and scalar product of vectors. Vectors in 3 dimensions. Linear combination. Linear dependence and independence of vectors.
11. Vector spaces and Linear subspaces Definition, examples and properties.
12. How to generate linear subspaces Linear combination and generators.
13. Linear dependence and independence
14. Basis of a linear subspace Basis. Dimensions. Solution set of an homogeneous system and its dimensions.
15. Vector subspaces sum and intersection Grassmann formula.
16. Affine space Lines in planes and space. Affine subspace.
17. Homomorphisms Homomorphism between vector spaces. Represent an homomorphism as a matrix.
18. Image of a matrix Properties of an homomorphism image and how to compute it. Surjective homomorphism.
19. Kernel of a matrix Properties of an homomorphism kernel and how to compute it. Injectivity homomorphism.
20. Endomorphisms Matrix representation of the endomorphisms. Change of basis.
21. Eigenvalues and Eigenvectors Definition and properties. Eigenspaces. Characteristic polynomial. Diagonalizable matrix.
22. Diagonalizing a matrix Rules and examples.
(reference books)
G. Accascina e V. Monti, "Geometria"
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Dates of beginning and end of teaching activities
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From 28/09/2020 to 22/01/2021 |
Delivery mode
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Traditional
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Attendance
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not mandatory
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Evaluation methods
|
Written test
Oral exam
|
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