Mathematics for Biotechnology
A.Y. 2023/2024
Learning objectives
The course aims to provide the basic Mathematics knowledge for a scientific degree course: real field and its properties; differential and integral calculus for real functions of a single real variable; first order ordinary differential equations; elements of linear algebra.
Expected learning outcomes
At the end of the course the student will be able to recognize the main properties of a mathematical model described by a single function; to solve simple linear systems; to solve first order differential equations.
Lesson period: First semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course can be attended as a single course.
Course syllabus and organization
Linea AK
Responsible
Lesson period
First semester
Course syllabus
1. Preliminaries. Sets. Real numbers. Sets of real numbers. Upper bound and lower bound of sets of real numbers. Intervals. Distance. Functions of a real variable, graph, domain, image. Injectivity. Composition of functions. Operations on graphs: translations, symmetries. Inverse functions. Monotone functions. Maxima and minima. Sign and zeros of a function.
2. Elementary functions. Absolute values. Powers with natural exponent, integer, rational and real. Power functions and exponential functions. Logarithmic functions. Trigonometric functions. Algebraic inequalities (second degree, irrational, exponential, logarithmic). Systems of inequalities.
3. Limits and continuous functions. Distance and neighborhoods. Limits of functions. Continuity. Elementary limits. Algebra of limits. Limits of composite functions. Comparison theorems. Asymptotes: horizontal, vertical and oblique. Continuous functions and their basic properties. Theorem of zeros. Weierstrass Theorem.
4. Derivatives. Definition of derivative at a point. Tangent line to a graph. Derivatives of elementary functions. Rules of derivation of sums, products, quotients, composite finctions inverse functions. Differentiability and continuity. Relative maxima and minima. Fermat, Rolle and Lagrange theorems. Consequences of Lagrange's theorem: differentiable functions with zero derivative, differentiable functions with the same derivative, sign of the first derivative and monotonicity intervals of the function. Searching for maxima and minima by using the sign of derivatives. Second derivative, its sign and convexity. Qualitative study of the graph of a function. Higher order derivatives.
5. Integrals. Primitive functions (indefinite integrals). Elementary integrals. Definition of definite integrals. Areas. The fundamental theorem of calculus.
6. Linear algebra. Geometric vectors in R^n. Matrices with real coefficients and their properties. Linear systems in matricial form
Ax = b. Systems resolution with the Gauss method. Rank of a matrix. Determinant of square matrices. Kronecker theorem. Rouché-Capelli theorem. Inverse of a square matrix. Cramer theorem. The scalar product and its properties. Orthogonal vectors. Reference systems in E^2 and E^3. Elements of analytical geometry. Vector product in R^3.
7. Differential equations. Definitions of differential equation (in normal and non-normal form) and of order of a differential equation. Solution of a differential equation. Examples of differential equations. Cauchy's problem.
2. Elementary functions. Absolute values. Powers with natural exponent, integer, rational and real. Power functions and exponential functions. Logarithmic functions. Trigonometric functions. Algebraic inequalities (second degree, irrational, exponential, logarithmic). Systems of inequalities.
3. Limits and continuous functions. Distance and neighborhoods. Limits of functions. Continuity. Elementary limits. Algebra of limits. Limits of composite functions. Comparison theorems. Asymptotes: horizontal, vertical and oblique. Continuous functions and their basic properties. Theorem of zeros. Weierstrass Theorem.
4. Derivatives. Definition of derivative at a point. Tangent line to a graph. Derivatives of elementary functions. Rules of derivation of sums, products, quotients, composite finctions inverse functions. Differentiability and continuity. Relative maxima and minima. Fermat, Rolle and Lagrange theorems. Consequences of Lagrange's theorem: differentiable functions with zero derivative, differentiable functions with the same derivative, sign of the first derivative and monotonicity intervals of the function. Searching for maxima and minima by using the sign of derivatives. Second derivative, its sign and convexity. Qualitative study of the graph of a function. Higher order derivatives.
5. Integrals. Primitive functions (indefinite integrals). Elementary integrals. Definition of definite integrals. Areas. The fundamental theorem of calculus.
6. Linear algebra. Geometric vectors in R^n. Matrices with real coefficients and their properties. Linear systems in matricial form
Ax = b. Systems resolution with the Gauss method. Rank of a matrix. Determinant of square matrices. Kronecker theorem. Rouché-Capelli theorem. Inverse of a square matrix. Cramer theorem. The scalar product and its properties. Orthogonal vectors. Reference systems in E^2 and E^3. Elements of analytical geometry. Vector product in R^3.
7. Differential equations. Definitions of differential equation (in normal and non-normal form) and of order of a differential equation. Solution of a differential equation. Examples of differential equations. Cauchy's problem.
Prerequisites for admission
Knowledge of Mathematics is required at high school level.
Teaching methods
Lectures and exercises.
Delivery mode: Frontal lessons and exercises held by the lecturer.
Delivery mode: Frontal lessons and exercises held by the lecturer.
Teaching Resources
[0] Material from the Ariel site "Matematica Assistita" available on the Ariel platform.
[1] A. Guerraggio: Matematica per le Scienze, ed. Pearson, 2014.
Seconda edizione 2018, con contenuti digitali scaricabili dalla rete.
[2] D. Benedetto, M. Degli Esposti, C. Maffei: Matematica per le Scienze della vita, ed. Ambrosiana 2012.
[3] M. Abate: Matematica e Statistica, ed. McGraw Hill, 2013.
[4] C. Sbordone - F. Sbordone: Matematica per le Scienze della Vita, ed. EdiSES, 2014.
[5] S. Annaratone: Matematica sul campo ed. Pearson, 2017.
[6] P. Marcellini, C. Sbordone: Elementi di Calcolo, ed. Liguori, 2004.
[7] M. Bramanti, C.D. Pagani, S. Salsa: Matematica. Calcolo infinitesimale e algebra lineare, ed. Zanichelli, 2004.
[1] A. Guerraggio: Matematica per le Scienze, ed. Pearson, 2014.
Seconda edizione 2018, con contenuti digitali scaricabili dalla rete.
[2] D. Benedetto, M. Degli Esposti, C. Maffei: Matematica per le Scienze della vita, ed. Ambrosiana 2012.
[3] M. Abate: Matematica e Statistica, ed. McGraw Hill, 2013.
[4] C. Sbordone - F. Sbordone: Matematica per le Scienze della Vita, ed. EdiSES, 2014.
[5] S. Annaratone: Matematica sul campo ed. Pearson, 2017.
[6] P. Marcellini, C. Sbordone: Elementi di Calcolo, ed. Liguori, 2004.
[7] M. Bramanti, C.D. Pagani, S. Salsa: Matematica. Calcolo infinitesimale e algebra lineare, ed. Zanichelli, 2004.
Assessment methods and Criteria
The exam will be written and will focus on the entire program.
Further details on the exam modalities will be communicated during the lessons of the course.
Further details on the exam modalities will be communicated during the lessons of the course.
MAT/01 - MATHEMATICAL LOGIC
MAT/02 - ALGEBRA
MAT/03 - GEOMETRY
MAT/04 - MATHEMATICS EDUCATION AND HISTORY OF MATHEMATICS
MAT/05 - MATHEMATICAL ANALYSIS
MAT/06 - PROBABILITY AND STATISTICS
MAT/07 - MATHEMATICAL PHYSICS
MAT/08 - NUMERICAL ANALYSIS
MAT/09 - OPERATIONS RESEARCH
MAT/02 - ALGEBRA
MAT/03 - GEOMETRY
MAT/04 - MATHEMATICS EDUCATION AND HISTORY OF MATHEMATICS
MAT/05 - MATHEMATICAL ANALYSIS
MAT/06 - PROBABILITY AND STATISTICS
MAT/07 - MATHEMATICAL PHYSICS
MAT/08 - NUMERICAL ANALYSIS
MAT/09 - OPERATIONS RESEARCH
Practicals: 48 hours
Lessons: 24 hours
Lessons: 24 hours
Linea LZ
Responsible
Lesson period
First semester
Course syllabus
1. Preliminaries. Sets. Real numbers. Sets of real numbers. Upper bound and lower bound of sets of real numbers. Intervals. Distance. Functions of a real variable, graph, domain, image. Injectivity. Composition of functions. Operations on graphs: translations, symmetries. Inverse functions. Monotone functions. Maxima and minima. Sign and zeros of a function.
2. Elementary functions. Absolute values. Powers with natural exponent, integer, rational and real. Power functions and exponential functions. Logarithmic functions. Trigonometric functions. Algebraic inequalities (second degree, irrational, exponential, logarithmic). Systems of inequalities.
3. Limits and continuous functions. Distance and neighborhoods. Limits of functions. Continuity. Elementary limits. Algebra of limits. Limits of composite functions. Comparison theorems. Asymptotes: horizontal, vertical and oblique. Continuous functions and their basic properties. Theorem of zeros. Weierstrass Theorem.
4. Derivatives. Definition of derivative at a point. Tangent line to a graph. Derivatives of elementary functions. Rules of derivation of sums, products, quotients, composite finctions inverse functions. Differentiability and continuity. Relative maxima and minima. Fermat, Rolle and Lagrange theorems. Consequences of Lagrange's theorem: differentiable functions with zero derivative, differentiable functions with the same derivative, sign of the first derivative and monotonicity intervals of the function. Searching for maxima and minima by using the sign of derivatives. Second derivative, its sign and convexity. Qualitative study of the graph of a function. Higher order derivatives.
5. Integrals. Primitive functions (indefinite integrals). Elementary integrals. Definition of definite integrals. Areas. The fundamental theorem of calculus.
6. Linear algebra.
a) Vectors in R^n. Matrices with real coefficients and their properties. Linear systems in matricial form Ax = b. Systems resolution with the Gauss method.
b) Rank of a matrix. Rouché-Capelli theorem.
c) Invertibility of a square matrix. Determinant of square matrices. Cramer theorem.
d)The scalar product and its properties. Orthogonal vectors. Elements of analytical geometry. Vector product in R^3.
7. Differential equations. Definitions of differential equation (in normal and non-normal form) and of order of a differential equation. Solution of a differential equation. Examples of differential equations. Cauchy's problem.
Note: the lessons will be accompanied by numerous hours of exercises carried out by the teachers themselves.
2. Elementary functions. Absolute values. Powers with natural exponent, integer, rational and real. Power functions and exponential functions. Logarithmic functions. Trigonometric functions. Algebraic inequalities (second degree, irrational, exponential, logarithmic). Systems of inequalities.
3. Limits and continuous functions. Distance and neighborhoods. Limits of functions. Continuity. Elementary limits. Algebra of limits. Limits of composite functions. Comparison theorems. Asymptotes: horizontal, vertical and oblique. Continuous functions and their basic properties. Theorem of zeros. Weierstrass Theorem.
4. Derivatives. Definition of derivative at a point. Tangent line to a graph. Derivatives of elementary functions. Rules of derivation of sums, products, quotients, composite finctions inverse functions. Differentiability and continuity. Relative maxima and minima. Fermat, Rolle and Lagrange theorems. Consequences of Lagrange's theorem: differentiable functions with zero derivative, differentiable functions with the same derivative, sign of the first derivative and monotonicity intervals of the function. Searching for maxima and minima by using the sign of derivatives. Second derivative, its sign and convexity. Qualitative study of the graph of a function. Higher order derivatives.
5. Integrals. Primitive functions (indefinite integrals). Elementary integrals. Definition of definite integrals. Areas. The fundamental theorem of calculus.
6. Linear algebra.
a) Vectors in R^n. Matrices with real coefficients and their properties. Linear systems in matricial form Ax = b. Systems resolution with the Gauss method.
b) Rank of a matrix. Rouché-Capelli theorem.
c) Invertibility of a square matrix. Determinant of square matrices. Cramer theorem.
d)The scalar product and its properties. Orthogonal vectors. Elements of analytical geometry. Vector product in R^3.
7. Differential equations. Definitions of differential equation (in normal and non-normal form) and of order of a differential equation. Solution of a differential equation. Examples of differential equations. Cauchy's problem.
Note: the lessons will be accompanied by numerous hours of exercises carried out by the teachers themselves.
Prerequisites for admission
Being a first year course, first semester, there are no specific prerequisites different from those required for access to the degree course.
Teaching methods
Traditional lessons, frontal, on blackboard.
Teaching Resources
Bibliography
[1] A. Guerraggio: Matematica per le Scienze, ed. Pearson, 2014.
Seconda edizione 2018, con contenuti digitali scaricabili dalla rete.
[2] D. Benedetto, M. Degli Esposti, C. Maffei: Matematica per le Scienze della vita, ed. Ambrosiana 2012.
[3] M. Abate: Matematica e Statistica, ed. McGraw Hill, 2013.
[4] C. Sbordone - F. Sbordone: Matematica per le Scienze della Vita, ed. EdiSES, 2014.
[5] S. Annaratone: Matematica sul campo ed. Pearson, 2017.
[6] P. Marcellini, C. Sbordone: Elementi di Calcolo, ed. Liguori, 2004.
[7] M. Bramanti, C.D. Pagani, S. Salsa: Matematica. Calcolo infinite-simale e algebra lineare, ed. Zanichelli, 2004.
[8] E. N. Bodine - S. Lenhart - L. J. Gross: Matematica per le scienze della vita,
ed. de Agostini 2017.
[9] D. Benedetto - M. Degli Esposti - C. Maffei: Dalle funzioni ai modelli, ed. Ambrosiana; I ed. 2014.
[10] A. M. Bigatti - L. Robbiano: Matematica di base ed. CEA (Casa Editrice Ambrosiana); II ed. 2021.
[11] V. Villani - G. Gentili: Matematica ed. McGraw Hill; VI ed. 2022 (+ eserciziario con 400 esercizi svolti).
It is useful to consult the teacher's web pages, available at:
http://ariel.unimi.it
[1] A. Guerraggio: Matematica per le Scienze, ed. Pearson, 2014.
Seconda edizione 2018, con contenuti digitali scaricabili dalla rete.
[2] D. Benedetto, M. Degli Esposti, C. Maffei: Matematica per le Scienze della vita, ed. Ambrosiana 2012.
[3] M. Abate: Matematica e Statistica, ed. McGraw Hill, 2013.
[4] C. Sbordone - F. Sbordone: Matematica per le Scienze della Vita, ed. EdiSES, 2014.
[5] S. Annaratone: Matematica sul campo ed. Pearson, 2017.
[6] P. Marcellini, C. Sbordone: Elementi di Calcolo, ed. Liguori, 2004.
[7] M. Bramanti, C.D. Pagani, S. Salsa: Matematica. Calcolo infinite-simale e algebra lineare, ed. Zanichelli, 2004.
[8] E. N. Bodine - S. Lenhart - L. J. Gross: Matematica per le scienze della vita,
ed. de Agostini 2017.
[9] D. Benedetto - M. Degli Esposti - C. Maffei: Dalle funzioni ai modelli, ed. Ambrosiana; I ed. 2014.
[10] A. M. Bigatti - L. Robbiano: Matematica di base ed. CEA (Casa Editrice Ambrosiana); II ed. 2021.
[11] V. Villani - G. Gentili: Matematica ed. McGraw Hill; VI ed. 2022 (+ eserciziario con 400 esercizi svolti).
It is useful to consult the teacher's web pages, available at:
http://ariel.unimi.it
Assessment methods and Criteria
The examination of the course is only written, the result is expressed in thirtieths. Candidates are offered some exercises to solve, usually 7, without the possibility of consulting notes, texts or electronic tools. Each exercise corresponds to a partial score, indicated in the text, which is obtained following a correct performance. After the first 6 weeks there is a written exemption test which, if passed, allows the candidate to be exempted from about half of the exam topic for the first 3 appeals. All the texts of the exam topics of the last years are available on the teacher's web pages, where there is also other information (detailed regulations, calendar, etc.)
MAT/01 - MATHEMATICAL LOGIC
MAT/02 - ALGEBRA
MAT/03 - GEOMETRY
MAT/04 - MATHEMATICS EDUCATION AND HISTORY OF MATHEMATICS
MAT/05 - MATHEMATICAL ANALYSIS
MAT/06 - PROBABILITY AND STATISTICS
MAT/07 - MATHEMATICAL PHYSICS
MAT/08 - NUMERICAL ANALYSIS
MAT/09 - OPERATIONS RESEARCH
MAT/02 - ALGEBRA
MAT/03 - GEOMETRY
MAT/04 - MATHEMATICS EDUCATION AND HISTORY OF MATHEMATICS
MAT/05 - MATHEMATICAL ANALYSIS
MAT/06 - PROBABILITY AND STATISTICS
MAT/07 - MATHEMATICAL PHYSICS
MAT/08 - NUMERICAL ANALYSIS
MAT/09 - OPERATIONS RESEARCH
Practicals: 48 hours
Lessons: 24 hours
Lessons: 24 hours
Professors:
Alzati Alberto, Colombo Elisabetta
Educational website(s)
Professor(s)
Reception:
Monday 14.00-16.00
Office n° 2103, II floor, c/o Dip. Mat., via Saldini 50
Reception:
friday.8.45-11.45
Office2101, second floor, via C. Saldini 50
Reception:
By appointment (to be agreed upon via email)
Room 2102, Dipartimento di Matematica "F. Enriques", Via Saldini 50