Code: | L.BIO002 | Acronym: | MATI |
Keywords | |
---|---|
Classification | Keyword |
OFICIAL | Basic Sciences (Mathematics, Physics, Chemistry, Biology) |
Active? | Yes |
Responsible unit: | Department of Civil and Georesources Engineering |
Course/CS Responsible: | Bachelor in Bioengineering |
Acronym | No. of Students | Study Plan | Curricular Years | Credits UCN | Credits ECTS | Contact hours | Total Time |
---|---|---|---|---|---|---|---|
L.BIO | 112 | Syllabus | 1 | - | 6 | 52 | 162 |
This course unit aims to provide students with theoretical and practical knowledge in Linear Algebra and Analytical Geometry, as well as Differential and Integral Calculus of a real functions of a real variable.
LEARNING OUTCOMES
Students should be capable of:
1- analyse linear dependence and independence of a group of vectors in R2 and R3.
2- determine the dimension and bases of R2 and R3 subspaces
3- carry out matrix operations.
4- calculate determinants of any order and be capable of using their main properties.
5- classify systems of linear equations regarding the type of solution and resolution of systems by using Gaussian elimination method.
6- determine eigenvalues and eigenvectors, as well as their eigensubspaces.
7- calculate the orthogonal projection, internal and external product between 2 vectors.
8- obtain inverse trigonometric functions, as well as their derivatives.
9- calculate primitives by substitution and parts method.
10- calculate primitives of rational fractions.
11- calculate defined Riemann integrals using fundamental theorems.
12- obtain the areas of plane regions using defined integrals.
A - Topics of Linear Algebra and Analytical Geometry
I- Vector spaces: definition; Rn case; vector subspaces; linear dependence and independence; basis and dimension
II- Matrices: definition, dimension and operations; the special case of square matrices: triangular matrices, symmetric matrices and matrix transposition; inverse matrix and its properties; orthogonal matrices; power of a matrix; matrix rank; matrices condensation method.
III- Determinants: definition and properties; determinants calculation- Laplace theorem; application of determinants to the calculation of the inverse matrix and the matrix rank.
IV- Systems of linear equations: homogeneous and non-homogeneous systems; vector space of solutions; matrix form of systems; discussion and resolution of systems- Gauss-Jordan method; Cramer rules.
V- Eigenvalues and eigenvectors: definition; characteristic polynomial and determination of eigenvalues of a matrix; eigensubspaces associated to an eigenvalue.
VI- Analytical geometry: vector norm; orthogonal projection of a vector onto another; scalar or internal product; vector or external product and mixed product in R3.
B - Differential and Integral Calculus of real functions of a real variable
I- Revision of some real functions of real variable: exponential and logarithmic function; its properties and graphs. Brief revision of the concepts of limits and continuity and its application to some functions; some indeterminate forms; trigonometric functions and their inverse; hyperbolic function.
II- Derivation: definition and interpretation of the derivative; rules of derivation of composed and inverse functions; problems of application to the growth of function and determination of maximum and minimum; examples of exponential growth and logistic curve; l’Hôpital’s rule; notion of differential.
III- Primitives: definition of primitive or antiderivative; simple examples and elementary rules; methods of substitution and parts; decomposition and primitives of rational fractions.
IV- Riemann integral on an interval [a,b]:definition by Riemann sums; basic properties; fundamental theorem of calculus; application of integral to the calculation of areas; mean value and mean value theorem.
Theoretical classes will be based on the presentation of the theoretical concepts and examples.
In the practical classes, the students will be solved by students proposed exercices under professor supervision.
The theoretical presentation of the program will be supported by slides.
Students will get notes to both the theoretical program and exercises.
Designation | Weight (%) |
---|---|
Participação presencial | 0,00 |
Teste | 100,00 |
Total: | 100,00 |
Designation | Time (hours) |
---|---|
Estudo autónomo | 106,00 |
Frequência das aulas | 56,00 |
Total: | 162,00 |
To be admitted to exams, students cannot miss more than 25% of classes (according to the General Evaluation Rules of FEUP).
Final Grade will be based on the following components:
- 1st Mini Test (MT1) – performed in person, date will be later announced;
- 2nd Mini Test (MT2) - performed in person, date will be later announced, and that will only include topic taught after MT1;
- Appeal Exam- ER- Only for students who did not complete the course or want to improve their grades.
Final Grade will be based on the following formula:
CF=0,5xMT1+0,5xMT2
or
CF=ER
Students will be asked to do some individual written exercises as homework. By doing this, they will show their interest and dedication regarding this course unit. During classes students may be asked to answer some questions about concepts or methods already explained. This will also show students’ interest and dedication regarding this course unit.
According to General Evaluation Rules of FEUP
Appeal exam.