Course detail
Mathematics II-B
FSI-BM Acad. year: 2025/2026 Summer semester
The course takes the form of lectures and seminars dealing with the following topics:
Real functions of two and more variables, Partial derivatives – total differentials, Applications of partial derivatives – maxima, minima and saddle points, Lagrange multipliers, Taylor's approximation and error estimates, Double integrals, Triple integrals, Applications of multiple integrals, Methods of solving ordinary differential equations
A significant part of the course is devoted to applications of the studied topics. The acquired knowledge is a prerequisite for understanding the theoretical foundations in the study of other specialized subjects.
Language of instruction
Czech
Number of ECTS credits
7
Supervisor
Department
Entry knowledge
Differential and integral calculus of functions in one variable.
Rules for evaluation and completion of the course
COURSE-UNIT CREDIT REQUIREMENTS:
There are two written tests. Condition for the course-unit credit: to obtain at least 50% points from each written test. Students, who do not fulfill conditions for the course-unit credit, can repeat the written test during the first two weeks of examination time.
FORM OF EXAMINATIONS:
The exam has an obligatory written and oral part. The student can obtain 85 points from the written part and 15 points from the oral part (the examiner can take into account the results of the seminar).
EXAMINATION:
- The written part ranges from 90 to 120 minutes according to the difficulty of the test.
- The written part will contain at least one question (example) from each of the following topics:
1. Differential calculus of functions of several variables.
2. Multiple integrals
3. Ordinary differential equations
- The written part may also include theoretical questions from the above-mentioned themes.
- The oral part usually consists of theoretical questions and a discussion related to the written exam. For each example, the student must be able to justify his calculation procedure – otherwise, the test will not be recognized and will be evaluated for zero points. A supplementary simple example can be given, which the student calculates immediately.
FINAL CLASSIFICATION:
0-49 points: F
50-59 points: E
60-69 points: D
70-79 points: C
80-89 points: B
90-100 points: A
Attendance at lectures is recommended, attendance at seminars is required. The lessons are planned on the basis of a weekly schedule. Missed seminars may be made up of the agreement with the teacher supervising the seminar.
Aims
The course aim is to acquaint the students with the theoretical basics of the above mentioned mathematical disciplines necessary for further study of engineering courses and for solving engineering problems encountered. Another goal of the course is to develop the students' logical thinking.
Students will acquire basic knowledge of mathematical disciplines listed in the course annotation and will be made familiar with their logical structure. They will learn how to solve mathematical problems encountered when dealing with engineering tasks using the knowledge and skills acquired. Moreover, they improve their skills in mathematical software, which can be used to solving problems.
The study programmes with the given course
Programme B-PRP-P: Professional Pilot, Bachelor's, compulsory
Programme B-ENE-P: Energy, Bachelor's, compulsory
Programme B-PDS-P: Industrial Design, Bachelor's, compulsory
Programme B-STR-P: Engineering, Bachelor's
specialization AIŘ: Applied Computer Science and Control, compulsory
Programme B-STR-P: Engineering, Bachelor's
specialization KSB: Quality, Reliability and Safety, compulsory
Programme B-STR-P: Engineering, Bachelor's
specialization SSZ: Machine and Equipment Construction, compulsory
Programme B-STR-P: Engineering, Bachelor's
specialization STG: Manufacturing Technology, compulsory
Type of course unit
Lecture
39 hours, optionally
Syllabus
1. Function in more variables, basic definitions, and properties. Limit of a function in more variables, continuous functions. Partial derivative.
2. A gradient of a function, derivative in a direction. First-order and higher-order differentials, tangent plane to the graph of a function in two variables.
3. Taylor polynomial and Taylor's theorem. Local extremes.
4. Method of Lagrange multipliers, absolute extremes.
5. Function defined implicitly. Definite integral more variables, definition, basic properties.
6. Fubini's theorem, calculation on elementary (normal) areas.
7. Transformation of the integrals (polar and cylindrical coordinates)
8. Transformation of the integrals (spherical coordinates). Applications of double and triple integrals.
9. Ordinary differential equations (ODE), basic terms, existence, and uniqueness of solutions, analytical methods of solving of 1st order ODE.
10. Higher-order ODEs, properties of solutions, and methods of solving higher-order linear ODEs. Systems of 1st order ODEs.
11. Properties of solutions and methods of solving linear systems of 1st-order ODEs.
12. Applications of ODEs.
13. Boundary value problem for 2nd order ODEs.
Exercise
33 hours, compulsory
Syllabus
The first week: calculating improper integrals, applications of the Riemann integral. Following weeks: seminars related to the lectures given in the previous week.
Computer-assisted exercise
6 hours, compulsory
Syllabus
Seminars in a computer lab have suitable mathematical software as computer support. Obligatory topics correspond to the course syllabus.