In the field of mathematics: Linear algebra, differential calculus of functions of one and several variables, integral calculus of functions of one variable, solving of linear ordinary differential equations and their systems.

In the field of mechanics: Vectorial representation of forces and moments. Free body diagrams. Potential and kinetic energy.

Attendance at lectures and in seminars is obligatory and checked. Absence may be compensated for based on an agreement with the teacher.

Course-unit credit is awarded on the following conditions: Active participation at seminars, passing a wtritten test (at least half of possible points in the test).

Examination: The exam will be done orally, it tests the knowledge of definitions and theorems (especially the ability of their application to the given problems). Detailed information will be announced at the end of the semester.

Aim of the course: The aim of the course is to acquaint the students with the fundamentals of the qualitative theory of ordinary differential equation, dynamical systems, and analytical mechanics. The task is also to show a possible use of the theoretical results in analysis of ordinary differential equations appearing in mathematical models in mechanics.

Acquired knowledge and skills: Students will acquire the skills to apply theoretical mathematical apparatus in analysis of differential equations appearing in selected mathematical models in mechanics. In particular, they will be able to derive equations of motion of simpler mechanical systems and to determine stability and type of the equilibria of the obtained non-linear autonomous systems of ordinary differential equations. Students will also be familiarized with ordinary differential equations as mathematical models in mechanics and other disciplines.

• Programme N-MAI-A Master's, 2. year of study, winter semester, compulsory
  

Solving of selected types of non-linear first-order ODEs.
Stability of linear systems of ODEs with constant coefficients, Hurwitz criterion.
Implicit differential equations: Lagrange and Clairot equations.
Geometric problems leading to the closed-form solutions of ODEs.
Euler differential equation in stress-analysis of thick-walled cylindrical vessels and analysis of deformation of shells.
Kinematics and dynamics of motion of a point and systems of points.
Kinematics and dynamics of simple motions of rigid bodies.
Equation of catenary.
Planar non-linear autonomous systems of ODEs: Stability and classification of equilibria, phase portrait.
Autonomous non-linear second-order equations: Stability and classification of equilibria.