Course detail

# Physics I

FSI-2FAcad. year: 2019/2020

Fundamental laws and theories of classical amd modern physics that are the basis of engineering disciplines.

Classical mechanics. Particle motion (velocity, acceleration). Dynamics of a particle, Newton's laws. Work and energy, conservative and non-conservative forces, potential. Dynamics of a system of particles and rigid body, dynamics of a rotating body. Gravitational field. Oscillations and waves, harmonic oscillator, traveling and standing wave, wave equation, interference of waves. Geometric and wave optics, imaging, diffraction and interference of light. Thermodynamics, heat, the kinetic theory of gases, entropy, engines.

Supervisor

Department

Learning outcomes of the course unit

Knowledge of the fundaments of classical and modern physics on the university level in the field of classical mechanics, oscillations and waves, gravitational field, optics and thermodynamics. Comprehension of general physical principles and capability to apply them to specific physical systems. Ability to carry out physical calculations by means of application of vector, differential and integral calculus.

Prerequisites

Secondary school knowledge of mathematics and physics. Fundamentals of vector, differential and integral calculus.

Co-requisites

Not applicable.

Recommended optional programme components

Not applicable.

Recommended or required reading

HALLIDAY, D. - RESNICK, R. - Walker, J.: Fyzika, 2. vydání, VUTIUM, Brno 2013

ŠANTAVÝ, I. - PEŠKA, L.: Fyzika I., skriptum VUT Brno, 1984

http://physics.fme.vutbr.cz

KUPSKÁ, I. - MACUR, M. - RYNDOVÁ, A.: Fyzika -Sbírka příkladů, skriptum VUT Brno,

ŠANTAVÝ, I a kol.: Vybrané kapitoly z fyziky, skriptum VUT, Brno 1986

HORÁK, Z. - KRUPKA, F.: Fyzika, SNTL, Praha 1976

KREMPASKÝ, J.: Fyzika, Alfa, Bratislava - SNTL, Praha 1982

ALONSO, M. - FINN, E. J.: Physics, Addison - Wesley, Reading 1996

FEYNMAN, R.P.-LEIGHTON, R.B.-SANDS, M.: Feynmanovy přednášky z fyziky, Fragment, 2001

ČSN ISO 1000 Veličiny a jednotky

Planned learning activities and teaching methods

The course is taught through lectures explaining the basic principles and theory of the discipline. Exercises are focused on practical topics presented in lectures. Teaching is suplemented by practical laboratory work.

Assesment methods and criteria linked to learning outcomes

Final classification reflects the result of continuous check in the form of tests in the seminars. The final examination consists of the obligatory written test and facultative oral part.

Details on the server physics.fme.vutbr.cz

Language of instruction

Czech

Work placements

Not applicable.

Aims

The goal of the course is to inform students about the fundamental laws and theories of classical and modern physics and to train them to apply this knowledge to simple physical systems, to explain and predict the behaviour of such systems. Further goal is to expose physics to students as the theoretical basis and fundament of engineering disciplines.

Specification of controlled education, way of implementation and compensation for absences

Attendance at seminars and labs which are stated in the timetable is checked by the teacher. Absence may be compensated for by the agreement with the teacher.

Classification of course in study plans

- Programme B3A-P Bachelor's
branch B-MET , 1. year of study, summer semester, 7 credits, compulsory

- Programme B3S-P Bachelor's
branch B-STI , 1. year of study, summer semester, 7 credits, compulsory-optional

branch B-KSB , 1. year of study, summer semester, 7 credits, compulsory - Programme B-MAI-P Bachelor's, 1. year of study, summer semester, 7 credits, compulsory

#### Type of course unit

Lecture

39 hours, optionally

Teacher / Lecturer

Syllabus

Measurement. The international system of units, changing units. Motion along a straight line. Graphical integration in motion analysis. Vectors, adding vectors, multiplying vectors.

Motion in two and three dimensions, velocity and acceleration, uniform circular motion. Relative motions.

Force and motion. Newtonian mechanics. Inertial reference frames. Newton’s first, second and third laws. Some particular forces. Applying Newton’s laws.

Work and kinetic energy. Work-kinetic energy theorem. Work done by gravitational force. Work done by spring force. Work done by general variable force. Power.

Potential energy and conservation of energy. Conservative and nonconservative forces. Determining gravitational and elastic potential energy values. Work done by external and nonconservative forces.

System of particles. Center of mass. Momentum. Newton’s second law for a system of particles. Collisions.

Rotation and rolling. The rotational variables. Rotational inertia. Torque. Angular momentum. Newton’s second law in angular form. Conservation of angular momentum.

Equilibrium and elasticity. The center of gravity. Tension and compression, shearing, hydraulic stress.

Gravitation. Newton’s law of gravitation. Principe of superposition. Gravitational potential energy. Planets and satellites, Kepler’s laws.

Fluids. Pressure. Pascal’s principle. Archimedes’ principle. The equation of continuity. Bernoulli’s equation.

Oscillations. Simple harmonic motion, the force law, energy. An angular simple harmonic oscillator. Pendulums. Damped simple harmonic motion. Forced oscillations and resonance.

Waves. Type of waves. Transverse and longitudinal waves. Traveling sinusoidal wave. The wave equation. The principle of superposition for waves. Interference of waves. Standing waves and resonance. Sound waves. Beats. The Doppler effect.

Thermodynamics. The zeroth law of thermodynamics and temperature. Work and heat. The internal energy and the first law of thermodynamics, applications. Ideal gas law, molar heats. The second law of thermodynamics and entropy. Reversible and irreversible processes. Heat engines, refrigerators and heat pumps. Carnot engine efficiency.

Laboratory exercise

13 hours, compulsory

Teacher / Lecturer

Ing. Petr Bouchal, Ph.D.

RNDr. Libuše Dittrichová, Ph.D.

Ing. Tomáš Krajňák

Ing. Jindřich Mach, Ph.D.

Ing. Tadeáš Maňka

Ing. Tomáš Musálek

Ing. Josef Polčák, Ph.D.

doc. Ing. Pavel Pořízka, Ph.D.

Ing. Michal Potoček, Ph.D.

Ing. David Prokop

Ing. Petr Řehák, Ph.D.

Ing. Miroslav Stibůrek

Ing. Tomáš Strapko

Ing. Štěpán Šustek

Ing. Tomáš Zikmund, Ph.D.

Syllabus

Efficiency of a heat engine: Stirling engine.

Numerical solution of equation of motion: Torque oscillations.

Physical modelling: Waves in tubes.

Numerical and graphical solution: Heat transfer.

Exercise

26 hours, compulsory

Teacher / Lecturer

doc. Ing. Miroslav Bartošík, Ph.D.

doc. Ing. Jan Čechal, Ph.D.

Ing. Miroslav Ďuriš

Ing. Michal Horák, Ph.D.

Ing. Martin Hrtoň

Ing. Petr Jákl, Ph.D.

Mgr. Věra Kollárová, Ph.D.

Mgr. Vlastimil Křápek, Ph.D.

Ing. Michal Kvapil, Ph.D.

Ing. Filip Ligmajer, Ph.D.

Ing. David Nezval

Ing. Jan Novotný, Ph.D.

prof. RNDr. Jiří Petráček, Dr.

Ing. Karel Slámečka, Ph.D.

prof. RNDr. Jiří Spousta, Ph.D.

Mgr. Jitka Strouhalová

Ing. Igor Turčan

Ing. Jakub Vrábel

Syllabus

The following exercises and problems (Ú) are from the textbook [1];

1. Vectors

2. Particle motion

3. Force and motion

4. Work and energy

5. Systems of particles

6. Rotation and rolling

7. Gravitation

8. Oscillations

9. Waves

10. Thermodynamics

eLearning

**eLearning:** opened course