Course code Fizi2005

Credit points 4.50

Total Hours in Course120

Number of hours for lectures24

Number of hours for seminars and practical classes16

Number of hours for laboratory classes16

Independent study hours64

Date of course confirmation22.03.2021

Responsible UnitInstitute of Mathematics and Physics

Dr. phys.

Dr. habil. sc. ing.

Fizi2004, Physics I

Fizi2015 [GFIZ2016] Physics II

FiziB010 [GFIZB010] Physics II

Physics course is giving an overview of fundamental laws that are essential to problem solving in engineering sciences. Course consists of lectures, manual training, laboratory and individual exercises. During the lectures students are introduced to theory and ways of describing physical laws. Manual training includes practicing and understanding written exercises and calculating precise results. During laboratory workshops students’ deal with hands-on exercises where they measure, process and analyse various data readings, as well as they learn to plot graphs.

After completing the course students will have:

1. knowledge about regularity of essential concepts of physics and critical understanding of how to use it in real-world process description. – The knowledge is assessed in laboratory works and tests.

2. skills to use measurements of physical quantities and apply knowledge in calculation for their branch of research, summarize and analytically describe the results. – The skills are assessed in laboratory works.

3. competence to evaluate results of measurements and calculations, problem solving and understand what influence their professional activities have on environment. – The competence is assessed in laboratory works and tests.

1. Magnetic field, sources of magnetic field. – 4h

2. Magnetic flux, Gauss’s law for magnetism. – 3h

3. Lorentz force. Ampere’s force law. – 2h

4. Magnetism in matter. – 3h

5. Maxwell’s equations. – 3h

6. 1st test: Magnetic fields. – 3h

7. Mehcanical oscillations (harmonic, damped, driven). Resonance. – 4h

8. Adding of oscillations. Waves, interference of waves. – 3h

9. Electromagnetic oscillations. – 4h

10. Electromagnetic waves. – 3h

11. 2nd test: Oscillations and waves. – 3h

12. Wave optics (interference, diffraction). -4h

13. Polarization. – 3h

14. Quantum nature of radiation. Thermal radiation. – 4h

15. Fundamentals of quantum mechanics and atomic physics.. – 4h

16. Radioactivity. – 3h

17. 3rd test: Wave optics, atomic physics and radioactivity. – 3h

The requirement is – passing the written exam.

The examination shall contain two parts:

1. Theoretical questions;

2. Practical exercises about the topics covered.

In order to be allowed to take the exam, all tests must be written and the laboratory works must be performed and defended, and total 50% of the maximum possible points must be obtained (including - at least 50% of maximum possible points in theoretical tests).

1) The student studies the literature in preparation for tests;

2) The student makes all the necessary calculations for laboratory works and prepares for their defense.

Knowledge control:

1/Theory tests – 3;

2/Practical exercise tests – 3;

3/Laboratory works (work and defence) – 8.

The evaluation of the theory tests is in the range from 0 to 15 points, thus the maximum possible number of points in the theory part is 45 points.

The evaluation of each problem solving test is in the range from 0 to 10 points, the total maximum number of points in problem solving tests is 30 points.

The evaluation of each laboratory work is in the range from 0 to 10 points, the total number of points for this part is calculated by multiplying the average points by 3, so the maximum number of points in laboratory work part is 30 points.

The maximum number of points in the study course is 105 points.

1. Valtera A. red. Fizika. Rīga: Zvaigzne, 1992. 733 lpp.

2. Fizika visiem. http://estudijas.llu.lv

1. Jansone M., Kalnača A. u.c. Uzdevumu krājums vispārīgajā fizikā. Rīga: RTU, 2000. 247 lpp.

2. Tipler P. A., Mosca G. Physics for Scientists and Engineers 6th edition. New York, NY: W. H. Freeman, 2008. 1172 p.

1. Terra. Rīga: Latvijas Universitāte ISSN 977-1407-7191