The student masters the essential knowledge and mathematical methods which are used in the study; reveals the widespread use of mathematical analysis and applies problems in physics research.

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Mathematical Analysis

The student masters the essential knowledge and mathematical methods which are used in the study; reveals the widespread use of mathematical analysis and applies problems in physics research.

Analytic geometry and linear algebra

The subject reveals profound idea of the subject and its widespread use in applied research, to develop the students' ability to use mathematical methods in special courses that prepare it as a professional on the deductive basis and forming the basic concepts, definitions, theorem proving.

4,5

Probability Theory and Mathematical Statistics

The subject gives the student an understanding of probabilistic patterns of behavior of different systems. The student has to acquire general mathematical apparatus of probability theory and Mathematical Statistics and to be able to practically apply it to the analysis and forecasting.

Basics of vector and tensor analysis

Teaches the students how to use mathematical apparatus that allows research to mathematically describe scalar and vector fields, which are the subject of study in next courses of physics and theoretical physics. In particular, the rate of "vector analysis" provides definitions of differential field characteristics such as grad U, div A, rot A and integral characteristics - flow and Circulation with which describes scalar potential, Laplace and solenoyidalni field. The task of the "Fundamentals of the tensor calculus" - to teach students basic algebraic operations with tensors and some of their properties and to develop in them an understanding of vector and tensor nature of various physical quantities.

Differential and Integral Equations

Gives to the student an understanding of probabilistic patterns of behavior of different systems. The student has to acquire general mathematical apparatus of probability theory and Mathematical Statistics and to be able to practically apply it to the analysis and forecasting. Student masters the techniques of differential and integral calculus.

Methods of Mathematical Physics

Teachs the students the basic methods of solving problems of mathematical physics - Fourier method, Green's functions, potential characteristics etc. and also special functions - cylindrical, spherical, orthogonal polynomials, gamma functions and initial information about the hypergeometric functions. Considers the notion of correct and incorrect objectives.

Programming and mathematical modeling

Gives necessary to work with computer technology basic knowledge. To achieve goals in Programming and mathematical modeling the students have several problems: to learn about the general forms of information presenting; learn programming environment Turbo Pascal 7.0; to learn basic numerical methods used for solving major physical problems, to learn about methods of experimental processing of data; gives skills in using a personal computer.

Mechanics

Representates the physical theory as a generalization of observations, experience and experiment; representation of physical theory as linkages between natural phenomena and kinematic variables that characterize them in mathematical form. "Mechanics" as a part of the general physics course has two aspects: - course should provide students with the basic methods of observation, measurement and experiment and accompanied by appropriate demonstrations and laboratory work in the physical practice; - Introduce a course in physical theory adequate small-form content to solve practical problems not only in physics but also in the amount of system natural and technical knowledge.

10,5

Molecular Physics

Study of the basic laws and peculiarities of molecular forms of movement; formation of students' perception of the relationship of an integrated system of physical properties of matter of their internal structure; teaches about the basic molecular physical phenomena, methods of observation and experimental research; with simple methods of processing and analysis of experimental results.

10,5

Electricity and Magnetism

Representation of physical theory as a generalization of observations, experience and experiment; representation of physical theory as linkages between electric and magnetic phenomena and values that characterize them in mathematical form. "Electricity and Magnetism" as part of the general physics course has two aspects: course should provide students with the basic methods of observation, measurement and experimentation, and accompanied by necessary demonstrations and lab-work physical marker for both the workshop; present course as a physical theory adequacy Wool mathematical form for solving practical not only in physics but also in system-related topic of natural and technical knowledge.

Optics

Forms a system of knowledge that contribute to understanding the fundamental laws and principles of classical and quantum optics, their use in the formulation and organization of the experiment, teaches basic methods of optical measurements.

Physics of atoms and atomic phenomena

Presents physical experiments with atomic systems as the basis for the creation of quantum physics and the formation of a system of knowledge that can apply in practice the semi-classical model of atomic-molecular processes.

Physics of nucleus and elementary particles

Study of the structure, patterns and properties of atomic nuclei, patterns of radioactive decay, nuclear reactions varieties and its applications, processes and physical laws of interaction of nuclear radiation with matter, modern experimental techniques in high energy physics, classification and properties of elementary particles, specific interactions between elementary particles, the relationship between the microcosm and the universe.

5,5

Fundamentals of Electrical and radio

Forms a system of knowledge that can apply in practice and setting up an experiment, measurement methods in electrical engineering and electronics, storage and processing of the received data, acquisition of skills and ability to work with specialized literature in electrical engineering and electronics.

8,5

Theoretical mechanics and fundamentals of continuum mechanics

Gives to the students a systematic exposition of theoretical mechanics and fundamentals of continuum mechanics. Students must know the fundamental concepts and laws of Newton –Haliley mechanics, laws of change and conservation of momentum, angular momentum, and energy equations, Lagrange, Hamilton and the Hamilton-Jacobi for a class of generalized potential forces and bases laws of continuum mechanics.

6,5

electrodynamics

Students have to learn the provisions of classical electrodynamics and special relativity theory, their mathematical tools, basic physical concepts.

QUANTUM MECHANICS

Gives to the students a deeper understanding of the laws of the microcosm. The student should acquire general mathematical apparatus of quantum mechanics and be able to use it in relativistic and nonrelativistic cases, make able to practically apply it and on this basis to get an idea of the physical nature of the phenomena that obey quantum laws. Students must learn to use approximate methods of quantum mechanics and quantum mechanics methods of many particles. What is important is the ability of students to interpret quantum processes.

Thermodynamics and Statistical Physics

Give to the students a detailed understanding of the behavior of different macroscopic systems in a state of thermodynamic equilibrium. Students must learn the general methods of studying physical systems and phenomena and be able to use them for research on the concept of a classical statistical physics, and in terms of the quantum laws of motion and interaction of objects.

astrophysics

The student must learn the basic data on the structure of the universe, the basic physical and chemical properties of celestial objects, the laws of motion of celestial bodies; acquainted with modern astronomical discoveries.

Chemistry

Provides students with such knowledge of chemistry as a branch of natural science, chemical systems, components and phases; aggregate state; phase content of physical and chemical analysis.

Programming Languages

Gives to the students an idea of the diversity of existing languages. And also provide an opportunity to learn the fundamental concepts of some of the most common methods of high-level programming - structural, structural-based methodology and object-oriented, based on Object Oriented Programming methodology.

Fundamentals of crystallography and crystal physics

Forms basic knowledge and skills of crystallography, crystal chemistry, fundamentals of crystal physics and physics of real crystals, providing qualified professional engineers, physicists activities and academic researchers.

2,5

Physical materials

Forms knowledge and skills to provide qualified engineer professional activity, physicists activities and academic researchers in the field of science and technology: review of the basic laws of formation of metallic and semiconducting phases; comparative analysis of the crystal and band structure, the nature of chemical bonds, structural perfection of crystal lattices and crystal chemistry of other features; introduction of mechanical, thermal, electrical and magnetic properties; presentation and analysis of the phase diagram of binary alloys; address special attention to the problem of phase transitions in iron-carbon alloys and their role for practice.

Defects in crystals

Forms knowledge and skills, such as structural defects classification, identification and description of point defects and dislocations in crystals that provide qualified professional engineers, physicists activities and academic researchers.

2,5

Solid State Physics (introduction)

This object is the first step to understanding the basics and further deepening the first study SSP as a science of structure, properties of solids and phenomena that happens they-are. Syllabus focused on the fact that the student understood the basic provisions and principles SSP without the use of mathematical apparatus of quantum mechanics non-relational -nicks that are not taught in the 3rd course.

2,5

Solid State Physics

This object is based on the fact that solid state physics - the science of the structure and properties of solids phenomena that take place in them, the program is structured so that the first step in its implementation was so that students understand and realize convinced that solid state physics is reduced to establish a connection between the properties of individual microscopic objects (atoms, molecules) and properties that occur when combining these facilities; almost all the properties of solids can be explained on the basis of simple models of solids; real objects of study of solid state physics is much more complicated than the model, but the effectiveness and usefulness of simple models is high; perfectionism simple models without bases non-relativistic quantum mechanics and statistical physics prove impossible to complete.

Structural analysis

Considers the physical basis diffraction methods study the structure of crystalline solids.

Electron microscopy

Forms of students' understanding of the physical processes underlying electron microscopy metals and alloys and principles of electron microscopes, knowledge and skills to provide qualified professional engineers, physicists activities and academic researchers in the field of science and technology.

Basis of dynamic theory of X-wave

Providing of training students for professional careers in science and technology, associated with a major study and the theoretical knowledge of the dynamic theory of diffraction of X-waves and relevant practical skills.

Computer methods and means of information processing

Development of data processing methodology of physical experiment, the study of modern software experiment, the main methods of statistical data processing optimizations.

2,5

Computer simulation of scattering processes

Special methods structure of solids

Providing of training students for professional careers in science and technology-related specialization training and the formation of the theoretical knowledge and practical skills. Namely, the features of the real structure study of mono- and polycrystals.

Physics of surface phenomena

Forms knowledge and skills, such as diagnostics surface physical and chemical processes on a real surface, semiconductor technology, that providing qualified professional engineers, physicists activities and scientific research.

Physics absorption processes

Introduce the theory of physics elastic energy absorption in solids resulting from summarizing observations, experience and experiment to establish connections between events absorption and structure of real materials and instill practical skills in obtaining and interpreting the absorption spectra of elastic energy.

Newest diffraction methods of solids

Forms the basic knowledge of laws and basic principles of new diffraction methods of investigation of the real structure of crystalline solids, gaining possession of skills in modern methods of research, treatment and analysis of experimental results; ability to use the knowledge gained during conducted independent research and future professional and scientific activities.

Computer software physics experiment in solid state physics

Provides knowledge that will allow inverse analysis applied problems in solid state physics and display basic equations describing the inverse problems; explore sustainable methods of solutions of these problems; correctness or incorrectness installation on Hadamard; bringing the problem to correct incorrect using the method of least squares Gauss method matrix pseudoinverse Moore-Penrose, Tikhonov regularization method.

3,5