13E062KM - Quantum Mechanics
| Course specification | ||||
|---|---|---|---|---|
| Course title | Quantum Mechanics | |||
| Acronym | 13E062KM | |||
| Study programme | Electrical Engineering and Computing | |||
| Module | Physical Electronics | |||
| Type of study | bachelor academic studies | |||
| Lecturer (for classes) | ||||
| Lecturer/Associate (for practice) | ||||
| Lecturer/Associate (for OTC) | ||||
| ESPB | 6.0 | Status | mandatory | |
| Condition | None. | |||
| The goal | Introduce students to the basic concepts of quantum mechanics, such as the Schrödinger equation, eigenvalues and eigenvectors. | |||
| The outcome | Understanding of the quantum states descriptions by wave functions. Gaining a working knowledge of solving the Schrödinger equation. | |||
| Contents | ||||
| URL to the subject page | http://nobel.etf.bg.ac.rs/studiranje/kursevi/of2km/ | |||
| Contents of lectures | Stationary Schrödinger equation. Linear operators. Coordinate and momentum representations. Uncertainty principles. Dirac notation. Matrix representation. Angular momentum. Spin. Electron in a central field. Hydrogen atom. Linear harmonic oscillator. Ladder operators. Particle in a magnetic field. Time-independent perturbations for non-degenerate states. Time-dependent perturbations theory. Qubit. | |||
| Contents of exercises | Computer simulations of selected examples from problem-solving classes. | |||
| Literature | ||||
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| Number of hours per week during the semester/trimester/year | ||||
| Lectures | Exercises | OTC | Study and Research | Other classes |
| 3 | 2 | |||
| Methods of teaching | Lectures and problem-solving classes. | |||
| Knowledge score (maximum points 100) | ||||
| Pre obligations | Points | Final exam | Points | |
| Activites during lectures | Test paper | 50 | ||
| Practical lessons | Oral examination | |||
| Projects | ||||
| Colloquia | 50 | |||
| Seminars | ||||