Lectures content overview
Completion requirements
| 17.2. | Course overview |
| 19.2. | Mach-Zehnder interferometer |
| 24.2. | Practicals |
| 26.2. |
Solution of Schrödinger equation. Postulate of Measurement. And a lot of support mathematics: adjoint operators, spectral theorem for normal matrices, spectral decomposition, normal and unitary matrices, projective operators |
| 3.3. | Practicals |
| 5.3. | Fourth postulate, tensor products and quantum registers |
| 10.3. | Deutsch/Deutsch-Jozsa algorithm |
| 12.3. | Jozsa algorithm (conclusion)/Universal set of gates |
|
17.3. |
Practicals |
| 19.3. |
Universal set of gates |
| 24.3. |
Universal set of gates(conclusion)/Characters of groups and Discrete Fourier Transform (DFT) |
| 26.3. |
DFT/Shor's algorithm |
| 31.3. | Practicals |
| 31.3. |
Shor's algorithm |
| 7.4. |
DFT decomposition |
| 9.4. | DFT success probability/Complex projective line - qubit representation |
| 14.4. | Practicals |
| 16.4. | Operators representation |
| 21.4. | Easter |
| 23.4. | Operators representation, ctd. |
| 28.4. | Quaternions and rotation |
| 30.4. | AXBXC decomposition |
| 5.5. | Practicals |
| 7.5. |
Bell states: questions of interpretation, density operator, trace |
| 12.5. |
Non-cloning theorem. Partial system: mixed state of a pure larger system; positive operators are Hermitian; definition of mixed states; diagonal decomposition; corresponding ensemble is not unique; partial trace; definition of von Neumann entropy |
Last modified: Monday, 12 May 2025, 6:01 PM