jupyter notebooks, code and other artefacts
| Topic | Reference/link | Description/link | Presenter |
|---|---|---|---|
| 40. Applications of Near-Term Photonic Quantum Computers: Software and Algorithms | arXiv:1912.07634 | Seminar at AANL | Hayk Sargsyan |
| 39. Quantum Computing and Quantum Cryptography | link to presentation | Presentation at ArmSec annual conference, AUA, Yerevan, Armenia | Hayk Sargsyan |
| 38. Quantum Technologies (QT) | Links at fb group | QT (Computing, Simulation, Communication, Sensing), it's Market, Social and Economic Impact | Hakob Avetisyan |
| 37. Non-Markovian dynamics of systems coupled to heat-bath(s) with same/different statistics | Langevin approach used for derivations, approximations, numerical methods used and results obtained in papers 1, 2. The case of a system simultaneously coupled to fermionic and bosonic heat-baths. | Arshak Hovhannisyan | |
| 36. Quantum computers. How to program them? | Presentation and Tutorial | Hakob Avetisyan | |
| 35. Practical Application Areas of Quantum Computing | Practical Application Areas of Quantum Computing | Hakob Avetisyan | |
| 34. How To Join The QC Ecosystem | How To Join The QC Ecosystem | Hakob Avetisyan | |
| 33. Quantum Supremacy (Google-Nasa) | Discussion of Google & NASA's report on quantum supremacy using a processor with programmable superconducting qubits | Hakob Avetisyan | |
| 32. Combining dynamical decoupling and other Error mitigation techniques to improve reliability of quantum computers | arXiv:0911.3202 | DD-protected quantum gates outperform unprotected gates. Under suitable conditions, fault-tolerant quantum circuits constructed from DD-protected gates can tolerate stronger noise, and have a lower overhead cost, than fault-tolerant circuits constructed from unprotected gates. | Arshak Hovhannisyan |
| 31. Boson sampling and possible applications to percolation theory | The original boson sampling, as well as gaussian boson sampling protocols is introduced. The mathematical models are described, and the relevance in modern quantum computing research is pointed out. Finally discussed some possible applications of these protocols in percolation problems. | Hayk Sargsyan | |
| 30. Quantum computing with continuous variables | Presentation at International School on Optics and Photonics ISOP 2019, RAU | Hayk Sargsyan | |
| 29. Quantum Computers and the Promise | Presentation at Russian-Armenian University's weekly seminars | Hakob Avetisyan | |
| 28. GATE MODEL, ADIABATIC, ANNEALING AND VARIATIONAL QUANTUM COMPUTING | Presentation at A. Alikhanyan National Laboratory weekly seminars | Hakob Avetisyan | |
| 27. Talk at AANL workshop | A. Alikhanyan National Laboratory, Fostering Synergy Between Science & Industry | Hakob Avetisyan | |
| 26. Mermin'a Magic Square Game | Am.J.Phys. 72, 1303 (2004) | Mermin'a Magic Square Game (at YerPhI) | Arshak Hovhannisyan |
| 25. Quantum Machine Learning | arXiv:1804.10068 | Introduction to QML (at YerevaNN) | Hakob Avetisyan |
| 24. Boson Sampling | arXiv:1406.6767 | An Introduction to Boson Sampling (at YerPhI) | Hakob Avetisyan |
| 23. Quantum Chemistry | arXiv:1605.03590 | Elucidating reaction mechanisms on quantum computers (at YerPhI) | Arshak Hovhannisyan |
| 22. Quantum Cryptography | Presentation | Talk at ArmSec Conference (Yerevan) | Nshan Barseghyan |
| 21. HHL algorithm | arXiv:0811.3171 | Quantum algorithm for solving linear systems of equations (at YerPhI) | Hakob Avetisyan |
| 20. Quantum RAM | arXiv:0708.1879 | Quantum Random Access Memory (at YerPhI) | Hakob Avetisyan |
| 19. Quantum machine learning | arXiv:1307.0411 | Quantum algorithms for supervised and unsupervised machine learning (at YerPhI) | Hakob Avetisyan |
| 18. Current State of Quantum Computing | Presentation | Talk at STC forum (Yerevan) | Hakob Avetisyan |
| 17. Entropy and Information | Shannon's Entropy | Davit Khachatryan | |
| 16. Addition on a Quantum Computer | arXiv:0008033 | Adding integers on Quantum Computer | Arshak Hovhannisyan |
| 15. Dgital circuits design | CMOS trigger, Mealy, Moore, ASIC | Roza Bejanyan | |
| 14. Digital circuits design | Combinational Circuits, Multiplexer, Encoder, Adder, Comparator | Roza Bejanyan | |
| 13. Fundamentals of Classical circuits | Bool. algebra, DeMorgan law, Karnaugh map, Basic circuits | Roza Bejanyan | |
| 12. Group theory 2 | Introduction to Groups | Nshan Barseghyan | |
| 11. Group theory 1 | Math Intro | Nshan Barseghyan | |
| 10. Quantum mechanics 6 | Peres, Quantum Theory: Concepts and Methods | Kochen–Specker Theorem | Hakob Avetisyan |
| 9. Quantum mechanics 5 | AmJPhys 55, 696 (1987), Scientific American 241, 158 (1979) | Determinism, Reality, Locality | Hakob Avetisyan |
| 8. Quantum mechanics 4 | RevModPhys 42, 358 (1970), Nuovo Cimento 38B, 75 (1977) | Hidden variables, Bell's Theorem, CHSH inequality | Hakob Avetisyan |
| 7. Quantum mechanics 3 | Ballentine, AmJPhys 54, 853 (1986) | Joint Prob. Distributions, Probability Theory in QM | Hakob Avetisyan |
| 6. Quantum mechanics 2 | Ballentine, RevModPhys 42, 358 (1970) | QM Postulates, State Prep., EPR, Uncertainty, Measurement | Hakob Avetisyan |
| 5. Quantum mechanics 1 | Overview from edX course (Harward) | Wave Mechanics, from-PIB-to-Helium Atom | Hakob Avetisyan |
| 4. Probability Theory | Adrine Kocharyan | ||
| 3. Python + Jupyter notebook | Vazgen Hakobjanyan | ||
| 2. Python + Jupyter notebook | Vazgen Hakobjanyan | ||
| 1. Linear Algebra | Rafael Shirakyan |