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apostol_vourdas [2020/03/07 11:05] – weinbub | apostol_vourdas [2020/03/07 11:15] (current) – weinbub |
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* 170 journal papers and 60 conference papers (3600 citations and h-factor=34 according to Google Scholar) | * 170 journal papers and 60 conference papers (3600 citations and h-factor=34 according to Google Scholar) |
* 55 invited talks and 55 contributed talks in international conferences | * 55 invited talks and 55 contributed talks in international conferences |
* [[Apostol Vourdas]], [[https://www.springer.com/gp/book/9783319594941|Finite and Profinite Quantum Systems]] (Springer, 2017) | |
* teaching interests: Computer Architecture, Formal Methods in Computer Science, Computer Graphics | * teaching interests: Computer Architecture, Formal Methods in Computer Science, Computer Graphics |
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===== Wigner-specific research ===== | ===== Wigner-specific research ===== |
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Earnshaw RA, Lei C, Li J, Mugassabi S and Vourdas A (2012): "Large scale data analysis using the Wigner function" Physica A, 391 2401-2407. | * [[Apostol Vourdas]], [[https://www.springer.com/gp/book/9783319594941|Finite and Profinite Quantum Systems]] (Springer, 2017) |
| * Earnshaw RA, Lei C, Li J, Mugassabi S and [[Apostol Vourdas]], [[https://www.sciencedirect.com/science/article/pii/S0378437111008958|Large scale data analysis using the Wigner function]], Physica A **391**, 2401-2407 (2012) |
Vourdas A (2010): "Wigner and Weyl functions for p-adic quantum mechanics" Physics of atomic nuclei, 73 237-241. | *[[Apostol Vourdas]], [[https://link.springer.com/article/10.1134/S1063778810020055|Wigner and Weyl functions for p-adic quantum mechanics]], Physics of atomic nuclei **73**, 237-241 (2010) |
| * G. Giakasa, L.K. Stergioulas, and [[Apostol Vourdas]], [[https://www.sciencedirect.com/science/article/pii/S002192909900216X|Time-frequency analysis and filtering of kinematic signals with impacts using the Wigner function: accurate estimation of the second derivative]], Journal Biomech. **33**, 567-574 (2000) |
GIAKAS G, STERGIOULAS L and VOURDAS A (2000): "Time-frequency analysis and filtering of kinematic signals with impacts using the Wigner function: accurate estimation of the second derivative" Journal Biomech., 33 567-574. | * S. Chountasis, [[Apostol Vourdas]], and C. Bendjaballah, [[https://journals.aps.org/pra/abstract/10.1103/PhysRevA.60.3467|Fractional fourier operators and generalized Wigner functions]], Physical Review A **60**, 3467 (1999) |
| * S. Chountasis, L. K. Stergioulas, and [[Apostol Vourdas]], [[https://www.tandfonline.com/doi/abs/10.1080/09500349908231397|Quantum filtering of noise in the Wigner function]], Journal Mod. Optics **46**, 2131-2134 (1999) |
HOUNTASIS S, VOURDAS A and BENDJABALLAH C (1999): "Fractional fourier operators and generalized Wigner functions" Physical Review, A60 3467-3473. | * S. Chountasis and [[Apostol Vourdas]], [[https://journals.aps.org/pra/abstract/10.1103/PhysRevA.58.1794|Weyl and Wigner functions in an extended phase space formalism]], Physical Review A **58**, 1794-1798 (1998) |
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CHOUNTASIS S, STERGIOULAS L.K and VOURDAS A (1999): "Quantum filtering of noise in the Wigner function" Journal Mod. Optics, 46 2131-2134. | |
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CHOUNTASIS S and VOURDAS A (1998): "Weyl and Wigner functions in an extended phase space formalism" Physical Review, A58 1794-1798. | |
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