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  1. Vladimirov A.P. Drukarenko N.A. Myznov K.E. Using Speckle Images for Determining the Local Plastic Strains Arising at High-Cycle Fatigue of 09G2S Steel // Technical Physics Letters. 2021. Vol. 47. No. 8. P. 773–776. DOI: 10.1134/S1063785021080137.
    WoS  Scopus 

  2. Vladimirov A.P. Kamantsev I.S. Drukarenko N.A. Trishin V.N. Akashev L.A. Druzhinin A.V. Assessing Fatigue Damage in Organic Glass Using Optical Methods // Optics and Spectroscopy. 2019. Vol. 127. Iss. 5. P. 943-953. DOI: https://doi.org/10.1134/S0030400X19110286.
    WoS  Scopus 

  3. Vladimirov A.P. Kamantsev I.S. Drukarenko N.A. Gladkovsky S.V. Bukhvalov A.B. Khudorozhkova Yu.V. Cheremicina E.R. Gorkunov E.S. Nucleation and Initiation of Cracks under High-Cycle Fatigue in the EP679 Maraging Steel // AIP Conference Proceedings. 2019. Vol. 2176. 030019. – https://doi.org/10.1063/1.5135143.
    WoS 

  4. Vladimirov A.P. Drukarenko N.A. Kamantsev I.S. Trishin V.N. Lookin N.A. Real-time study of high-cycle fatigue damage using the averaged speckle dynamics // IOP Conf. Series: Journal of Physics: Conf. Series. 2018. Vol. 1149. 012013. DOI:10.1088/1742-6596/1149/1/012013.
    WoS 

  5. Vladimirov A.P. Mikhailova Yu.A. Drukarenko N.A. Dynamic speckle interferometry of technical and thin biological objects // Proceedings of SPIE. 2018. Vol. 10834. Speckle 2018: VII International Conference on Speckle Metrology, 1083427. DOI: 10.1117/12.2319729.
    WoS 

  6. Vladimirov A.P. Ponosov Yu.S. Application of speckle dynamics and Raman light scattering to study the fracture features of pipe steel at high-cycle fatigue // PNRPU Mechanics Bulletin. 2018. No. 3. P. 138-146. DOI: 10.15593/perm.mech/2018.3.13.
    Scopus 

  7. Druzhinin A.V. Vladimirov A.P. Tsvetkova E.V. Teoretical Bases of Magnetooptical Refractometry for Transparent Media [Electronic resource] // Diagnostics, Resource and Mechanics of materials and structures. 2018. Iss. 6. P. 83-89. DOI: 10.17804/2410-9908.2018.6.083-089.
    РИНЦ 

  8. Vladimirov A.P. Alexey A. Bakharev Dynamic Speckle Interferometry of Thin Biological Objects: Theory, Experiments and Practical Perspectives // Optical Interferometry. – Chapter 6. – P. 103-141. – http://dx.doi.org/chapter/10.5772/66712. – http://dx.doi.org/chapter/10.5772/63683. – Publisher: INTECH, 2017. – Edited by Alexander A. Banishev, Mithun Bhowmick and Jue Wang. – Belyaev, A. K., Irschik, Hans, Krommer, Michael (Eds.), Print ISBN: 978-953-51-2955-4. Online ISBN: 978-953-51-2956-1. 2017. 249 p.

  9. Ogorelkov D. A. Kamantsev I.S. Vladimirov A.P. Khudorozhkova Yu.V. Numerical and Experimental Approaches to the Evaluation of the Fatigue Life of a Cylindrical Specimen made of the 09G2S Steel // AIP Conf. Proc. – 2017. Vol. 1915. – 040010.
    Full text>>

  10. Ogorelkov D. A. Kamantsev I.S. Kuznetsov A.V. Vladimirov A.P. Khudorozhkova Yu.V. Numerical and Experimental Approaches to the Evaluation of the Fatigue Life of a Cylindrical Specimen made of the 09G2S Steel // AIP Conference Proceedings. 2017. 1915. – 040010. 5 p.

  11. Mikhailova Y.A. Vladimirov A.P. Bakharev A.A. Sergeev A.G. Novosyolova I.A. Yakin D.I. Studying of cell culture reaction to temperature change by dynamic speckle interferometry // Russian Journal of Biomechanics. 2017. Vol. 21. – No. 1. P. 64-73.

  12. Vladimirov A.P. Dynamic Speckle Interferometry of High-Cycle Material Fatigue: Theory and Some Experiments // AIP Conference Proceedings. 2016. Vol. 1740. – 040004. – DOI: 10 1063/1 4962663.

  13. Vladimirov A.P. Novoselova I.A. Mikhailova Y.A. Bakharev A.A. Yakin D. I. The use of laser dynamical speckle interferometry in the study of cellular processes // Journal of Biomedical Photonics & Eng. 2016. Is. 2(1). P. 010302-1-010302-6. DOI: 10.18287/JBPE16.02.010302.

  14. Vladimirov A.P. Speckle metrology of dynamic macro- and microprocesses in deformable media // Optical Engineering. 2016. Vol. 55. – No. 12. – 121727. P. 1-10.

  15. Vladimirov A.P. Kamantsev I.S. Veselova V.E. Gorkunov E.S. Gladkovsky S.V. Use of Dynamic Speckle Interferometry for Contactless Diagnostics of Fatigue Crack Initiation and Determining Its Growth Rate // Technical Physics. 2016. Vol. 61. – No. 4. P. 563–568.

  16. Baharev A.A. Vladimirov A.P. Malygin A.S. Mihailova Y.A. Novoselova I.A. Yakin D.I. Druzhinin A.V. Dynamic speckle-interferometer for intracellular processes analyses at high optical magnification // Proc. of SPIE. 2015. Vol. 9529. P. 95291G-1 – 95291G-9.

  17. Vladimirov A.P. Dynamic speckle interferometry of intracellular processes: theory and features of application // Proc. of SPIE. 2015. Vol. 9529. P. 95290Y-1 – 95290Y-9.

  18. Vladimirov A.P. Baharev A.A. Malygin A.S. Mikhailova J.A. Novoselova I.A. Yakin D.I. Application of speckle dynamics for studies of cell metabolism // Proc. of SPIE. 2015. Vol. 9529. P. 95291F-1 – 95291F-10.

  19. Vladimirov A.P. Kamantsev I.S. Veselova V.E. Gladkovsky S.V. Using speckle images correlation for real-time inspection of fatigue crack initiation and propagation // Proc. of SPIE. 2015. Vol. 9525. P. 952525-1 - 952525-6.

  20. Vladimirov A.P. Dynamic Speckle-Interferometry of Microscopic Processes in Thin Biological Objects // Radiophysics and Quantum Electronics. 2015. Vol. 57. No. 8-9. P. 564-576.

  21. Vladimirov A.P. Malygin A.S. Mikhailova Yu.A. et. al. Using Speckle Dynamics for Comparison of the Metabolic Activity of Different Cell Cultures // Radiophysics and Quantum Electronics. 2015. Vol. 57. No. 8-9. P. 584-588.

  22. Vladimirov A.P. Time - Average Dynamic Speckle Interferometry // AIP Conf. Proc. 1600, 237. 2014. – http://dx.doi.org/10.1063/1.4879588.

  23. Vladimirov A.P. Bakharev A.A. Malygin A.S. Mikhaylova J.A. Borodin E.M. Poryvayeva N.P. Glinskikh A.P. Application of dynamic speckle-interferometry in the study of the metabolism of cultivated cells with viruses // AIP Conf. Proc. 1600, 357. 2014. – http://dx.doi.org/10.1063/1.4879603.

  24. Vladimirov A.P. Dynamic speckle - interferometry of micro-displacements // AIP Conf. Proc. 2012. V. 1457. P. 459-468.

  25. Vladimirov A.P. Dynamic speckle interferometry of the microscopic processes // Proceedings of SPIE. 2012. V. 8413. P. 841305. P. 1-6.

  26. Vladimirov A.P. Druzhinin A.V. Malygin A.S. Mikitas К.N. Theory and calibration of speckle dynamics of phase object // Proceedings of SPIE. 2012. V. 8337. – P. 8337ОС: 1-15.

  27. Vladimirov A.P. Gorkunov E.S. Eremin P.S. Zadvorkin S.M. Shadrin M.V. Solov’ev K.E. A Speckle_Interferometric Setup for Contactless Measurements
    of the Velocity of Rayleigh Ultrasonic Waves // Instruments and Experimental Techniques. Pleiades Publishing, Ltd., 2010. Vol. 53, No. 1. P. 118–121.

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