Lukin Vladimir Petrovich

Publications in Math-Net.Ru

1. Overview of modern technologies for measuring, predicting and correcting turbulent distortions in optical waves
   
   Computer Optics, 48:1 (2024),  68–80
2. Comparison of the efficiency of sodium atom excitation schemes for generating monochromatic and polychromatic laser guide stars
   
   Kvantovaya Elektronika, 54:2 (2024),  67–76
3. Adaptive phase correction of vortex lasers beams in a turbulent atmosphere
   
   Kvantovaya Elektronika, 52:12 (2022),  1146–1151
4. Requirements for dynamic characteristics of adaptive optics systems
   
   Kvantovaya Elektronika, 52:7 (2022),  652–660
5. Cross-correlation of phase fluctuations measured with a point source and an incoherent luminous object
   
   Kvantovaya Elektronika, 51:3 (2021),  272–275
6. Outer scale of turbulence and its influence on fluctuations of optical waves
   
   UFN, 191:3 (2021),  292–317
7. The combined use of adaptive optics and nonlinear optical wavefront reversal techniques to compensate for turbulent distortions when focusing laser radiation on distant objects
   
   Computer Optics, 44:4 (2020),  519–532
8. Peculiarities of adaptive phase correction of optical wave distortions under conditions of 'strong' intensity fluctuations
   
   Kvantovaya Elektronika, 50:9 (2020),  866–875
9. Adaptive correction of the image of an incoherent source object
   
   Kvantovaya Elektronika, 49:2 (2019),  162–168
10. Measurement of an image jitter of an extended incoherent radiation source
    
    Kvantovaya Elektronika, 47:6 (2017),  580–588
11. Possibilities of joint application of adaptive optics technique and nonlinear optical phase conjugation to compensate for turbulent distortions
    
    Kvantovaya Elektronika, 46:5 (2016),  481–486
12. Adaptive optics in the formation of optical beams and images
    
    UFN, 184:6 (2014),  599–640
13. Adaptive optical imaging in the atmosphere
    
    UFN, 176:9 (2006),  1000–1006
14. Phase control of a focused laser beam: the comparison of the efficiency of methods
    
    Kvantovaya Elektronika, 35:2 (2005),  143–148
15. Phase and amplitude – phase control of a laser beam propagating in the atmosphere
    
    Kvantovaya Elektronika, 34:9 (2004),  825–832
16. Atmospheric adaptive optics
    
    UFN, 173:8 (2003),  887–893
17. Analysis of errors of the large telescope optics
    
    Dokl. Akad. Nauk SSSR, 300:2 (1988),  312–315
18. Efficiency of a two-color adaptive optical system
    
    Kvantovaya Elektronika, 15:9 (1988),  1856–1861
19. Focusing of a high-power laser beam in the course of thermal self-interaction in a moving medium
    
    Kvantovaya Elektronika, 15:2 (1988),  341–346
20. Mode correction for turbulent distortions of optical waves
    
    Kvantovaya Elektronika, 13:8 (1986),  1652–1656
21. Dynamic characteristics of adaptive optical systems
    
    Kvantovaya Elektronika, 12:9 (1985),  1959–1962
22. Adaptive correction of images
    
    Kvantovaya Elektronika, 10:12 (1983),  2465–2473
23. "Quasimode" correction of an image passed through a randomly inhomogeneous medium
    
    Kvantovaya Elektronika, 10:5 (1983),  995–1001
24. Correction of angular displacements of optical beams
    
    Kvantovaya Elektronika, 9:11 (1982),  2264–2271
25. Reciprocity principle and adaptive control of optical radiation parameters
    
    Kvantovaya Elektronika, 9:5 (1982),  952–958
26. Comparative characteristics of some correction algorithms
    
    Kvantovaya Elektronika, 8:10 (1981),  2145–2153
27. Propagation of modulated waves in a turbulent atmosphere. II. Correlation functions and frequency spectrum of fluctuations of the modulating-oscillation phase
    
    Kvantovaya Elektronika, 5:5 (1978),  1124–1129
28. Efficiency of the compensation of phase distortions of optical waves
    
    Kvantovaya Elektronika, 4:4 (1977),  923–927