Tsvetkov Viktor Pavlovich

Publications in Math-Net.Ru

1. Determination of instaneous cardiac rhythm parameters in multifractal dynamics model by regularized Newton's method
   
   Matem. Mod., 29:12 (2017),  147–156
2. Catastrophes instantaneous heart rate in the model multifractal dynamics and based on the data of Holter monitoring
   
   Matem. Mod., 29:5 (2017),  73–84
3. Bifurcation catastrophes of an instant cardiac rhythm in multifractal dynamics model
   
   Vestnik TVGU. Ser. Prikl. Matem. [Herald of Tver State University. Ser. Appl. Math.], 2016, no. 1,  63–73
4. Analysis of instantaneous cardiac rhythm in a model multi-fractal dynamics based on Holter monitoring
   
   Matem. Mod., 27:4 (2015),  16–30
5. Mathematical model of multifractal dynamics and global warming
   
   Eurasian Math. J., 5:2 (2014),  52–59
6. Mathematical model of multi-fractal dynamics and analysis of heart rate
   
   Matem. Mod., 26:10 (2014),  127–136
7. Extremum energy of a rotating magnetized gravitating configuration as balance condition
   
   Vestnik TVGU. Ser. Prikl. Matem. [Herald of Tver State University. Ser. Appl. Math.], 2011, no. 20,  73–76
8. Formation of ring-shaped bubbles in the mathematical model of the rotating Newtonian polytrops
   
   Vestnik TVGU. Ser. Prikl. Matem. [Herald of Tver State University. Ser. Appl. Math.], 2010, no. 17,  73–84
9. Configurations of rotating magnetic Newtonian polytropics with small index
   
   Vestnik TVGU. Ser. Prikl. Matem. [Herald of Tver State University. Ser. Appl. Math.], 2010, no. 16,  75–86
10. Mathematical model of equilibrium rotating newtonian configurations of the degenerate fermi-gas
    
    Vestnik TVGU. Ser. Prikl. Matem. [Herald of Tver State University. Ser. Appl. Math.], 2009, no. 15,  107–114
11. Mathematical model of equilibrium rotating newtonian configurations of the degenerate fermi-gas
    
    Vestnik TVGU. Ser. Prikl. Matem. [Herald of Tver State University. Ser. Appl. Math.], 2009, no. 13,  15–22
12. A gravitating rapidly rotating superdense configuration with realistic state equations
    
    Matem. Mod., 18:3 (2006),  103–119
13. Integral Equation for the Spinor Amplitude of a Dirac Particle in a Curved Space-Time
    
    TMF, 135:2 (2003),  331–337
14. Massive neutral Dirac particle in a curved space–time with the Kerr–Schild metric
    
    TMF, 125:2 (2000),  343–352
15. The Burman–Lagrange series method in the problem of analytic representation of Newtonian potential of perturbed ellipsoidal configurations
    
    Dokl. Akad. Nauk SSSR, 313:5 (1990),  1099–1102