Solnechnyi Èngel M

Publications in Math-Net.Ru

1. Studying the dynamic properties of a distributed thermomechanical controlled plant with intrinsic feedback. II
   
   Avtomat. i Telemekh., 2023, no. 4,  35–44
2. Dynamic properties of a one-dimensional heat transfer system with a moving heat source
   
   Avtomat. i Telemekh., 2022, no. 8,  29–37
3. Studying the dynamic properties of a distributed thermomechanical system and stability conditions for its control system
   
   Avtomat. i Telemekh., 2021, no. 8,  60–84
4. Studying the dynamic properties of a distributed thermomechanical controlled plant with intrinsic feedback. I
   
   Avtomat. i Telemekh., 2020, no. 4,  52–60
5. Conditions for stability and roughness of the distributed plant control system with a controller close to the degenerate system
   
   Avtomat. i Telemekh., 2017, no. 7,  86–94
6. Stability conditions for a heat transfer object control system with Schipanov controller under imperfections in the controller
   
   Avtomat. i Telemekh., 2016, no. 12,  70–88
7. Stability preservation conditions for a two-layered heat transfer object closed by feedback
   
   Avtomat. i Telemekh., 2015, no. 9,  64–82
8. Using G. V. Shchipanov's ideas to provide perturbation-invariance of the output of a distributed linear plant
   
   Avtomat. i Telemekh., 2014, no. 1,  90–104
9. On stability conditions of a control system for a linear heat transfer object bounded from one side
   
   Avtomat. i Telemekh., 2011, no. 4,  11–26
10. Investigation of causality and stability conditions of linear heat-conductivity object control system (special cases). Part II
    
    UBS, 32 (2011),  40–82
11. Investigation of causality and stability conditions of a linear heat-conductivity object control system (special cases). Part I
    
    UBS, 28 (2010),  89–125
12. Invariance and astatism in systems not measuring perturbations
    
    Avtomat. i Telemekh., 2008, no. 12,  76–85
13. Causality and stability conditions for the control of a linear distributed system
    
    Avtomat. i Telemekh., 2006, no. 4,  53–85
14. Degeneration effects in distributed systems and their behavior as their parameters approach the point of degeneration
    
    Avtomat. i Telemekh., 2004, no. 11,  64–78
15. Causality of a Heat Conductivity System with Nonlinear Feedback from Boundary Conditions. I
    
    Avtomat. i Telemekh., 2002, no. 9,  15–26
16. Investigation of degenerate distributed systems by the symmetry method
    
    Avtomat. i Telemekh., 1999, no. 5,  91–96
17. On the causality of operators that arise in problems of mathematical physics with weak nonlinearities
    
    Differ. Uravn., 35:6 (1999),  801–808
18. Investigation of the conditions for the stability of a linear control system with one-channel feedback with respect to the small parameters
    
    Avtomat. i Telemekh., 1998, no. 12,  68–81
19. Conditions for the Volterra property of an operator generated by the Cauchy problem for a partial differential equation
    
    Differ. Uravn., 33:2 (1997),  267–274
20. Properness Conditions for Distributed Linear Dynamic Systems
    
    Avtomat. i Telemekh., 1996, no. 5,  58–69
21. Mathematical description of the dynamics of linear distributed systems by means of generalized functions and their Fourier transforms
    
    Avtomat. i Telemekh., 1995, no. 1,  64–75
22. Investigation of the problem of the construction of a weakly invariant system for the control of an aircraft
    
    Avtomat. i Telemekh., 1993, no. 1,  50–61
23. Investigation of the problem of the synthesis of an invariant system for the control of a synchronized generator
    
    Avtomat. i Telemekh., 1991, no. 12,  62–75
24. On Crudeness of linear systems depending on a Scalar parameter
    
    Avtomat. i Telemekh., 1990, no. 11,  63–72
25. Problems on the design of dynamical control systems that satisfy prescribed constraints on the process state
    
    Avtomat. i Telemekh., 1990, no. 2,  50–58
26. Stability and grudeness conditions for a single-channel invariant arbitrary-order system
    
    Avtomat. i Telemekh., 1988, no. 7,  58–70
27. Design of control systems having the desired properties
    
    Avtomat. i Telemekh., 1987, no. 1,  24–33
28. Automated linear analysis of continuous control systems
    
    Avtomat. i Telemekh., 1986, no. 10,  157–168
29. The possibility of approximating dynamic properties of a single-channel control system approaching absolute invariance
    
    Avtomat. i Telemekh., 1985, no. 4,  49–56
30. Sufficient conditions for stability of nonautonomous linear systems and estimation of the regions of attraction of nonlinear systems
    
    Avtomat. i Telemekh., 1985, no. 1,  40–47
31. Asymptotic behavior of properties of a gas flow when the Mach number approaches zero
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 1984, no. 5,  78–81
32. On change of the phase volume in control systems with discontinuous responses
    
    Avtomat. i Telemekh., 1983, no. 7,  63–69
33. On physical feasibility and stability of linear distributed systems
    
    Avtomat. i Telemekh., 1981, no. 4,  26–38
34. On stability and insensitivity of linear systems to various kinds of signals
    
    Avtomat. i Telemekh., 1979, no. 9,  26–35
35. The theorems of Fatou and Lebesgue for sequences and systems of finite subsets in lattices
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 1976, no. 10,  74–78
36. Solvability conditions for the control system synthesis problem under specified requirements on the transient responses
    
    Avtomat. i Telemekh., 1975, no. 12,  36–50
37. Invariant dynamic systems with degenerate subsystems and conditions for their crudeness
    
    Avtomat. i Telemekh., 1975, no. 8,  14–21
38. Points of stationarity of functionals of the type of the action integral of a conservative system
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 1971, no. 2,  96–101
39. The intersection of subspaces augmented by one dimension, and the intersection of linear varieties
    
    Izv. Vyssh. Uchebn. Zaved. Mat., 1969, no. 11,  87–93