Geodesic
Linearization of differential algebraic equations with integral terms and their application to the thermal energy modelling
Vestnik Ûžno-Uralʹskogo gosudarstvennogo universiteta. Seriâ, Matematičeskoe modelirovanie i programmirovanie, Tome 11 (2018) no. 4, pp. 94-109 Cet article a éte moissonné depuis la source Math-Net.Ru

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Modelling of various natural and technical processes often results in systems that comprise ordinary differential equations and algebraic equations This paper studies systems of quasi-linear integral-differential equations with a singular matrix multiplying the higher derivative of the desired vector-function. Such systems can be treated as differential algebraic equations perturbed by the Volterra operators. We obtained solvability conditions for such systems and their initial problems and consider possible ways of linearization for them on the basis of the Newton method. Applications that arise in the area of thermal engineering are discussed and as an example we consider a hydraulic circuit presented as a system comprising an interconnected set of discrete components that transport liquid. Numerical experiments that employed the implicit Euler scheme showed that the mathematical model of the straight-through boiler with a turbine and a regeneration system has a solution and this solution tends to the stationary mode preset by regulators.
Keywords: differential algebraic equations, Fredholm operator, Volterra operator, initial problem, consistency problem, index. 
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E. V. Chistyakova; V. F. Chistyakov; A. A. Levin. Linearization of differential algebraic equations with integral terms and their application to the thermal energy modelling. Vestnik Ûžno-Uralʹskogo gosudarstvennogo universiteta. Seriâ, Matematičeskoe modelirovanie i programmirovanie, Tome 11 (2018) no. 4, pp. 94-109. http://geodesic.mathdoc.fr/item/VYURU_2018_11_4_a6/

[1] Reich S., Differential-Algebraic Equations and Applications in Circuit Theory, Universität Potsdam, 1992

[2] Eich-Soellner E., Führer C., Numerical Methods in Multibody Systems, Teubner, Stuttgart, 1998 | DOI | MR

[3] Balyshev O. A., Tairov E. A., Analysis of Transient and Steady-State Processes in Pipeline Systems, Nauka, Novosibirsk, 1999 (in Russian)

[4] Vlach J., Singhal K., Computer Methods for Circuit Analysis and Design, Van Nostrand Reinhold, N.Y., 1983

[5] Sviridyuk G. A., Fedorov V. E., Linear Sobolev Type Equations and Degenerate Semigroups of Operators, VSP, Utrecht–Boston–Köln–Tokyo, 2003 | DOI | MR | Zbl

[6] Brenan K. E., Campbell S. L., Petzold L. R., Numerical Solution of Initial-Value Problems in Differential Algebraic Equations, SIAM Publications, Philadelphia, 1996 | MR | Zbl

[7] Boyarintsev Yu. E., Chistyakov V. F., Algebraic Differential Systems. Methods for Investigation and Solution, Nauka, Novosibirsk, 1998 (in Russian) | MR

[8] Lamour R., Marz R., Tischendorf C., Differential-Algebraic Equations: a Projector Based Analysis, Springer, Berlin, 2013 | DOI | MR | Zbl

[9] Luzin N. N., “On the Study of the Matrix Theory of Differential Equations”, Avtomatika i Telemekhanika, 1940, no. 5, 4–66 (in Russian) | MR

[10] Chistyakov V. F., Algebraic Differential Operators with a Finite-Dimensional Kernel, Nauka, Novosibirsk, 1996 (in Russian) | MR

[11] Mehrmann V., Shi C., “Transformation of High Order Linear Differential-Algebraic Systems to First Order”, Numerical Algorithms, 2006, no. 42, 281–307 | DOI | MR | Zbl

[12] Chistyakov V. F., Chistyakova E. V., “Linear Differential-Algebraic Equations Perturbed by Volterra Integral Operators”, Differential Equations, 53:10 (2017), 1–14 | DOI | MR

[13] Bulatov M. V., Chistyakov V. F., “A Method for Solving Linear Singular Systems of DAEs with Index Higher than One”, Numerical Analysis Methods and Their Applications, Irkutsk, 1987, 100–105 (in Russian) | MR

[14] Krasnov M. L., Integral Equations: Introduction to the Theory, Nauka, M., 1975 (in Russian)

[15] Pazii N. D., Local Analytical Classification of the Sobolev Type Equations, PhD Thesis, Chelyabinsk, 1999 (in Russian)

[16] Merenkov A. P., Hasilev V. Ya., Theory of Hydraulic Circuits, Nauka, M., 1985 (in Russian)

[17] Chistyakov V. F., “Linearization of Singular Systems of Quasi-Linear Ordinary Differential Equations”, Approximare Methods for Solving Operator Equations and Their Applications, Irkutsk, 1982, 146–157 (in Russian)

[18] Chistyakov V. F., “The Connection Between the Matrix Pencil and the Existence of a Solution to an Implicit System of ODEs”, Methods for Optimization and Operational Research, Irkutsk, 1982, 194–202

[19] Chistyakova E. V., Chistyakov V. F., “On the Solvability of Degenerate Systems of General Quasilinear Integro-Differential Equations”, Computational Technologies, 16:5 (2011), 100–114

[20] Chistyakova E. V., Nguyen Duc Bang, “Investigation of the Unsteady-State Hydraulic Networks by Means of Singular Systems of Integral Differential Equations”, Bulletin of the South Ural State University. Series: Mathematical Modelling, Programming and Computer Software, 9:1 (2016), 59–72 | DOI | Zbl

[21] Levin A. A., Chistyakov V. F., Tairov E. A., “On Application of the Structure of the Nonlinear Equations System, Describing Hydraulic Circuits of Power Plants”, Bulletin of the South Ural State University. Series: Mathematical Modelling, Programming and Computer Software, 9:4 (2016), 53–62 | DOI | Zbl