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View all- Öncü SÜnal KTunçer U(2020)D Sınıfı Eviricinin Runge-Kutta Metodu ile Analizinin YapılmasıAcademic Perspective Procedia10.33793/acperpro.03.01.663:1(337-345)Online publication date: 25-Oct-2020
Transient Analysis of Electrical Circuits using Block Backward Differentiation Formula
Pages 99 - 103
Abstract
Transient is the time-varying currents and voltages resulting from the sudden change in supply current or voltage. This phenomenon usually occurs due to any switching, interrupting, short-circuiting as well as any rapid changes in the structure of an electrical circuit. To avoid any damage in certain components resulting from the transient, it is important to analyze the change of voltage or current across the circuit elements. This paper studies the transient analysis of a second order RLC circuit that consists of resistors (R) and two energy storage elements, which are inductor (L) and capacitor (C). Such circuit is normally represented in the form of second order ordinary differential equations (ODEs) and such problems are not easily solved analytically. Therefore, a numerical method, namely block backward differentiation formula (BBDF) is applied for solving the ODEs by taking into consideration the damping factor and change in charge with respect to time. This method has the advantage that in each application, the solution is computed at two points simultaneously, which can give faster solutions to the problem. Numerical experiments are carried out to evaluate the capability of the proposed method. It is shown that the numerical solutions approximate the analytical solutions. The performance of the BBDF is compared with the Euler's method, Heun's method and Runge-Kutta method in terms of accuracy. Results obtained show that the proposed method is reliable for transient analysis of electrical circuit due to its comparable degree of accuracy.
References
[1]
Zelenkov, A. A. 2009. Transient analysis of electric power circuits by the classical method, Training B. Ministry of Education and Science of Ukraine.
[2]
Suhag, A. 2013. Transient analysis of electrical circuits using Runge- Kutta method and its application. Int. J. Sci. Res. Publ., 3, 11, 1--5.
[3]
Guha, S. and Srivastava, R. 2010. Numerical Methods for Engineering and Science. New Delhi, India: Oxford University Press.
[4]
Henry, O., Albert, B. and Justice, I. 2019. Application of numerical methods in transient analysis. Int. J. Sci. Res., 8, 5, 2108--2112.
[5]
Kee, T. A. and Ranom, R. 2018. Comparison of numerical techniques in solving transient analysis of electrical circuits. ARPN J. Eng. Appl. Sci., 13, 1, 314--320.
[6]
Ibrahim, Z. B., Othman, K. I. and Suleiman, M. 2007. Implicit r-point block backward differentiation formula for solving first-order stiff ODEs. Appl. Math. Comput., 186, 1, 558--565.
[7]
Ibrahim, Z. B., Suleiman, M. Nasir, N. A. A. M. and Othman, K. I. 2011. Convergence of the 2-point block backward differentiation formulas. Appl. Math. Sci., 5, 69-72, 3473--3480.
[8]
Idrees, M., Mabood, F., Ali, A. and Zaman, G. 2013. Exact solution for a class of stiff systems by differential transform method. Appl. Math., 4, 3, 440--444.
[9]
Nasir, N. A. A. M., Ibrahim, Z. B., Othman, K. I. and Suleiman, M. 2012. Numerical solution of first order stiff ordinary differential equations using fifth order block backward differentiation formulas. Sains Malaysiana, 41, 4, 489--492.
[10]
Nasir, N. A. A. M., Ibrahim, Z. B., Suleiman, M., Othman, K. I. and Rahim, Y. F. 2012. Numerical solution of tumor-immune interaction using 2-point block backward differentiation method. Int. J. Mod. Phys. Conf. Ser., 9, 278--284.
[11]
Cengel, Y. A. and Palm III, W. J. 2013. Differential Equations for Engineers and Scientists. New York: McGraw-Hill.
[12]
Mansor, N. A., Nusi, N. M. and Baharudin, S. 2017. Differential Equations. Oxford Fajar.
Index Terms
- Transient Analysis of Electrical Circuits using Block Backward Differentiation Formula
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Published In
March 2020
138 pages
ISBN:9781450376891
DOI:10.1145/3386762
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Published: 29 May 2020
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IEEA 2020
IEEA 2020: 2020 The 9th International Conference on Informatics, Environment, Energy and Applications
March 13 - 16, 2020
Amsterdam, Netherlands
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View all- Öncü SÜnal KTunçer U(2020)D Sınıfı Eviricinin Runge-Kutta Metodu ile Analizinin YapılmasıAcademic Perspective Procedia10.33793/acperpro.03.01.663:1(337-345)Online publication date: 25-Oct-2020
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