(Kink; Kink; Kink; Kink) and (Pulse; Pulse; Pulse; Pulse) Solutions of a Set of Four Equations Modeled in a Nonlinear Hybrid Electrical Line with Crosslink Capacitor

Tiague Takongmo Guy; Jean Roger Bogning

doi:10.9734/psij/2019/v22i430135

Submit Manuscript

Subscription

(Kink; Kink; Kink; Kink) and (Pulse; Pulse; Pulse; Pulse) Solutions of a Set of Four Equations Modeled in a Nonlinear Hybrid Electrical Line with Crosslink Capacitor

Tiague Takongmo Guy

Jean Roger Bogning

Physical Science International Journal, Page 1-14
DOI: 10.9734/psij/2019/v22i430135
Published: 18 July 2019

Abstract

The physics system that helps us in the study of this paper is a nonlinear hybrid electrical line with crosslink capacitor. Meaning it is composed of two different nonlinear hybrid parts Linked by capacitors with identical constant capacitance. We apply Kirchhoff laws to the circuit of the line to obtain new set of four nonlinear partial differential equations which describe the simultaneous dynamics of four solitary waves. Furthermore, we apply efficient mathematical methods based on the identification of coefficients of basic hyperbolic functions to construct exact solutions of those set of four nonlinear partial differential equations. The obtained results have enabled us to discover that, one of the two nonlinear hybrid electrical line with crosslink capacitor that we have modeled accepts the simultaneous propagation of a set of four solitary waves of type (Pulse; Pulse; Pulse; Pulse), while the other accepts the simultaneous propagation of a set of four solitary waves of type (Kink; Kink; Kink; Kink) when certain conditions we have established are respected. We ameliorate the quality of the signals by changing the sinusoidal waves that are supposed to propagate in the hybrid electrical lines with crosslink capacitor to solitary waves which are propagating in the new nonlinear hybrid electrical lines; we therefore, facilitate the choice of the type of line relative to the type of signal that we want to transmit.

Keywords:

Hybrid electrical line
crosslink capacitor
construction
solitons solution
solitary wave
nonlinear partial differential equation
kink
pulse

How to Cite

Guy, T. T., & Bogning, J. R. (2019). (Kink; Kink; Kink; Kink) and (Pulse; Pulse; Pulse; Pulse) Solutions of a Set of Four Equations Modeled in a Nonlinear Hybrid Electrical Line with Crosslink Capacitor. Physical Science International Journal, 22(4), 1-14. https://doi.org/10.9734/psij/2019/v22i430135

References

Rossi JO, Rizzo PN. Study of hybrid nonlinear transmission lines for high power RF generation. Proc. of 17th IEEE Int. Pulsed Power Conf. Washington, DC. 2009;46-50.

Rossi JO, Rizzo PN, Yamasaki FS. Prospects for applications of hybrid lines in RF generation. Proc. of 2010 IEEE Int. Power Modulator and High Voltage Conf. Atlanta, GA. 2010;632-635.

Wazwaz AM. A reliable treatment of the physical structure for the nonlinear equation K (m,n), Appl. Math. Comput. 2005;163:1081-1095.

Ekici M, Zhou Q, Sonmezoglu A, Moshokoa SP, Zaka Ullah M, Biswas A, Belic M. Solitons in magneto-optic waveguides by extended trial function scheme. Superlattices Microstruct. 2017c; 107:197–218.

Jawad AJM, Mirzazadeh M, Zhou Q, Biswas A. Optical solitons with anti-cubic nonlinearity using three integration schemes. Superlattices Microstruct. 2017; 105:1–10.

Mirzazadeh M, Ekici M, Sonmezoglu A, Eslami M, Zhou Q, Kara AH, Milovic D, Majid FB, Biswas A, Belic M. Optical solitons with complex Ginzburg–Landau equation. Nonlinear Dyn. 2016;85(3): 1979–2016.

Seadawy AR, Lu D. Bright and dark solitary wave soliton solutions for the generalized higher order nonlinear Schrodinger equation and its stability. Results Phys. 2017;7:43–48.

Wang ML. Exact solutions for a compound Käv- Burgers equation, Phys. Lett. A. 1996;213:279-287.

Fan E. Extended tanh-function method and its applications to nonlinear equations, Phys. Lett. A. 2000;277:212-218.

Fan E, Zhang J. A note on the homogeneous balance method, Phys. Lett. A. 2002;305:383-392.

Zhou YB, Wang ML, Wang YM. Periodic wave solutions to a coupled KdV equations with variable coefficients, Phys. Lett. A. 2003;308:31-37

Wazwaz AM. Solutions of compact and non compact structures for nonlinear Klein-Gordon type equation, Appl. Math. Comput. 2003;134:487-500.

Wazwaz AM. Traveling wave solutions of generalized forms of Burgers – KdV and Burgers Huxly equations, Appl. Math. Comput. 2005;169:639-656.

Feng Z. The first integral method to study the Burgers – Korteweg-de-Vries equation, J. Phys. Lett. A. 2002;35:343-349.

Feng Z. On explicit exat solutions for the Lienard equation and its applications, J. Phys. Lett. A. 2002;293:57-66.

Feng Z. On explicit exact solutions to compound Burgers- KdV equation, J. Math. Anal. Appl. 2007;328:1435-1450

Bogning JR, CT Djeumen Tchaho CT,. Kofané TC. Construction of the soliton solutions of the Ginzburg-Landau equations by the new Bogning-Djeumen Tchaho-Kofané method. Phys. Scr. 2012; 85:025013-025017.

Bogning JR, CT Djeumen Tchaho CT, Kofané TC. Generalization of the Bogning- Djeumen Tchaho-Kofane method for the construction of the solitary waves and the survey of the instabilities. Far East J. Dyn. Sys. 2012;20(2):101-119.

Djeumen Tchaho CT, Bogning JR, Kofané TC. Modulated soliton solution of the modified Kuramoto-Sivashinsky's equation. American Journal of Computational and Applied Mathematics. 2012;2(5):218-224.

Djeumen Tchaho CT, Bogning JR, Kofane TC. Multi-soliton solutions of the modified Kuramoto-Sivashinsky’s equation by the BDK method. Far East J. Dyn. Sys. 2011; 15(2):83-98.

Djeumen Tchaho CT, Bogning JR, Kofane TC. Construction of the analytical solitary wave solutions of modified Kuramoto-Sivashinsky equation by the method of identification of coefficients of the hyperbolic functions. Far East J. Dyn. Sys. 2010;14(1):14-17.

Bogning JR. Pulse soliton solutions of the modified KdV and born-infeld equations. International Journal of Modern Nonlinear Theory and Application. 2013;2:135-140.

1591 times
743 times

Download Statistics

Downloads

Download data is not yet available.