Stability, bifurcation, chaotic pattern, phase portrait and exact solutions of a class of semi-linear Schrödinger equations with Kudryashov’s power law self-phase modulation and multiplicative white noise based on Stratonvich’s calculus

doi:10.1088/1674-1056/ade664

中国物理B ›› 2025, Vol. 34 ›› Issue (12): 124205-124205.doi: 10.1088/1674-1056/ade664

• • 上一篇

Stability, bifurcation, chaotic pattern, phase portrait and exact solutions of a class of semi-linear Schrödinger equations with Kudryashov’s power law self-phase modulation and multiplicative white noise based on Stratonvich’s calculus

Cheng-Qiang Wang(王成强)^1,†, Xiang-Qing Zhao(赵向青)¹, Yu-Lin Zhang(张玉林)², and Zhi-Wei Lv(吕志伟)¹

1 School of Mathematics and Physics, Suqian University, Suqian 223800, China;
2 School of Mathematics, Chengdu Normal University, Chengdu 611130, China

收稿日期:2025-03-13 修回日期:2025-05-30 接受日期:2025-06-20 发布日期:2025-11-25
通讯作者: Cheng-Qiang Wang E-mail:chengqiangwang2022@foxmail.com
基金资助:
Chengqiang Wang is partially supported by Qing Lan Project of Jiangsu, Suqian Sci. & Tech. Program (Grant Nos. Z2023131 and M202206), the Startup Foundation for Newly Recruited Employees, the Xichu Talents Foundation of Suqian University (Grant No. 2022XRC033), and the National Natural Science Foundation of China (Grant No. 11701050).

Stability, bifurcation, chaotic pattern, phase portrait and exact solutions of a class of semi-linear Schrödinger equations with Kudryashov’s power law self-phase modulation and multiplicative white noise based on Stratonvich’s calculus

Cheng-Qiang Wang(王成强)^1,†, Xiang-Qing Zhao(赵向青)¹, Yu-Lin Zhang(张玉林)², and Zhi-Wei Lv(吕志伟)¹

1 School of Mathematics and Physics, Suqian University, Suqian 223800, China;
2 School of Mathematics, Chengdu Normal University, Chengdu 611130, China

Received:2025-03-13 Revised:2025-05-30 Accepted:2025-06-20 Published:2025-11-25
Contact: Cheng-Qiang Wang E-mail:chengqiangwang2022@foxmail.com
About author:2025-124205-250415.pdf
Supported by:
Chengqiang Wang is partially supported by Qing Lan Project of Jiangsu, Suqian Sci. & Tech. Program (Grant Nos. Z2023131 and M202206), the Startup Foundation for Newly Recruited Employees, the Xichu Talents Foundation of Suqian University (Grant No. 2022XRC033), and the National Natural Science Foundation of China (Grant No. 11701050).

摘要/Abstract

摘要： We devote ourselves to finding exact solutions (including perturbed soliton solutions) to a class of semi-linear Schrödinger equations incorporating Kudryashov's self-phase modulation subject to stochastic perturbations described by multiplicative white noise based on Stratonvich's calculus. By borrowing ideas of the sub-equation method and utilizing a series of changes of variables, we transform the problem of identifying exact solutions into the task of analyzing the dynamical behaviors of an auxiliary planar Hamiltonian dynamical system. We determine the equilibrium points of the introduced auxiliary Hamiltonian system and analyze their Lyapunov stability. Additionally, we conduct a brief bifurcation analysis and a preliminary chaos analysis of the auxiliary Hamiltonian system, assessing their impact on the Lyapunov stability. Based on the insights gained from investigating the dynamics of the introduced auxiliary Hamiltonian system, we discover `all' of the exact solutions to the stochastic semi-linear Schrödinger equations under consideration. We obtain explicit formulas for exact solutions by examining the phase portrait of the introduced auxiliary Hamiltonian system. The obtained exact solutions include singular and periodic solutions, as well as perturbed bright and dark solitons. For each type of obtained exact solution, we pick one representative to plot its graph, so as to visually display our theoretical results. Compared with other methods for finding exact solutions to deterministic or stochastic partial differential equations, the dynamical system approach has the merit of yielding all possible exact solutions. The stochastic semi-linear Schrödinger equation under consideration can be used to portray the propagation of pulses in an optical fiber, so our study therefore lays the foundation for discovering new solitons optimized for optical communication and contributes to the improvement of optical technologies.

关键词: stochastic semi-linear Schrödinger equations, self-phase modulation, soliton solutions, Stratonvich’s calculus

Abstract: We devote ourselves to finding exact solutions (including perturbed soliton solutions) to a class of semi-linear Schrödinger equations incorporating Kudryashov's self-phase modulation subject to stochastic perturbations described by multiplicative white noise based on Stratonvich's calculus. By borrowing ideas of the sub-equation method and utilizing a series of changes of variables, we transform the problem of identifying exact solutions into the task of analyzing the dynamical behaviors of an auxiliary planar Hamiltonian dynamical system. We determine the equilibrium points of the introduced auxiliary Hamiltonian system and analyze their Lyapunov stability. Additionally, we conduct a brief bifurcation analysis and a preliminary chaos analysis of the auxiliary Hamiltonian system, assessing their impact on the Lyapunov stability. Based on the insights gained from investigating the dynamics of the introduced auxiliary Hamiltonian system, we discover `all' of the exact solutions to the stochastic semi-linear Schrödinger equations under consideration. We obtain explicit formulas for exact solutions by examining the phase portrait of the introduced auxiliary Hamiltonian system. The obtained exact solutions include singular and periodic solutions, as well as perturbed bright and dark solitons. For each type of obtained exact solution, we pick one representative to plot its graph, so as to visually display our theoretical results. Compared with other methods for finding exact solutions to deterministic or stochastic partial differential equations, the dynamical system approach has the merit of yielding all possible exact solutions. The stochastic semi-linear Schrödinger equation under consideration can be used to portray the propagation of pulses in an optical fiber, so our study therefore lays the foundation for discovering new solitons optimized for optical communication and contributes to the improvement of optical technologies.

Key words: stochastic semi-linear Schrödinger equations, self-phase modulation, soliton solutions, Stratonvich’s calculus

中图分类号: (Optical solitons; nonlinear guided waves)

42.65.Tg

42.65.Sf (Dynamics of nonlinear optical systems; optical instabilities, optical chaos and complexity, and optical spatio-temporal dynamics)

Cheng-Qiang Wang(王成强), Xiang-Qing Zhao(赵向青), Yu-Lin Zhang(张玉林), and Zhi-Wei Lv(吕志伟). Stability, bifurcation, chaotic pattern, phase portrait and exact solutions of a class of semi-linear Schrödinger equations with Kudryashov’s power law self-phase modulation and multiplicative white noise based on Stratonvich’s calculus[J]. 中国物理B, 2025, 34(12): 124205-124205.

参考文献

[1] Yang Y Q, Yan Z Y and Malomed B A 2015 Chaos 25 103112
[2] Kudryashov N A 2021 Mathematics 9 3024
[3] Ma W X, Osman M S, Arshed S, Raza N and Srivastava H M 2021 Chin. J. Phys. 72 475
[4] Kudryashov N A 2020 Optik 206 164335
[5] Wang T Y, Zhou Q and Liu W J 2022 Chin. Phys. B 31 020501
[6] Zhang Y F, Wang H F and Bai N 2022 Acta Math. Appl. Sin. 38 579
[7] Mirzazadeh M, Hashemi M S, Akbulu A, Rehman H U, Iqbal I and Eslami M 2024 Math. Methods Appl. Sci. 47 5355
[8] Yildirim Y and Biswas A 2024 Phys. Lett. A 527 129998
[9] Arnous A H, Murad M A S, Biswas A and Yildirim Y 2025 Ain Shams Eng. J. 16 103243
[10] Zayed E M E, El-Shater M, Elsherbeny A M, Arnous A H, Biswas A, Yildirim Y, et al. 2025 Ain Shams Eng. J. 16 103260
[11] Zhou Y Q, Liu Q, Zhang J and Zhang W N 2006 Appl. Math. Comput. 177 495
[12] Zhou Y Q, Liu Q and Zhang W N 2011 Nonlinear Anal. 74 1047
[13] Kumara S and Kumar A 2022 Math. Comput. Simul. 201 254
[14] Li Y, Hao X Z, Yao R X, Xia Y R and Shen Y L 2023 Math. Comput. Simul. 208 57
[15] Ashraf M A, Seadawy A R, Rizvi S T R and Althobaiti A 2024 Opt. Quant. Electron. 56 1243
[16] Li Z and Liu C Y 2024 Results Phys. 56 107305
[17] Zayed E M E, Nofal T A, Alngar M E M and El-Horbaty M M 2021 Optik 231 166381
[18] Zhou Q, Huang Z H, Sun Y Z, Triki H, Liu W J and Biswas A 2022 Nonlinear Dynam. 111 5757
[19] Zayed E M E, Gepreel K A and El-Horbaty M 2023 Optik 286 170975
[20] Zayed E M E, Shohib R M A and Alngar M E M 2023 Optik 278 170736
[21] Zayed E M E and Alngar M E M 2021 Optik 227 166099
[22] Kudryashov N A 2022 Optik 259 168975
[23] Secer A 2022 Optik 268 169831
[24] Yildirim Y, Biswas A and Alshehri H M 2022 Optik 264 169336
[25] Zayed E M E, Alngar M E M, Shohib R M A, Biswas A, Yildirim Y, Alshomrani A S and Alshehri H M 2022 Optik 264 169369
[26] Zhou Q, Sun Y Z, Triki H, Zhong Y, Zeng Z L and MirzazadehM2022 Results Phys. 41 105898
[27] AlQahtani S A, Alngar M E M, Shohib R M A and Pathak P 2023 Chaos Solitons Fract. 171 113498
[28] Chen D and Li Z 2023 Optik 277 170687
[29] Cakicioglu H, Ozisik M, Secer A and Bayram M 2023 Optik 279 170776
[30] Li R J, Sinnah Z A B, Shatouri Z M, Manafian J, Aghdaei M F and Kadi A 2023 Results Phys. 46 106293
[31] Akram G, Sadaf M and Khan M A U 2023 Math. Comput. Simul. 206 1
[32] El-Ganainia S and Kumarb S 2023 Math. Comput. Simul. 208 28
[33] Izgi Z P 2023 Math. Comput. Simul. 208 535
[34] Butt A R, Umair M and Basendwah G A 2024 Optik 308 171801
[35] Lu T X, Tang L, Chen Y L and Chen C W 2024 Results Phys. 60 107679
[36] Khan M I, Farooq A, Nisar K S and Shah N A 2024 Results Phys. 59 107593
[37] MuradMA S, Ismael H F, Sulaiman T A and Bulut H 2024 Opt. Quant. Electron. 56 76
[38] Trouba N T, Alngar M E M, Mahmoud H A and Shohib R M A 2024 Ain Shams Eng. J. 15 103117
[39] Wazwaz A M 2024 Ukr. J. Phys. Opt. 25 S1131
[40] Liu L, Zhou X X, Xie X Y and Sun W R 2025 Math. Comput. Simul. 228 466
[41] Yao Y L, Yi H H, Zhang X and Ma G L 2023 Chin. Phys.. Lett. 40 100503
[42] Zhang X F, Xu T, Li M and Meng Y 2023 Chin. Phys.. B 32 010505
[43] Yuan R R, Shi Y, Zhao S L and Wang W Z 2024 Chaos Solitons Fract. 181 114709
[44] Zayed E M E, Alurrfi K A E, Hasek A M M, Arar N, Arnous A H and Yildirim Y 2024 Phys. Scr. 99 095220
[45] Zayed E M E, Arnous A H, Secer A, Ozisik M, Bayram M, Shah N A and Chung J D 2024 Results Phys. 58 107439
[46] Wang C Q, Zhao X Q, Mai Q Y and Lv Z W 2025 Phys. Scr. 100 025257
[47] Chahlaoui Y, Shohib R M A and Alngar M E M 2024 Opt. Quant. Electron. 56 1108
[48] Yi X Q, Zhou Y Q, Liu Q, Li K B and Zhang S N 2025 Qual. Theory Dyn. Syst. 24 55
[49] Arshed S, Raza N and Alansari M 2021 Ain Shams Eng. J. 12 3091
[50] Liu H D, Tian B, Gao X T, Shan HWand Ma J Y 2025 Nonlinear Dyn. 113 12057
[51] Rehman H U, Aljohani A F, Althobaiti A, Althobaiti S and Iqbal I 2024 Opt. Quantum Electron. 56 1336
[52] Kloeden P E and Platen E 1992 Numerical Solution of Stochastic Differential Equations (Heidelberg: Springer Berlin) pp. 305
[53] Al-Askar F M 2023 Results Phys. 52 106784
[54] Fan E G 2002 J. Phys. A Math. Gen. 35 6853
[55] Wazwaz A-M 2004 Appl. Math. Comput. 154 713
[56] El-Wakil S A and Abdou M A 2007 Chaos Solitons Fract. 31 840
[57] Wang M L, Li X Z and Zhang J L 2008 Phys. Lett. A 372 417
[58] Zayed E M E and Gepreel K A 2009 J. Math. Phys. 50 013502
[59] Liu C S 2010 Comput. Phys. Commun. 181 317
[60] Li L X, Li E Q and Wang M L 2010 Appl. Math. J. Chin. Univ. 25 454
[61] Srivastava H, Baleanu D, Machado J A T, Osman M S, Rezazadeh H, Arshed S and Günerhan H 2020 Phys. Scr. 95 075217
[62] Tang L, Biswas A and Yildirim Y 2023 Contemp. Math. 4 981
[63] Wang C Q, Zhao X Q, Mai Q Y and Lv Z W 2024 Fractal Fract. 8 83
[64] Rahman M U, Sun M, Boulaaras S and Baleanu D 2024 Bound. Value Probl. 2024 15
[65] Wang C Q, Zhao X Q, Zhang Y L and Lv Z W 2023 Entropy 25 359
[66] Perko L 2001 Differential Equations and Dynamical Systems 3rd Edn. (New York: Springer) pp. 119-127
[67] Liu X M, Zhang Z Y and Liu W J 2023 Chin. Phys. Lett. 40 070501

Stability, bifurcation, chaotic pattern, phase portrait and exact solutions of a class of semi-linear Schrödinger equations with Kudryashov’s power law self-phase modulation and multiplicative white noise based on Stratonvich’s calculus

Stability, bifurcation, chaotic pattern, phase portrait and exact solutions of a class of semi-linear Schrödinger equations with Kudryashov’s power law self-phase modulation and multiplicative white noise based on Stratonvich’s calculus

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