سولیتون های نوری و جواب های دیگر معادله کوندو-موکرجی-ناسکار دوبعدی
محورهای موضوعی : آمارکامیار حسینی 1 , ماشااله متین فر 2 , محمد میرزازاده 3
1 - گروه ریاضی، دانشکده علوم ریاضی، دانشگاه مازندران، بابلسر، ایران
2 - گروه ریاضی، دانشکده علوم ریاضی، دانشگاه مازندران، بابلسر، ایران
3 - گروه علوم مهندسی، دانشگاه گیلان، شرق گیلان، واجارگاه، ایران
کلید واژه: (2+1)-dimensional Kundu-Mukherjee-Naskar equation, Traveling wave hypothesis, Exp_a and Jacobi elliptic function methods, Optical solitons and other solutions,
چکیده مقاله :
معادله کوندو-موکرجی-ناسکار دوبعدی توصیف کننده انتشار دینامیک سولیتون در سیستم های ارتباطی فیبر نوری در مقاله حاضر مطالعه می شود. هدف موردنظر با به کارگیری یک تبدیل موج حرکتی برای کاهش معادله کوندو-موکرجی-ناسکار دوبعدی به یک دامنه یک-بعدی و حل معادله دیفرانسیل معمولی غیرخطی حاصله با استفاده از روش های تابع نمایی و ضمنی ژاکوبی اجرایی می گردد. به عنوان یک موفقیت، سولیتون های نوری و جواب های دیگر معادله کوندو-موکرجی-ناسکار دوبعدی با تایید عملکرد فوق العاده روش های به کارگیری شده رسما استخراج می شوند.معادله کوندو-موکرجی-ناسکار دوبعدی توصیف کننده انتشار دینامیک سولیتون در سیستم های ارتباطی فیبر نوری در مقاله حاضر مطالعه می شود. هدف موردنظر با به کارگیری یک تبدیل موج حرکتی برای کاهش معادله کوندو-موکرجی-ناسکار دوبعدی به یک دامنه یک-بعدی و حل معادله دیفرانسیل معمولی غیرخطی حاصله با استفاده از روش های تابع نمایی و ضمنی ژاکوبی اجرایی می گردد. به عنوان یک موفقیت، سولیتون های نوری و جواب های دیگر معادله کوندو-موکرجی-ناسکار دوبعدی با تایید عملکرد فوق العاده روش های به کارگیری شده رسما استخراج می شوند.
The (2+1)-dimensional Kundu-Mukherjee-Naskar (2D-KMN) equation that addresses the propogation of soliton dynamics in optical fiber communication systems is investigated in the present paper. The intended purpose is accomplished by applying a traveling wave hypothesis for reducing the 2D-KMN equation in a 1-dimensional domain and solving the resulting ODE using the exp_a and Jacobi elliptic function methods. As an accomplishment, optical solitons and other solutions of the (2+1)-dimensional Kundu–Mukherjee–Naskar equation are extracted, confirming the outstanding performance of the methods.The (2+1)-dimensional Kundu-Mukherjee-Naskar (2D-KMN) equation that addresses the propogation of soliton dynamics in optical fiber communication systems is investigated in the present paper. The intended purpose is accomplished by applying a traveling wave hypothesis for reducing the 2D-KMN equation in a 1-dimensional domain and solving the resulting ODE using the exp_a and Jacobi elliptic function methods. As an accomplishment, optical solitons and other solutions of the (2+1)-dimensional Kundu–Mukherjee–Naskar equation are extracted, confirming the outstanding performance of the methods.
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