РУАЭСТ (RUAEST)
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2011 год объявлен Годом космонавтики
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СТРУКТУРНО-ФУНКЦИОНАЛЬНАЯ МОДЕЛЬ ФОРМИРОВАНИЯ ПРОФЕССИОНАЛЬНО-ЛИЧНОСТНОГО САМОРАЗВИТИЯ ПОДХОДЫ, ПРИНЦИПЫ, КОМПОНЕНТЫ И УСЛОВИЯ
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Проект "Ямал-400" стартовал
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ВОЗМОЖНОСТИ СОЦИАЛИЗАЦИИ И РЕСОЦИАЛИЗАЦИИ НЕСОВЕРШЕННОЛЕТНИХ, НАХОДЯЩИХСЯ В КОНФЛИКТЕ С ЗАКОНОМ, В УСЛОВИЯХ СПЕЦИАЛЬНО ОРГАНИЗОВАННОЙ ВОСПИТАТЕЛЬНОЙ СРЕДЫ (НА ПРИМЕРЕ БРИГАДИРОВ СПЕЦИАЛЬНОГО ПРЕДПРИЯТИЯ «НОВОЕ ПОКОЛЕНИЕ»)
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The Derivation of the Dispersion Equations of Adiabatic Waveguide Modes in the Thin-Film Waveguide Luneburg Lens in the Form of Non-Linear Partial Differential Equation of the First Order
The Derivation of the Dispersion Equations of Adiabatic Waveguide Modes in the Thin-Film Waveguide Luneburg Lens in the Form of Non-Linear Partial Differential Equation of the First Order
This paper presents a derivation of the dispersion equation for a three-layer integratedoptical Luneburg lens based on the method of adiabatic waveguide modes. From this equation there follows the relationship between the coefifcient of phase deceleration and function, which determines the thickness of the irregular waveguide layer. The dispersion equation is represented in the form of non-linear partial differential equation of the first order with coefifcients, depending on parameters. Among these parameters are regular waveguide layer thickness and optical parameters of the pending Luneburg lens. To represent the dispersion equation in the form of differential equations in partial derivatives, it is necessary to calculate a symbolic form the determinant of a matrix of 12th order, which determines the solubility of the system of linear algebraic equations, resulting from the boundary conditions. To calculate this determinant in analytical form a procedure of reduction of the system of linear algebraic equations with the use of the computer algebra system Maple is proposed.