AbstractA factorization method is constructed for sequences of second-order linear difference equations in analogy with the factorization method for differential equations. Six factorization types are established and recursion relations are obtained for various classes of special functions, among which are the hypergeometric functions and their limits, and the classical polynomials of a discrete variable: Tchebycheff, Krawtchouk, Charlier, Meixner, and Hahn. It is shown that the factorization method is a disguised form of Lie algebra representation theory
Intended for researchers, numerical analysts, and graduate students in various fields of applied mat...
AbstractThe linear difference equation of the nth order with variable coefficients and a related dif...
An equivalence problem is solved completely for a linear system of two second-order ordinary differe...
AbstractA factorization method is constructed for sequences of second-order linear difference equati...
AbstractThe factorization method for systems of linear difference equations is shown to be related t...
AbstractA brief review on the recent results of nonlinear differential-difference and difference equ...
Lie symmetries has been introduced by Sophus Lie to study differential equations. It has been one of...
AbstractWe apply general difference calculus in order to obtain solutions to the functional equation...
AbstractBy solving an infinite nonlinear system of q-difference equations one constructs a chain of ...
Despite the fact that Sophus Lie's theory was virtually the only systematic method for solving nonli...
THE DIFFERENCE CALCULUS GENESIS OF DIFFERENCE EQUATIONS DEFINITIONS DERIVATION OF DIFFERENCE EQUATIO...
AbstractWe consider a large class of sequences which are defined by systems of (possibly nonlinear) ...
Difference equations are the discrete analogs to differential equations. While the independent varia...
AbstractIn this paper, we indicate necessary and sufficient conditions for factorization of the diff...
It is known that every solution to the second-order difference equation x(n) = x(n-1) + x(n-2) = 0, ...
Intended for researchers, numerical analysts, and graduate students in various fields of applied mat...
AbstractThe linear difference equation of the nth order with variable coefficients and a related dif...
An equivalence problem is solved completely for a linear system of two second-order ordinary differe...
AbstractA factorization method is constructed for sequences of second-order linear difference equati...
AbstractThe factorization method for systems of linear difference equations is shown to be related t...
AbstractA brief review on the recent results of nonlinear differential-difference and difference equ...
Lie symmetries has been introduced by Sophus Lie to study differential equations. It has been one of...
AbstractWe apply general difference calculus in order to obtain solutions to the functional equation...
AbstractBy solving an infinite nonlinear system of q-difference equations one constructs a chain of ...
Despite the fact that Sophus Lie's theory was virtually the only systematic method for solving nonli...
THE DIFFERENCE CALCULUS GENESIS OF DIFFERENCE EQUATIONS DEFINITIONS DERIVATION OF DIFFERENCE EQUATIO...
AbstractWe consider a large class of sequences which are defined by systems of (possibly nonlinear) ...
Difference equations are the discrete analogs to differential equations. While the independent varia...
AbstractIn this paper, we indicate necessary and sufficient conditions for factorization of the diff...
It is known that every solution to the second-order difference equation x(n) = x(n-1) + x(n-2) = 0, ...
Intended for researchers, numerical analysts, and graduate students in various fields of applied mat...
AbstractThe linear difference equation of the nth order with variable coefficients and a related dif...
An equivalence problem is solved completely for a linear system of two second-order ordinary differe...