AbstractThis paper presents an operator calculus approach to computing with non-commutative variables. First, we recall the product formulation of formal exponential series. Then we show how to formulate canonical boson calculus on formal series. This calculus is used to represent the action of a Lie algebra on its universal enveloping algebra. As applications, Hamilton's equations for a general Hamiltonian, given as a formal series, are found using a double-dual representation, and a formulation of the exponential of the adjoint representation is given. With these techniques one can represent the Volterra product acting on the enveloping algebra. We illustrate with a three-step nilpotent Lie algebra
In this paper, formal exponential representations of the solutions to nonautonomous nonlinear differ...
AbstractIn this paper, we introduce the concepts of a formal function over an alphabet and a formal ...
We study densely defined unbounded operators acting between different Hilbert spaces. For these, we ...
AbstractThis paper presents an operator calculus approach to computing with non-commutative variable...
In nonlinear control, it is helpful to choose a formalism well suited to computations involving solu...
Given formal differential operators $F_i$ on polynomial algebrain several variables $x_1,...,x_n$, w...
This book provides explicit representations of finite-dimensional simple Lie algebras, related parti...
Abstract. Given formal differential operators Fi on polynomial algebra in several variables x1,..., ...
Pseudodifferential operators are formal Laurent series in the formal inverse ∂−1 of the derivative o...
AbstractA standard way of realizing a Lie algebra is as a family of vector fields closed under commu...
Summary. In this paper we define the algebra of formal power series and the algebra of polynomials o...
AbstractWe prove that the logarithm of the formal power series, obtained from a stochastic different...
AbstractIn this paper, we study the generalization of Hankel-like results for formal pseudo-differen...
We treat the problem of normally ordering expressions involving the standard boson operators a, a* w...
AbstractGiven an n-dimensional Lie algebra g over a field k⊃Q, together with its vector space basis ...
In this paper, formal exponential representations of the solutions to nonautonomous nonlinear differ...
AbstractIn this paper, we introduce the concepts of a formal function over an alphabet and a formal ...
We study densely defined unbounded operators acting between different Hilbert spaces. For these, we ...
AbstractThis paper presents an operator calculus approach to computing with non-commutative variable...
In nonlinear control, it is helpful to choose a formalism well suited to computations involving solu...
Given formal differential operators $F_i$ on polynomial algebrain several variables $x_1,...,x_n$, w...
This book provides explicit representations of finite-dimensional simple Lie algebras, related parti...
Abstract. Given formal differential operators Fi on polynomial algebra in several variables x1,..., ...
Pseudodifferential operators are formal Laurent series in the formal inverse ∂−1 of the derivative o...
AbstractA standard way of realizing a Lie algebra is as a family of vector fields closed under commu...
Summary. In this paper we define the algebra of formal power series and the algebra of polynomials o...
AbstractWe prove that the logarithm of the formal power series, obtained from a stochastic different...
AbstractIn this paper, we study the generalization of Hankel-like results for formal pseudo-differen...
We treat the problem of normally ordering expressions involving the standard boson operators a, a* w...
AbstractGiven an n-dimensional Lie algebra g over a field k⊃Q, together with its vector space basis ...
In this paper, formal exponential representations of the solutions to nonautonomous nonlinear differ...
AbstractIn this paper, we introduce the concepts of a formal function over an alphabet and a formal ...
We study densely defined unbounded operators acting between different Hilbert spaces. For these, we ...