100 research outputs found
A discrete Bochner-Martinelli formula
In the even dimensional case the discrete Dirac equation may be reduced to the so-called discrete isotonic Dirac system in which suitable Dirac operators appear from both sides in half the dimension. This is an appropriated framework for the development of a discrete Martinelli-Bochner formula for discrete holomorphic functions on the simplest of all graphs, the rectangular Z(m) one. Two lower-dimensional cases are considered explicitly to illustrate the closed analogy with the theory of continuous variables and the developed discrete scheme
A note on the solvability of homogeneous Riemann boundary problem with infinity index
summary:In this note we establish a necessary and sufficient condition for solvability of the homogeneous Riemann boundary problem with infinity index on a rectifiable open curve. The index of the problem we deal with considers the influence of the requirement of the solutions of the problem, the degree of non-smoothness of the curve at the endpoints as well as the behavior of the coefficient at these points
Duality for Hermitean systems in R2n
In this paper, using the algebraic structure of the space of circulant (2 × 2) matrix, we characterize the dual of the (Frechet) space of germs of left Hermitean monogenic matrix functions in a compact set of Euclidean space with even di;ension. As an application we describe the dual space of the so-called h-monogenic functions satisfying simultaneously two Dirac type equations
A d-summable approach to Deng information dimension of complex networks
Several new network information dimension definitions have been proposed in
recent decades, expanding the scope of applicability of this seminal tool. This
paper proposes a new definition based on Deng entropy and d-summability (a
concept from geometric measure theory). We will prove to what extent the new
formulation will be useful in the theoretical and applied points of view
Generalized Moisil-Théodoresco systems and Cauchy integral decompositions
Let ℝ0,m+1(s) be the space of s-vectors (0≤s≤m+1) in the Clifford algebra ℝ0,m+1 constructed over the quadratic vector space ℝ0,m+1, let r,p,q∈ℕ with 0≤r≤m+1, 0≤p≤q, and r+2q≤m+1, and let ℝ0,m+1(r,p,q)=∑j=pq⨁ ℝ0,m+1(r+2j). Then, an ℝ0,m+1(r,p,q)-valued smooth function W defined in an open subset Ω⊂ℝm+1 is said to satisfy the generalized Moisil-Théodoresco system of type (r,p,q) if ∂xW=0 in Ω, where ∂x is the Dirac operator in ℝm+1. A structure theorem is proved for such functions, based on the construction of conjugate harmonic pairs. Furthermore, if Ω is bounded with boundary Γ, where Γ is an Ahlfors-David regular surface, and if W is a ℝ0,m+1(r,p,q)-valued Hölder continuous function on Γ, then necessary and sufficient conditions are given under which W admits on Γ a Cauchy integral decomposition W=W++W−
Higher order Borel–Pompeiu representations in Clifford analysis
In this paper, we show that a higher order Borel–Pompeiu (Cauchy–Pompeiu) formula, associated with an arbitrary orthogonal basis (called structural set) of a Euclidean space, can be extended to the framework of generalized Clifford analysis. Furthermore, in lower dimensional cases, as well as for combinations of standard structural sets, explicit expressions of the kernel functions are derived
Higher order Borel-Pompeiu representations
We establish a higher order Borel-Pompeiu formula for monogenic functions associated to an arbitrary orthogonal basis (called structural set) of Euclidean space, or combinations of such structural sets
A quaternionic fractional Borel-Pompeiu type formula
Quaternionic analysis relies heavily on results on functions defined on
domains in (or ) with values in . This
theory is centered around the concept of hyperholomorphic functions
i.e., null-solutions of the Fueter operator related to a so-called
structural set of . Fractional calculus, involving
derivatives-integrals of arbitrary real or complex order, is the natural
generalization of the classical calculus, which in the latter years became a
well-suited tool by many researchers working in several branches of science and
engineering. In theoretical setting, associated with a fractional Fueter
operator that depends on an additional vector of complex parameters with
fractional real parts, this paper establishes a fractional analogue of
Borel-Pompeiu formula as a first step to develop a fractional
hyperholomorphic function theory and the related operator calculus
A quaternionic proportional fractional Fueter-type operator calculus
The main goal of this paper is to construct a proportional analogues of the
quaternionic fractional Fueter-type operator recently introduced in the
literature. We start by establishing a quaternionic version of the well-known
proportional fractional integral and derivative with respect to a real-valued
function via the Riemann-Liouville fractional derivative. As a main result, we
prove a quaternionic proportional fractional Borel-Pompeiu formula based on a
quaternionic proportional fractional Stokes formula. This tool in hand allows
us to present a Cauchy integral type formula for the introduced quaternionic
proportional fractional Fueter-type operator with respect to a real-valued
function.Comment: 20 page
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