A Higher-Order Calculus for Graph Transformation

## Abstract In coordinate‐transformation‐based approaches to electromagnetic concealment (“cloaking”) of objects, use of higher‐order (quadratic) mappings has been proposed as an effective device to obtain satisfactory responses without the use of magnetic materials that are complicated to synthesi

We consider the higher-order Fierz transformation, which corresponds to expanding a product of ψ ψ terms into a sum of products of Dirac densities and currents. It is shown that the Fierz transformation can be obtained by solving a large system of linear equations with fractional complex coefficient

Chen CC., K.M. Koh and Y.H. Peng, On the higher-order edge toughness of a graph, Discrete Mathematics 111 (1993) 113-123. For an integer c, 1 <c < 1 V(G) I-1, we define the cth-order edye toughness of a graph G as The objective of this paper is to study this generalized concept of edge toughness.

## Abstract We present a stabilized numerical formulation for incompressible continua based on a higher‐order Finite Calculus (FIC) approach and the finite element method. The focus of the paper is on the derivation of a stabilized form for the mass balance (incompressibility) equation. The simpler