English

Second Order Transfer Equations; and Generalizations to Arbitrary Orders

Complex Variables 2021-03-18 v1 Dynamical Systems

Abstract

The author provides a solution to the equation y(s+2)=T2y=F(s,y,Ty)=F(s,y(s),y(s+1)) y(s+2) = \mathcal{T}^2 y = F(s,y,\mathcal{T} y) = F(s,y(s),y(s+1)); where yy is holomorphic; and FF is a holomorphic function with specific decay conditions. This result is provided using infinite compositions, and a limiting process. The technique is generalized to arbitrary kk'th order transfer equations: u(s+k)=F(s,u(s),u(s+1),...,u(s+k1))u(s+k) = F(s,u(s),u(s+1),...,u(s+k-1)). The technique is derived by utilizing solutions w(s+1)=Tw=F(s,w)w(s+1) = \mathcal{T} w = F(s,w) and sequentially approximating uu, or yy, with a sequence of said ww.

Keywords

Cite

@article{arxiv.2103.09292,
  title  = {Second Order Transfer Equations; and Generalizations to Arbitrary Orders},
  author = {James David Nixon},
  journal= {arXiv preprint arXiv:2103.09292},
  year   = {2021}
}
R2 v1 2026-06-24T00:15:06.359Z