On the linking of number lattices

Abstract

In this paper we study ideas which have proved useful in topological network theory in the context of lattices of numbers. A number lattice LS is a collection of row vectors, over Q on a finite column set S, generated by integral linear combination of a finite set of row vectors. A generalized number lattice KS is the sum of a number lattice LS and a vector space VS which has only the zero vector in common with it. The dual KdS of a generalized number lattice is the collection of all vectors whose dot product with vectors in KS are integral and is another generalized number lattice. We consider a linking operation ('matched composition`) between generalized number lattices KSP,KP (regarded as collections of row vectors on column sets S P, P, respectively with S,P, disjoint) defined by KSP KP \fS:((fS,gP)∈ KSP, gP ∈ KP\. We show that this operation together with contraction and restriction, and the results, the implicit inversion theorem (which gives simple conditions for the equality KSP (KSP KS)= KS, to hold) and implicit duality theorem ((KSP KP)d= KSPd KPd)), are both relevant and useful in suggesting problems concerning number lattices and their solutions. Using the implicit duality theorem, we give simple methods of constructing new self dual lattices from old. We also give new and efficient algorithms for the following. Given VSP,KP, such that VSP (VSP KP)= KP, where VSP is a vector space with a totally unimodular basis matrix, to construct reduced bases for the number lattice part of VSP KP, KPd, (VSP KP)d, from a reduced basis for the number lattice part of KP.