Order symmetry and orthogonality of trajectories in discrete interval exchange transformations

Abstract

Let π=(<D,<A) be a pair of distinct orders on a k-letter alphabet A. The periodic trajectories vi∞ of a discrete k-interval exchange transformations T with permutation π are characterized by the following order symmetry : viω<D vjω (lexicographically) if and only if vi-ω<Avj-ω (reverse lexicographically). For general words u and v over A, the orders need not agree in which case either uω<A vω<D uω (Type 1) or vω<A uω<D vω (Type 2). We partition all such order crossings amongst the set of conjugates of two words u and v into disjoint families T1(u,v) and T2(u,v) and define the index i(u,v) by |T1(u,v)|+|T2(u,v)|. Remarkably the difference, |T2(u,v)|-|T1(u,v)|, depends only on the Parikh vectors λ(u) and λ(v). We show that |T2(u,v)|-|T1(u,v)|=λ(u)T Ωλ(v) where Ω is a k× k skew symmetric matrix depending only on π. It follows that the Parikh vectors of the trajectories of a discrete interval exchange are orthogonal with respect to Ω. Applied to dimension 3, we obtain an arithmetic formula for the number of orbits in a discrete 3-interval exchange and hence a characterization of minimality. For general k, the orthogonality of the trajectories gives an upper bound k+d2 on the number of distinct trajectories where d= (Ω). If T is symmetric, then the number of distinct trajectories is at most k+12 . An alternate interpretation of this result is that on an ordered k-letter alphabet, there are at most k+12 primitive, pairwise non conjugate perfectly clustering words which perfectly cluster collectively in a single array in which all their conjugates are arranged in increasing order.

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