Eriksson’s numbers game and finite Coxeter groups

Abstract: The numbers game is a one-player game played on a finite simple graph with certain "amplitudes" assigned to its edges and with an initial assignment of real numbers to its nodes. The moves of the game successively transform the numbers at the nodes using the amplitudes in a certain way. This game and its interactions with Coxeter/Weyl group theory and Lie theory have been studied by many authors. In particular, Eriksson connects certain geometric representations of Coxeter groups with games on graphs with cert… Show more

“…In particular, the configuration v must converge to some limiting allowed configuration (which is zero on Γ ′ ), and one could continue the numbers game from this limit if desired. Note that, in the case that c ij = c ji for all odd n ij , we must also have α · v > −1 8 Also, this observation easily implies the main results (Theorems 2.1 and 4.1) of [DE08]: if vi ≤ 0 for all i and v = 0, then the usual numbers game can only terminate if Γ, C are associated to a finite Coxeter group: otherwise (assuming Γ is connected), infinitely many elements β ∈ ∆+ which are not multiples of each other satisfy β · v < 0: note that, for each i ∈ I, the set P(W αi) essentially does not depend on the choice of C for a given Coxeter group.…”

On dominance and minuscule Weyl group elements

“…In particular, the configuration v must converge to some limiting allowed configuration (which is zero on Γ ′ ), and one could continue the numbers game from this limit if desired. Note that, in the case that c ij = c ji for all odd n ij , we must also have α · v > −1 8 Also, this observation easily implies the main results (Theorems 2.1 and 4.1) of [DE08]: if vi ≤ 0 for all i and v = 0, then the usual numbers game can only terminate if Γ, C are associated to a finite Coxeter group: otherwise (assuming Γ is connected), infinitely many elements β ∈ ∆+ which are not multiples of each other satisfy β · v < 0: note that, for each i ∈ I, the set P(W αi) essentially does not depend on the choice of C for a given Coxeter group.…”

On dominance and minuscule Weyl group elements

“…Semistandard lattices [DW]; for a combinatorial description of the adjacency-free fundamental weights, see [Don6] We obtain, in a uniform way, splitting distributive lattices for the following (root system, dominant weight) pairs: (An, λ), where λ is any dominant weight; (Bn, aω 1 + bωn); (Cn, aω 1 + bωn); (Dn, aω 1 + bω n−1 + cωn); (E 6 , aω 1 + bω 6 ); (E 7 , aω 7 ); (G 2 , aω 1 + bω 2 ). The "KN" and "De Concini" symplectic lattices Defined in [Don1] and again in [Don2] These are two families of distributive lattice supporting graphs for the fundamental representations of the symplectic Lie algebras.…”

“…Using a Coxeter group viewpoint, it is possible to show that for any λ = i∈I a i ω i ∈ Λ + such that J = {i ∈ I | a i = 0}, then the stablizer W λ of λ under the Weyl group action is just W J ∼ = W Φ J (see for example §3 of [Don6]). In Corollary 3.10, we say how weight diagrams with respect to root subsystems can be understood in terms of weight diagrams with respect to the "parent" root system.…”

“…, which is closely related to moves of the so-called "numbers game" (see e.g. Appendix B, or [Don6] and references therein). With a root system / Cartan matrix / weight lattice / Weyl group in hand, one could begin a concrete theory of W -symmetric functions using the above numbers-game-…”

“…So we begin the exposition of this appendix with a discussion of Weyl groups and Weyl symmetric functions as presented in that ∼2008 paper. This discussion borrows from [Don6], [Don8], and [ADLMPPW] as well as standard treatments like [Hum1], [Hum2], [Bour],…”

Poset models for Weyl group analogs of symmetric functions and Schur functions

Olry Terquem’s Forgotten Problem and an Enumerative-Combinatorial Perspective on the Euclidean Algorithm