The Expected Jaggedness of Order Ideals

Chan, Melody; Haddadan, Shahrzad; Hopkins, Samuel B.; Moci, Luca

doi:10.1017/fms.2017.5

Cited by 20 publications

(113 citation statements)

References 18 publications

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“…To proceed further we need to introduce toggling and the "toggle perspective." This perspective was first developed in [12], while the "toggle" terminology comes from Striker and Williams [88]. For p ∈ P we define the toggle at p τ p : J(P ) → J(P ) as The τ p are involutions.…”

Section: The Cde Propertymentioning

confidence: 99%

“…Finding such a linear equation is essentially the only the general tool we have for proving that a distributive lattice is CDE. Theorem 3.7 was first proved in a case-by-case manner in [35], also using results from [12]. Shortly thereafter, Rush [69] gave a uniform proof of Theorem 3.7.…”

Section: The Cde Propertymentioning

confidence: 99%

“…• P is the poset corresponding to a "balanced skew shape" (see [12]); • P is the poset corresponding to a "shifted-balanced shape" (see [35]).…”

Section: The Cde Propertymentioning

confidence: 99%

“…Namely, we have: Proof. The cases (Λ OG (6,12) , Φ + (H 3 )) and (Λ Q 2n , Φ + (I 2 (2n))) are simple exercises. For (P, Q) = (Λ Gr(k,n) , T k,n ), we want a bijection between J(P ) and J(Q) which preserves down-degree.…”

Section: The Cde Propertymentioning

confidence: 99%

“…Conjecture 3.19. Let (P, Q) ∈ {(Λ Gr(k,n) , T k,n ), (Λ OG (6,12) , Φ + (H 3 )), (Λ Q 2n , Φ + (I 2 (2n)))} be a minuscule doppelgänger pair. Then #PP ℓ e (P ) = #PP ℓ e (Q) for any ℓ ≥ 1, e ≥ 0.…”

Section: So In Factmentioning

confidence: 99%

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Minuscule Doppelgängers, The Coincidental down-Degree Expectations Property, and Rowmotion

Hopkins

2020

Experimental Mathematics

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We relate Reiner, Tenner, and Yong's coincidental down-degree expectations (CDE) property of posets to the minuscule doppelgänger pairs studied by Hamaker, Patrias, Pechenik, and Williams. Via this relation, we put forward a series of conjectures which suggest that the minuscule doppelgänger pairs behave "as if" they had isomorphic comparability graphs, even though they do not. We further explore the idea of minuscule doppelgänger pairs pretending to have isomorphic comparability graphs by considering the rowmotion operator on order ideals. We conjecture that the members of a minuscule doppelgänger pair behave the same way under rowmotion, as they would if they had isomorphic comparability graphs. Moreover, we conjecture that these pairs continue to behave the same way under the piecewise-linear and birational liftings of rowmotion introduced by Einstein and Propp. This conjecture motivates us to study the homomesies (in the sense of Propp and Roby) exhibited by birational rowmotion. We establish the birational analog of the antichain cardinality homomesy for the major examples of posets known or conjectured to have finite birational rowmotion order (namely: minuscule posets and root posets of coincidental type).

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Section: The Cde Propertymentioning

confidence: 99%

Section: The Cde Propertymentioning

confidence: 99%

“…• P is the poset corresponding to a "balanced skew shape" (see [12]); • P is the poset corresponding to a "shifted-balanced shape" (see [35]).…”

Section: The Cde Propertymentioning

confidence: 99%

Section: The Cde Propertymentioning

confidence: 99%

Section: So In Factmentioning

confidence: 99%

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Minuscule Doppelgängers, The Coincidental down-Degree Expectations Property, and Rowmotion

Hopkins

2020

Experimental Mathematics

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Flexible toggles and symmetric invertible asynchronous elementary cellular automata

Defant

2018

Discrete Mathematics

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A sequential dynamical system (SDS) consists of a graph G with vertices v1, . . . , vn, a state set A, a collection of "vertex functions" {fv i } n i=1 , and a permutation π ∈ Sn that specifies how to compose these functions to yield the SDS map [G, {fv i } n i=1 , π] : A n → A n . In this paper, we study symmetric invertible SDS defined over the cycle graph Cn using the set of states F2. These are, in other words, asynchronous elementary cellular automata (ECA) defined using ECA rules 150 and 105. Each of these SDS defines a group action on the set F n 2 of n-bit binary vectors. Because the SDS maps are products of involutions, this relates to generalized toggle groups, which Striker recently introduced. In this paper, we further generalize the notion of a generalized toggle group to that of a flexible toggle group; the SDS maps we consider are examples of Coxeter elements of flexible toggle groups.Our main result is the complete classification of the dynamics of symmetric invertible SDS defined over cycle graphs using the set of states F2 and the identity update order π = 123 · · · n. More precisely, if T denotes the SDS map of such an SDS, then we obtain an explicit formula for |Perr(T )|, the number of periodic points of T of period r, for every positive integer r. It turns out that if we fix r and vary n and T , then |Perr(T )| only takes at most three nonzero values.

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