The Rees product and cubical complexes - Armstrong Atlantic

Introduction Results Cubical results Rees multiple Almost cubical posets Conclusion

The Rees product and cubical complexes

Tricia Muldoon Brown

Armstrong Atlantic State University

April 18, 2010

Tricia Muldoon Brown: The Rees product and cubical complexes Armstrong Atlantic State University

Outline

Introduction

Results

Cubical Results

Rees multiple

Almost cubical posets

Questions

Assumptions

P is a poset which is:

bounded below

graded, with rank function ρ.

Rees product

Definition

For two graded posets P and Q with rank function ρ the Reesproduct P ? Q, is the set of ordered pairs (p, q) in the Cartesianproduct P × Q with ρ(p) ≥ ρ(q). These pairs are partially orderedby (p, q) ≤ (p′, q′) if p ≤P p′, q ≤Q q′, andρ(p′)− ρ(p) ≥ ρ(q′)− ρ(q).

C4 ? C4

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Figure: The Rees product of two chains

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Figure: The face lattice of the square, C2

Notation: Rees(P,Q) = ((P \ {0}) ? Q) ∪ {0, 1}

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Figure: The face lattice of the square, C2

Notation: Rees(P,Q) = ((P \ {0}) ? Q) ∪ {0, 1}

Rees(C2,C3)

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Figure: Rees(C2,C3)

Observation

For P, a rank n poset, the Rees product Rees(P,Cn) is isomorphicto the Segre product ((P \ {0}) ◦ (Cn ? Cn)) ∪ {0, 1}.

Cohen-Macaulay

Theorem (Bjorner–Welker)

The Rees product of two Cohen-Macaulay posets isCohen-Macaulay.

Simplicial Mobius values

Theorem (Jonsson)

The Mobius function of the Rees product of the Boolean algebraBn on n elements with the n element chain Cn is given by the nthderangement number, that is,

µ(Rees(Bn,Cn)) = (−1)n+1 · Dn.

Cubical Mobius values

Theorem (Brown–Readdy)

The Mobius function of the Rees product of the face lattice of then-dimensional cube Cn with the n + 1 element chain Cn+1 is ntimes a signed derangement number, that is

µ(Rees(Cn,Cn+1)) = (−1)n · n · per

1 2 2 · · · 22 1 2 · · · 22 2 1 · · · 2...

......

. . ....

2 2 2 · · · 1

Simplicial poset

Definition

A poset P with a minimal element 0P is simplicial if the interval[0P , x ] is isomorphic to a Boolean algebra for all x ∈ P.

Corollary (Shareshian-Wachs)

Let P be a ranked simplicial poset of length n. Then

µ(Rees(P,Cn) =n∑

(−1)r−1Wr (P)r !.

Rees multiple

Definition

Let P be a rank n poset with rank function ρ and R = Rees(P,Cn).For any p ∈ P with ρ(p) = r , define the Rees multiple

xr ,p =r∑

µ(0R , (p, j))

Definition

A poset P is called lower uniform if [0P , x ] ' [0p, y ] whenρ(x) = ρ(y).

Rees multiple

Definition

Let P be a rank n poset with rank function ρ and R = Rees(P,Cn).For any p ∈ P with ρ(p) = r , define the Rees multiple

xr ,p =r∑

µ(0R , (p, j))

Definition

A poset P is called lower uniform if [0P , x ] ' [0p, y ] whenρ(x) = ρ(y).

Cubical poset

Definition

A poset P with a minimal element 0P is cubical if the interval[0P , x ] is isomorphic to the face lattice of a cube for all x ∈ P.

Proposition

Let P be a ranked cubical poset of length n. Then

µ(Rees(P,Cn) =n∑

(−1)r−1Wr (P)|xr |.

where xr is the Rees multiple for the cubical lattice.

Cubical poset

Definition

A poset P with a minimal element 0P is cubical if the interval[0P , x ] is isomorphic to the face lattice of a cube for all x ∈ P.

Proposition

Let P be a ranked cubical poset of length n. Then

µ(Rees(P,Cn) =n∑

(−1)r−1Wr (P)|xr |.

where xr is the Rees multiple for the cubical lattice.

Values

Rees multiple 0 1 2 3 4 5 6

Bn 1 1 2 6 24 120 720Cn 1 −1 2 −7 40

Proposition

The rank r Rees multiple for the cubical lattice, xr , is given by therecursive formula

x0 = 1

xr = −r −r−1∑i=1

(r + 1− i)Wi (Cr−1)xi

where the ith Whitney number Wi (Cn) is the number of(i − 1)-dimensional faces in the n-dimensional cube.

Rees product as a Segre product

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W0(Cn)

W1(Cn)

W2(Cn) W2(Cn)

W3(Cn) W3(Cn) W3(Cn)

W4(Cn) W4(Cn) W4(Cn) W4(Cn)

Compute x4 by choosing any p ∈ Cn of rank 4.

Rees product as a Segre product

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W0(Cn)

W1(Cn)

W2(Cn) W2(Cn)

W3(Cn) W3(Cn) W3(Cn)

W4(Cn) W4(Cn) W4(Cn) W4(Cn)

Compute x4 by choosing any p ∈ Cn of rank 4.Tricia Muldoon Brown: The Rees product and cubical complexes Armstrong Atlantic State University

Example

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W0(C3)

W1(C3)

W2(C3) W2(C3)

W3(C3) W3(C3) W3(C3)

p p p p

Example

x4 =4∑

µ(0, (p, i))

− ∑0≤x<(p,i)

µ(0, x)

= −(2 ·W3(C3)x3 + 3 ·W2(C3)x2 + 4 ·W1(C3)x1 + 4W0(C3)x0)

= −(2 · 6(−7) + 3 · 12 · 2 + 4 · 8(−1) + 4 · 1 · 1) = 40

Example

x4 =4∑

µ(0, (p, i))

− ∑0≤x<(p,i)

µ(0, x)

= −(2 ·W3(C3)x3 + 3 ·W2(C3)x2 + 4 ·W1(C3)x1 + 4W0(C3)x0)

= −(2 · 6(−7) + 3 · 12 · 2 + 4 · 8(−1) + 4 · 1 · 1) = 40

Example

x4 =4∑

µ(0, (p, i))

− ∑0≤x<(p,i)

µ(0, x)

= −(2 ·W3(C3)x3 + 3 ·W2(C3)x2 + 4 ·W1(C3)x1 + 4W0(C3)x0)

= −(2 · 6(−7) + 3 · 12 · 2 + 4 · 8(−1) + 4 · 1 · 1) = 40

Example

x4 =4∑

µ(0, (p, i))

− ∑0≤x<(p,i)

µ(0, x)

= −(2 ·W3(C3)x3 + 3 ·W2(C3)x2 + 4 ·W1(C3)x1 + 4W0(C3)x0)

= −(2 · 6(−7) + 3 · 12 · 2 + 4 · 8(−1) + 4 · 1 · 1) = 40

Non-recursive formula

Proposition

Let fn,k−1 = Wk(Cn). The rank r Rees multiple, xr , for the cubicallattice is given by∑

(−1)l(kl −kl−1 + 1) · · · (k2−k1 + 1)(k1 + 1)fkl ,kl−1· · · fk2,k1fk1,−1

where the sum is over all integers 0 < k1 < k2 < · · · < kl = r − 1where 1 ≤ l ≤ r .

Simplicial case

Corollary

The number of permutations in the rth symmetric group, r !, isgiven by∑

(−1)l(kl − kl−1 + 1) · · · (k2 − k1 + 1)k1

(klkl−1

)· · ·(k2k1

)where the sum is over all integers 0 < k1 < k2 < · · · < kl = r suchthat 1 ≤ l ≤ r .

This sum is over all l-compositions(kl − kl−1) + · · ·+ (k2 − k1) + k1 of r where 0 ≤ l ≤ r − 1

Simplicial case

Corollary

The number of permutations in the rth symmetric group, r !, isgiven by∑

(−1)l(kl − kl−1 + 1) · · · (k2 − k1 + 1)k1

(klkl−1

)· · ·(k2k1

)where the sum is over all integers 0 < k1 < k2 < · · · < kl = r suchthat 1 ≤ l ≤ r .

This sum is over all l-compositions(kl − kl−1) + · · ·+ (k2 − k1) + k1 of r where 0 ≤ l ≤ r − 1

Almost cubical posets

Definition

Let Cn,k be the face poset of the cubical complex consisting of thethe boundaries of two n-dimensional cubes joined at ak-dimensional face adjoined with a maximal element.

Squares

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Figure: The boundaries of two squares joined at an edge

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Figure: C2,1Tricia Muldoon Brown: The Rees product and cubical complexes Armstrong Atlantic State University

Mobius function

Corollary

The Mobius function, µ(Rees(Cn,k ,Cn+1)), is given by

2 · µ(Rees(Cn,Cn+1)) + (n − k − 1) · µ(Rees(Ck ,Ck+1)).

This follows from the fact

Wi (Cn,k) = 2Wi (Cn)−Wi (Ck)

for 0 ≤ i ≤ n.

Mobius function

Corollary

The Mobius function, µ(Rees(Cn,k ,Cn+1)), is given by

2 · µ(Rees(Cn,Cn+1)) + (n − k − 1) · µ(Rees(Ck ,Ck+1)).

This follows from the fact

Wi (Cn,k) = 2Wi (Cn)−Wi (Ck)

for 0 ≤ i ≤ n.

Proposition

Let P and Q be ranked posets of length n. If

Wk(P) = Wk(Q) for all k = 0, 1, . . . n, and

µ([0P , x ]) = µ([0Q , y ]) where ρP(x) = ρQ(y),

thenµ(Rees(P,Cn)) = µ(Rees(Q,Cn))

More than 2 cubes

Corollary

Let C jn,k be the face poset of the cubical complex consisting of the

the boundaries of j n-dimensional cubes joined at a k-dimensionalface adjoined with a maximal element. Then the Mobius functionµ(Rees(C j

n,k ,Cn+1)) equals

j · µ(Rees(Cn,Cn+1)) + (j − 1) · (n − k − 1) · µ(Rees(Ck ,Ck+1)).

Questions and Comments

1 Is the are cubical q-analogue?

2 Almost uniform?

3 What is the Rees multiple for other uniform or lower uniformposets? Does it have any meaning?

4 Similar results for t-ary tree.

5 Can we find |xr | as a sum of positive terms? What else does itcount?

2 Almost uniform?

Conclusion

The End

The Rees product and cubical complexes - Armstrong Atlantic

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