Lower Bounds on the Sizes of Integer Programs Without Additional ...

Lower Bounds on the Sizes of Integer Programs Without Additional Variables Volker Kaibel & Stefan Weltge

Aussois, 2014

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once.

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once. Natural approach: (binary) variable xij for each edge {i, j}

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once. Natural approach: (binary) variable xij for each edge {i, j} identify each tour T with its characteristic vector χ(T ) ∈ {0, 1}E (χ(T )e = 1 ⇐⇒ e ∈ T )

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once. Natural approach: (binary) variable xij for each edge {i, j} identify each tour T with its characteristic vector χ(T ) ∈ {0, 1}E (χ(T )e = 1 ⇐⇒ e ∈ T ) TSPn := {χ(T ) : T hamiltonian tour}

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once. Natural approach: (binary) variable xij for each edge {i, j} identify each tour T with its characteristic vector χ(T ) ∈ {0, 1}E (χ(T )e = 1 ⇐⇒ e ∈ T ) TSPn := {χ(T ) : T hamiltonian tour} given weights cij , we would like to solve: min {hc, xi : x ∈ TSPn }

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once. Natural approach: (binary) variable xij for each edge {i, j} identify each tour T with its characteristic vector χ(T ) ∈ {0, 1}E (χ(T )e = 1 ⇐⇒ e ∈ T ) TSPn := {χ(T ) : T hamiltonian tour} given weights cij , we would like to solve: min {hc, xi : x ∈ TSPn } = min {hc, xi : x ∈ conv(TSPn )}

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once. Natural approach: (binary) variable xij for each edge {i, j} identify each tour T with its characteristic vector χ(T ) ∈ {0, 1}E (χ(T )e = 1 ⇐⇒ e ∈ T ) TSPn := {χ(T ) : T hamiltonian tour} given weights cij , we would like to solve: min {hc, xi : x ∈ TSPn } = min {hc, xi : x ∈ conv(TSPn )} = min {hc, xi : Ax ≤ b}

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once. Natural approach: (binary) variable xij for each edge {i, j} identify each tour T with its characteristic vector χ(T ) ∈ {0, 1}E (χ(T )e = 1 ⇐⇒ e ∈ T ) TSPn := {χ(T ) : T hamiltonian tour} given weights cij , we would like to solve: min {hc, xi : x ∈ TSPn } = min {hc, xi : x ∈ conv(TSPn )} = min {hc, xi : Ax ≤ b} Ax ≤ b is very large and complicated

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Motivation

Basics

Lower bounds

Conclusion

Traveling Salesman Problem Find a shortest cycle in a complete graph (V , E ) that hits each node exactly once. Natural approach: (binary) variable xij for each edge {i, j} identify each tour T with its characteristic vector χ(T ) ∈ {0, 1}E (χ(T )e = 1 ⇐⇒ e ∈ T ) TSPn := {χ(T ) : T hamiltonian tour} given weights cij , we would like to solve: min {hc, xi : x ∈ TSPn } = min {hc, xi : x ∈ conv(TSPn )} = min {hc, xi : Ax ≤ b} Ax ≤ b is very large and complicated Why not use additional variables? Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

1 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (2)

min {hc, xi : x ∈ TSPn } = min {hc, xi : Ax + By ≤ b}

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

2 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (2) Theorem (Fiorini, Pokutta et al. 2012) There is no polynomial size system Ax + By ≤ b such that min {hc, xi : x ∈ TSPn } = min {hc, xi : Ax + By ≤ b} holds for all c ∈ RE .

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

2 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (2) Theorem (Fiorini, Pokutta et al. 2012) There is no polynomial size system Ax + By ≤ b such that min {hc, xi : x ∈ TSPn } = min {hc, xi : Ax + By ≤ b} holds for all c ∈ RE . But there are several polynomial size integer programming formulations of the form  min hc, xi : Ax + By ≤ b, x ∈ {0, 1}E , y ∈ Zk for solving the TSP (Miller-Tucker-Zemlin, flow based, ...)

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

2 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (2) Theorem (Fiorini, Pokutta et al. 2012) There is no polynomial size system Ax + By ≤ b such that min {hc, xi : x ∈ TSPn } = min {hc, xi : Ax + By ≤ b} holds for all c ∈ RE . But there are several polynomial size integer programming formulations of the form  min hc, xi : Ax + By ≤ b, x ∈ {0, 1}E , y ∈ Zk for solving the TSP (Miller-Tucker-Zemlin, flow based, ...)

Theorem For any family of sets Xd ⊆ {0, 1}d with the property that the problem “Given x ∈ Zd , is x ∈ Xd ?” is in NP,

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

2 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (2) Theorem (Fiorini, Pokutta et al. 2012) There is no polynomial size system Ax + By ≤ b such that min {hc, xi : x ∈ TSPn } = min {hc, xi : Ax + By ≤ b} holds for all c ∈ RE . But there are several polynomial size integer programming formulations of the form  min hc, xi : Ax + By ≤ b, x ∈ {0, 1}E , y ∈ Zk for solving the TSP (Miller-Tucker-Zemlin, flow based, ...)

Theorem For any family of sets Xd ⊆ {0, 1}d with the property that the problem “Given x ∈ Zd , is x ∈ Xd ?” is in NP, we have polynomial size systems Ax + By ≤ b such that  Xd = x : Ax + By ≤ b, x ∈ {0, 1}d , y ∈ Zk . Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

2 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (3) Observation All such polynomial size formulations for the TSP use auxiliary variables.

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

3 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (3) Observation All such polynomial size formulations for the TSP use auxiliary variables.

Motivating question Is there a polynomial size system Ax ≤ b such that  min {hc, xi : x ∈ TSPn } = min hc, xi : Ax ≤ b, x ∈ ZE holds for all c ⊆ RE ?

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

3 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (3) Observation All such polynomial size formulations for the TSP use auxiliary variables.

Motivating question Is there a polynomial size system Ax ≤ b such that  min {hc, xi : x ∈ TSPn } = min hc, xi : Ax ≤ b, x ∈ ZE holds for all c ⊆ RE ?

Definition For a set X ⊆ Zd , a polyhedron P ⊆ Rd is called a relaxation for X if P ∩ Zd = X .

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

3 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (3) Observation All such polynomial size formulations for the TSP use auxiliary variables.

Motivating question Is there a polynomial size system Ax ≤ b such that  min {hc, xi : x ∈ TSPn } = min hc, xi : Ax ≤ b, x ∈ ZE holds for all c ⊆ RE ?

Definition For a set X ⊆ Zd , a polyhedron P ⊆ Rd is called a relaxation for X if P ∩ Zd = X . The relaxation complexity of X is the smallest number of facets of any relaxation for X . (short: rc(X )) Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

3 / 15

Motivation

Basics

Lower bounds

Conclusion

Motivation (3) Observation All such polynomial size formulations for the TSP use auxiliary variables.

Motivating question Is rc(TSPn ) polynomial in n?

Definition For a set X ⊆ Zd , a polyhedron P ⊆ Rd is called a relaxation for X if P ∩ Zd = X . The relaxation complexity of X is the smallest number of facets of any relaxation for X . (short: rc(X ))

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

3 / 15

Motivation

Separation

Basics

Lower bounds

Conclusion

Subtour elimination polytope  Rnsub := x ∈ [0, 1]E : x(δ(v )) = 2 for all v ∈ V x(δ(S)) ≥ 2 for all ∅ = 6 S ⊂V

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables



Aussois, 2014

4 / 15

Motivation

Separation

Basics

Lower bounds

Conclusion

Subtour elimination polytope  Rnsub := x ∈ [0, 1]E : x(δ(v )) = 2 for all v ∈ V x(δ(S)) ≥ 2 for all ∅ = 6 S ⊂V



Rnsub is a relaxation for TSPn

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

4 / 15

Motivation

Separation

Basics

Lower bounds

Conclusion

Subtour elimination polytope  Rnsub := x ∈ [0, 1]E : x(δ(v )) = 2 for all v ∈ V x(δ(S)) ≥ 2 for all ∅ = 6 S ⊂V



Rnsub is a relaxation for TSPn Rnsub has exponentially many facets

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

4 / 15

Motivation

Separation

Basics

Lower bounds

Conclusion

Subtour elimination polytope  Rnsub := x ∈ [0, 1]E : x(δ(v )) = 2 for all v ∈ V x(δ(S)) ≥ 2 for all ∅ = 6 S ⊂V



Rnsub is a relaxation for TSPn Rnsub has exponentially many facets But: We can optimize over Rnsub in polynomial time!

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

4 / 15

Motivation

Separation

Basics

Lower bounds

Conclusion

Subtour elimination polytope  Rnsub := x ∈ [0, 1]E : x(δ(v )) = 2 for all v ∈ V x(δ(S)) ≥ 2 for all ∅ = 6 S ⊂V



Rnsub is a relaxation for TSPn Rnsub has exponentially many facets But: We can optimize over Rnsub in polynomial time!

Theorem For any family of sets Xd ⊆ {0, 1}d with the property that the problem “Given x ∈ Zd , is x ∈ Xd ?” is in P,

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

4 / 15

Motivation

Separation

Basics

Lower bounds

Conclusion

Subtour elimination polytope  Rnsub := x ∈ [0, 1]E : x(δ(v )) = 2 for all v ∈ V x(δ(S)) ≥ 2 for all ∅ = 6 S ⊂V



Rnsub is a relaxation for TSPn Rnsub has exponentially many facets But: We can optimize over Rnsub in polynomial time!

Theorem For any family of sets Xd ⊆ {0, 1}d with the property that the problem “Given x ∈ Zd , is x ∈ Xd ?” is in P, there are relaxations Rd for Xd and we can optimize over Rd in polynomial time. Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

4 / 15

Motivation

Cube

Basics

Lower bounds

Conclusion

Clearly: rc({0, 1}d ) ≤ 2d

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

5 / 15

Motivation

Cube

Basics

Lower bounds

Conclusion

Clearly: rc({0, 1}d ) ≤ 2d

Theorem

rc({0, 1}d ) = d + 1

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

5 / 15

Motivation

Cube

Basics

Lower bounds

Conclusion

Clearly: rc({0, 1}d ) ≤ 2d

Theorem

rc({0, 1}d ) = d + 1

{0, 1}d =



x ∈ Zd : 0 ≤ x1 +

d X 1 xi 2i i=2

xk ≤ 1 +

 d X 1 x for k = 1, . . . , d i 2i

i=k+1 Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

5 / 15

Lower bounds

Motivation

Basics

Lower bounds

Conclusion

Definition Let X ⊆ Zd . A set H ⊆ Zd \ X is called a hiding set for X if: H ⊆ aff(X ) For any two distinct points a, b ∈ H: conv({a, b}) ∩ conv(X ) 6= ∅

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

6 / 15

Motivation

Lower bounds

Basics

Lower bounds

Conclusion

Definition Let X ⊆ Zd . A set H ⊆ Zd \ X is called a hiding set for X if: H ⊆ aff(X ) For any two distinct points a, b ∈ H: conv({a, b}) ∩ conv(X ) 6= ∅

Proposition H hiding set for X Stefan Weltge

⇒ rc(X ) ≥ |H|

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

6 / 15

Hiding set for TSP

Stefan Weltge

Motivation

Basics

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Lower bounds

Conclusion

Aussois, 2014

7 / 15

Proof strategy

Stefan Weltge

Motivation

Basics

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Lower bounds

Conclusion

Aussois, 2014

8 / 15

Motivation

Proof strategy

1 2·

Basics

Lower bounds

Conclusion

+ 12 · =

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

8 / 15

Motivation

Proof strategy

1 2·

Basics

Lower bounds

Conclusion

+ 12 · =

1 2·

Stefan Weltge

+ 12 ·

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

8 / 15

Motivation

Basics

Lower bounds

Conclusion

Hiding set for TSP (2)

1 2

·

+

1 2

·

= Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

9 / 15

Motivation

Basics

Lower bounds

Conclusion

Hiding set for TSP (2)

1 2

·

+

1 2

·

= Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

9 / 15

Motivation

Basics

Lower bounds

Conclusion

Hiding set for TSP (2)

1 2

·

+

1 2

Stefan Weltge

·

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

10 / 15

Motivation

Basics

Lower bounds

Conclusion

Hiding set for TSP (2)

1 2

·

+

1 2

·

∈ conv(TSPn ) Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

10 / 15

Results for TSP

Motivation

Basics

Lower bounds

Conclusion

Theorem The asymptotical growth of rc(TSPn ) is 2Θ(n) .

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

11 / 15

Results for TSP

Motivation

Basics

Lower bounds

Conclusion

Theorem The asymptotical growth of rc(TSPn ) is 2Θ(n) . The subtour elimination relaxation is asymptotically smallest possible.

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

11 / 15

Results for TSP

Motivation

Basics

Lower bounds

Conclusion

Theorem The asymptotical growth of rc(TSPn ) is 2Θ(n) . The subtour elimination relaxation is asymptotically smallest possible.

Theorem The asymptotical growth of rc(?) is 2Θ(n) , where ? is the set of characteristic vectors of ... spanning trees arborescences forests branchings connected edge sets for the complete (undirected/directed) graph on n nodes.

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

11 / 15

Motivation

Further Results

( EVENn :=

n

n X

n

i=1 n X

x ∈ {0, 1} : (

ODDn :=

x ∈ {0, 1} :

Basics

Lower bounds

Conclusion

) xi even ) xi odd

i=1

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

12 / 15

Motivation

Further Results

( EVENn :=

n

n X

n

i=1 n X

x ∈ {0, 1} : (

ODDn :=

x ∈ {0, 1} :

Basics

Lower bounds

Conclusion

) xi even ) xi odd

i=1

Theorem (Jeroslow 1973) ODDn is a hiding set for EVENn .

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

12 / 15

Motivation

Further Results

( EVENn :=

n

n X

n

i=1 n X

x ∈ {0, 1} : (

ODDn :=

x ∈ {0, 1} :

Basics

Lower bounds

Conclusion

) xi even ) xi odd

i=1

Theorem (Jeroslow 1973) ODDn is a hiding set for EVENn .

Corollary rc(EVENn ) ≥ 2n−1

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

12 / 15

Motivation

Basics

Lower bounds

Conclusion

Further Results (2) For T ⊆ V with n, |T | even: T -JOINSn := set of characteristic vectors of T -joins in (V , E )

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

13 / 15

Motivation

Basics

Lower bounds

Conclusion

Further Results (2) For T ⊆ V with n, |T | even: T -JOINSn := set of characteristic vectors of T -joins in (V , E )

Theorem n

rc(T -JOINSn ) ≥ 2 4 −1

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

13 / 15

Motivation

Basics

Lower bounds

Conclusion

Further Results (2) For T ⊆ V with n, |T | even: T -JOINSn := set of characteristic vectors of T -joins in (V , E )

Theorem n

rc(T -JOINSn ) ≥ 2 4 −1

 DIFFm,n := x ∈ {0, 1}m×n : x has pairwise distinct rows

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

13 / 15

Motivation

Basics

Lower bounds

Conclusion

Further Results (2) For T ⊆ V with n, |T | even: T -JOINSn := set of characteristic vectors of T -joins in (V , E )

Theorem n

rc(T -JOINSn ) ≥ 2 4 −1

 DIFFm,n := x ∈ {0, 1}m×n : x has pairwise distinct rows

Theorem rc(DIFF2,n ) ≥ 2n

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

13 / 15

Motivation

Conclusion

Basics

Lower bounds

Conclusion

Hard to model without additional variables: - Acyclicity

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

14 / 15

Motivation

Conclusion

Basics

Lower bounds

Conclusion

Hard to model without additional variables: - Acyclicity - Connectivity

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

14 / 15

Motivation

Conclusion

Basics

Lower bounds

Conclusion

Hard to model without additional variables: - Acyclicity - Connectivity - Parity

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

14 / 15

Motivation

Conclusion

Basics

Lower bounds

Conclusion

Hard to model without additional variables: -

Stefan Weltge

Acyclicity Connectivity Parity Distinctness

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

14 / 15

Motivation

Conclusion

Basics

Lower bounds

Conclusion

Hard to model without additional variables: -

Acyclicity Connectivity Parity Distinctness

Everything becomes easy with additional variables!

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

14 / 15

Motivation

Conclusion

Basics

Lower bounds

Conclusion

Hard to model without additional variables: -

Acyclicity Connectivity Parity Distinctness

Everything becomes easy with additional variables!

Projection is a powerful tool!

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

14 / 15

My Favorite Open Question

Motivation

Basics

Lower bounds

Conclusion

What is the relaxation complexity of the standard simplex’ vertices?

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

15 / 15

My Favorite Open Question

Motivation

Basics

Lower bounds

Conclusion

What is the relaxation complexity of the standard simplex’ vertices?

Let ∆d := {O, e1 , . . . , ed }

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

15 / 15

My Favorite Open Question

Motivation

Basics

Lower bounds

Conclusion

What is the relaxation complexity of the standard simplex’ vertices?

Let ∆d := {O, e1 , . . . , ed } Clearly: rc(∆d ) ≤ d + 1

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

15 / 15

My Favorite Open Question

Motivation

Basics

Lower bounds

Conclusion

What is the relaxation complexity of the standard simplex’ vertices?

Let ∆d := {O, e1 , . . . , ed } Clearly: rc(∆d ) ≤ d + 1

Is there a polyhedron P with less than d + 1 facets such that P ∩ Zd = ∆d ?

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

15 / 15

My Favorite Open Question

Motivation

Basics

Lower bounds

Conclusion

What is the relaxation complexity of the standard simplex’ vertices?

Let ∆d := {O, e1 , . . . , ed } Clearly: rc(∆d ) ≤ d + 1

Is there a polyhedron P with less than d + 1 facets such that P ∩ Zd = ∆d ? (If yes, P must be unbounded and hence irrational!)

Stefan Weltge

Lower Bounds on the Sizes of Integer Programs w/o Additional Variables

Aussois, 2014

15 / 15