Breaking Symmetry in Matrix Models of Constraint Satisfaction Problems
19
Alan M. Frisch Artificial Intelligence Group Department of Computer Science University of York Co-authors Ian Miguel, Toby Walsh, Pierre Flener, Brahim Hnich, Zeynep Kiziltan, Justin Pearson Acknowledgement Warwick Harvey Breaking Symmetry in Matrix Models of Constraint Satisfaction Problems
-
Upload
george-foster -
Category
Documents
-
view
19 -
download
0
description
Breaking Symmetry in Matrix Models of Constraint Satisfaction Problems. Alan M. Frisch Artificial Intelligence Group Department of Computer Science University of York Co-authors Ian Miguel, Toby Walsh, Pierre Flener, Brahim Hnich, Zeynep Kiziltan, Justin Pearson Acknowledgement - PowerPoint PPT Presentation
Transcript of Breaking Symmetry in Matrix Models of Constraint Satisfaction Problems
Alan M. FrischArtificial Intelligence Group
Department of Computer Science
University of York
Co-authors
Ian Miguel, Toby Walsh, Pierre Flener, Brahim Hnich, Zeynep Kiziltan, Justin Pearson
Acknowledgement
Warwick Harvey
Breaking Symmetryin Matrix Models of
Constraint Satisfaction Problems
The Constraint Satisfaction Problem
An instance of the CSP consists of
• Finite set of variables X1,…,Xn, having finite domains D1,…,Dn.
• Finite set of constraints. Each restricts the values that the variables can simultaneously take. Example: x neq y. x+y<z.
Solutions of a CSP Instance
• A total instantiation maps each variable to an element in its domain.
• A solution to a CSP instance is a total instantiation that satisfies all the constraints.
• Problem: Given an instance– Determine if it is satisfiable (has a solution)– Find a solution– Find all solutions– Find optimal solution
Partial Instantiation Search(Forward Checking)
0
0
1
00
0 1 1
1 10
0 0
00
0 1
10
0
00
1 0
10
0 1
1
0
0
10
1 1
00
1 0
0 10
1 1 0
0 10
1 1
100
1 0 1
1
X X
10
0 0
0 10
0 0 1
1 10
0 1 1
0
X !
00
0 1
0
X
10
0 1 0
1
! !
! ! !
Index Symmetry in Matrix Models
• Many CSP Problems can be modelled by a multi-dimensional matrix of decision variables.
0 vs 72 vs 72 vs 60 vs 41 vs 63 vs 54 vs 5Period 3
0 vs 5
1 vs 4
3 vs 7
Week 5
3 vs 4
0 vs 6
1 vs 5
Week 6
1 vs 31 vs 22 vs 54 vs 66 vs 7Period 4
5 vs 65 vs 70 vs 31 vs 72 vs 3Period 2
2 vs 4 3 vs 64 vs 70 vs 20 vs 1Period 1
Week 7Week 4Week 3Week 2Week 1
Round Robin Tournament Schedule
Examples of Index Symmetry
• Balanced Incomplete Block Design– Set of Blocks – Set of objects in each block
• Rack Configuration– Set of cards (PI)– Set of rack types– Set of occurrences of each rack type
Examples of Index Symmetry
• Social Golfers– Set of rounds – Set of groups– Set of golfers
• Steel Mill Slab Design• Printing Template Design• Warehouse Location• Progressive Party Problem• …
Transforming Value Symmetry to Index Symmetry
• a, b, c, d are indistinguishable values
{b, d}ca
100
010
100
001a
b
c
d
Now the rows are indistinguishable
Index Symmetry in One Dimension
• Indistinguishable Rows
A B C
D E F
G H I
• 2 Dimensions[A B C] lex [D E F] lex [G H I]
• N Dimensionsflatten([A B C]) lex
flatten([D E F]) lex flatten([G H I])
Index Symmetry in Multiple Dimensions
A B C
D E F
G H I
A B C
D E F
G H I
A B C
D E F
G H I
A B C
D E F
G H IConsistent Consistent
Inconsistent Inconsistent
Incompleteness of Double Lex
01
01
10
01
10
10
Swap 2 columnsSwap row 1 and 3
Completeness in Special Cases
• All variables take distinct values– Push largest value to a particular corner, and– Order the row and column containing that value
• 2 distinct values, one of which has at most one occurrence in each row or column.– Lex order the rows and the columns
• Each row is a different multiset of values– Multiset order the rows and lex order the columns
Enforcing Lexicographic Ordering
• We have developed a linear time algorithm for enforcing generalized arc-consistency on a lexicographic ordering constraint between two vectors of variables.
• Experiments show that in some cases it is vastly superior to previous consistency algorithms, both in time and in amount pruned.
Enforcing Lexicographic Ordering
)( jlexiji
VVGAC
does not imply
GAC(V1 lex V2 lex … lex Vn)
• Not pair-wise decomposable
• Not transitive GAC(V1 lex V2) and GAC(V2 lex V3) does not imply GAC(V1 lex V3)
Complete Solution for 2x3 Matrices
1. ABCDEF ACBDFE
2. ABCDEF BCAEFD
3. ABCDEF BACEDF
4. ABCDEF CABFDE
5. ABCDEF CBAFED
6. ABCDEF DFEACB
FED
CBAABCDEF is minimal among the index symmetries
7. ABCDEF EFDBCA
8. ABCDEF EDFBAC
9. ABCDEF FDECAB
10. ABCDEF FEDCBA
11. ABCDEF DEFABC
Simplifying the Inequalities
Columns are lex ordered
1. BE CF
3. AD BE
1st row all permutations of 2nd
6. ABC DFE
8. ABC EDF
10. ABC FED
11. ABC DEF
9. ABC FDE
7. ABCD EFDB
FED
CBA
Illustration
Swap 2 rowsRotate columns left
Both satisfy 7. ABC EFDRight one satisfies 7. ABCD EFDB (1353 5133)Left one violates 7. ABCD EFDB (1355 1353)
FED
CBA
315
531
153
531
• Symmetry-Breaking Predicates for Search Problems[J. Crawford, M. Ginsberg, E. Luks, A. Roy, KR ~97].
Conclusion
• Many problems have models using a multi-dimensional matrix of decision variables in which there is index symmetry.
• Constraint toolkits should provide facilities to support this.
• We have laid some foundations towards developing such facilities.
• Open problems remain.
