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Problem Solving with Constraints

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Path Consistency & Global Consistency Properties Problem Solving with Constraints CSCE421/821, Fall2012 www.cse.unl.edu/~choueiry/F12-421-821 All questions: Piazza – PowerPoint PPT presentation

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Title: Problem Solving with Constraints


1
Path Consistency Global Consistency Properties
  • Problem Solving with Constraints
  • CSCE421/821, Fall2012
  • www.cse.unl.edu/choueiry/F12-421-821
  • All questions Piazza
  • Berthe Y. Choueiry (Shu-we-ri)
  • Avery Hall, Room 360
  • Tel 1(402)472-5444

2
Lecture Sources
  • Required reading
  • Algorithms for Constraint Satisfaction Problems,
    Mackworth and Freuder AIJ'85
  • Sections 3.1, 3.2, 3.3. Chapter 3. Constraint
    Processing. Dechter
  • Recommended
  • Sections 3.43.10. Chapter 3. Constraint
    Processing. Dechter
  • Networks of Constraints Fundamental Properties
    and Application to Picture Processing, Montanari,
    Information Sciences 74
  • Bartak Consistency Techniques (link)
  • Path Consistency on Triangulated Constraint
    Graphs, Bliek Sam-Haroud IJCAI'99

3
Outline
  • Motivation
  • Path consistency and its complexity
  • Global consistency properties
  • Minimality
  • Decomposability
  • When PC guarantees global consistency

4
AC is not enough Example borrowed from Dechter
  • Arc-consistent?
  • Satisfiable?
  • ? seek higher levels of consistency

V
V
1
1
b a
a b
V
V
V
V
2
3
2
a b
3
b a
a b
a b
5
Outline
  • Motivation
  • Path consistency and its complexity
  • Global consistency properties
  • Minimality
  • Decomposability
  • When PC guarantees global consistency

6
Consistency of a path
  • A path (V0, V1, V2, , Vm) of length m is
    consistent iff
  • for any value x?DV0 and for any value y?DVm that
    are consistent (i.e., PV0 Vm(x, y))
  • ? a sequence of values z1, z2, , zm-1 in the
    domains of variables V1, V2, , Vm-1, such that
    all constraints between them (along the path, not
    across it) are satisfied
  • (i.e., PV0 V1(x, z1) ? PV1 V2(z1, z2) ?
    ? PVm-1 Vm(zm-1, zm) )

7
Note
  • ? The same variable can appear more than once in
    the path
  • ? Every time, it may have a different value
  • ? Constraints considered PV0,Vm and those along
    the path
  • ? All other constraints are neglected

8
Example consistency of a path
  • ? Check path length 2, 3, 4, 5, 6, ....

?
?
?
?
?
?
?
?
?
?
?
?
9
Path consistency definition
  • ? A path of length m is path consistent
  • ? A CSP is path consistent Property of a
    CSP
  • Definition A CSP is path consistent (PC) iff
    every path is
  • consistent (i.e., any length of path)
  • Question should we enumerate every path of any
    length?
  • Answer No, only length 2, thanks to Mackworth
    AIJ'77

10
Tools for PC-1
  • Two operators
  • Constraint composition ( )
  • R13 R12 R23
  • Constraint intersection ( ? )
  • R13? R13, old ? R13, induced

11
Path consistency (PC-1)
  • Achieved by composition and intersection (of
    binary relations expressed as matrices) over all
    paths of length two.
  • Procedure PC-1
  • 1 Begin
  • 2 Yn ? R
  • 3 repeat
  • 4 begin
  • 5 Y0 ? Yn
  • 6 For k ? 1 until n do
  • 7 For i ? 1 until n do
  • 8 For j ? 1 until n do
  • 9 Ylij ? Yl-1ij ? Yl-1ik Yl-1kk Yl-1kj
  • 10 end
  • 11 until Yn Y0
  • 12 Y ? Yn
  • 10 end

12
Properties of PC-1
  • Discrete CSPs Montanari'74
  • PC-1 terminates
  • PC-1 results in a path consistent CSP
  • PC-1 terminates. It is complete, sound (for
    finding PC network)
  • PC-2 Improves PC-1 similar to how AC3 improves
    AC-1
  • Complexity of PC-1..

13
Complexity of PC-1
  • Procedure PC-1
  • 1 Begin
  • 2 Yn ? R
  • 3 repeat
  • 4 begin
  • 5 Y0 ? Yn
  • 6 For k ? 1 until n do
  • 7 For i ? 1 until n do
  • 8 For j ? 1 until n do
  • 9 Ylij ? Yl-1ij ? Yl-1ik Yl-1kk
    Yl-1kj
  • 10 end
  • 11 until Yn Y0
  • 12 Y ? Yn
  • 10 end
  • Line 9 a3
  • Lines 610 n3. a3
  • Line 3 at most n2 relations x a2 elements
  • PC-1 is O(a5n5)

PC-2 is O(a5n3) and ?(a3n3) PC-1, PC-2 are
specified using constraint composition
Basic Consistency Methods
14
Enforcing Path Consistency (PC)
  • General case Complete graph
  • Theorem In a complete graph, if every path of
    length 2 is consistent, the network is path
    consistent Mackworth AIJ'77
  • ? PC-1 two operations, composition and
    intersection
  • ? Proof by induction.
  • General case Triangulated graph
  • Theorem In a triangulated graph, if every path
    of length 2 is consistent, the network is path
    consistent Bliek Sam-Haroud 99
  • ? PPC (partially path consistent) ? PC

15
PPC versus PC
Algorithm Graph PC-p? Filtering
Arbitrary Constraints PC-2 Complete ? Tight, not necessarily minimal
Arbitrary Constraints PPC Triangulated ? Weaker filtering than PC-2
16
Some improvements
  • Mohr Henderson (AIJ 86)
  • PC-2 O(a5n3) ? PC-3 O(a3n3)
  • Open question PC-3 optimal?
  • Han Lee (AIJ 88)
  • PC-3 is incorrect
  • PC-4 O(a3n3) space and time
  • Singh (ICTAI 95)
  • PC-5 uses ideas of AC-6 (support bookkeeping)
  • Also
  • PC8 iterates over domains, not constraints
    Chmeiss Jégou 1998
  • PC2001 an improvement over PC8, not tested
    Bessière et al. 2005
  • Note PC is seldom used in practical applications
    unless in presence of special type of constraints
    (e.g., bounded difference)

Project!
17
Path consistency as inference of binary
constraints
  • Path consistency corresponds to inferring a new
    constraint
  • (alternatively, tightening an existing
    constraint) between every two
  • variables given the constraints that link them to
    a third variable
  • ? Considers all subgraphs of 3 variables
  • ? 3-consistency

B lt C
18
Path consistency as inference of binary
constraints
  • Another example

19
Question Adapted from Dechter
  • Given three variables Vi, Vk, and Vj and the
    constraints CVi,Vk, CVi,Vj, and CVk,Vj, write the
    effect of PC as a sequence of operations in
    relational algebra.

B
B
A lt B
A lt B
A
A
B lt C
B lt C
C
C
-3 lt A C lt 0
A 3 gt C
Solution CVi,Vj ? CVi,Vj ? ??ij(CVi,Vk
CVk,Vj)
20
Constraint propagation courtesy of Dechter
  • After Arc-consistency
  • After Path-consistency
  • Are these CSPs the same?
  • Which one is more explicit?
  • Are they equivalent?
  • The more propagation,
  • the more explicit the constraints
  • the more search is directed towards a solution

21
PC can detect unsatisfiability
  • Arc-consistent?
  • Path-consistent?

V1
a b
?
?
?
V2
V3
?
a b
a b
a b
?
?
a b
V4
22
Warning Does 3-consistency guarantee
2-consistency?
B
red, blue
red, blue
?
?
A
C
red
red
  • Question
  • Is this CSP 3-consistent?
  • is it 2-consistent?
  • Lesson
  • 3-consistency does not guarantee 2-consistency

23
PC is not enough
  • Arc-consistent?
  • Path-consistent?
  • Satisfiable?
  • ? we should seek (even) higher levels of
    consistency
  • k-consistency, k 1, 2, 3, .
    following lecture

?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
?
24
Outline
  • Motivation
  • Path consistency and its complexity
  • Global consistency properties
  • Minimality
  • Decomposability
  • When PC guarantees global consistency

25
Minimality
  • PC tightens the binary constraints
  • The tightest possible binary constraints yield
    the minimal network
  • Minimal network a.k.a. central problem
  • Given two values for two variables, if they are
    consistent, then they appear in at least one
    solution.
  • Note
  • Minimal ? path consistent
  • The definition of minimal CSP is concerned with
    binary CSPs, but it need not be

26
Minimal CSP
  • Minimal network a.k.a. central problem
  • Given two values for two variables, if they are
    consistent, then they appear in at least one
    solution.
  • Informally
  • In a minimal CSP the remainder of the CSP does
    not add any further constraint to the direct
    constraint CVi, Vj between the two variables Vi
    and Vj
    Mackworth AIJ'77
  • A minimal CSP is perfectly explicit as far as
    the pair Vi and Vj is concerned, the rest of the
    network does not add any further constraints to
    the direct constraint CVi, Vj
    Montanari'74
  • The binary constraints are explicit as possible.
    Montanari'74

27
Decomposability
  • Any combination of values for k variables that
    satisfy the constraints between them can be
    extended to a solution.
  • Decomposability generalizes minimality
  • Minimality any consistent combination of
    values for
  • any 2 variables is extendable to a
    solution
  • Decomposability any consistent combination of
    values for
  • any k variables is extendable to a
    solution

Minimal ?
Decomposable ?
Path Consistent
? ? ?
?
n-consistent ?
Strong n-consistent ?
Solvable
28
Relations to (theory of) DB
CSP Database
Minimal C-wise consistent The relations join completely
Decomposable ?
29
Outline
  • Motivation
  • Path consistency and its complexity
  • Global consistency properties
  • Minimality
  • Decomposability
  • When PC guarantees global consistency

30
PC approximates..
  • In general
  • Decomposability ? minimality ? path consistent
  • PC is used to approximate minimality (which is
    the central problem)
  • When is the approximation the real thing?
  • Special cases
  • When composition distributes over intersection,
    Montanari'74
  • PC-1 on the completed graph guarantees
    minimality and decomposability
  • When constraints are convex
    Bliek Sam-Haroud 99
  • PPC on the triangulated graph guarantees
    minimality and decomposability (and the existing
    edges are as tight as possible)

31
PPC versus PC
Algorithm Graph PC-p? Filtering
Arbitrary Constraints PC-2 Complete ? Tight, not necessarily minimal
Arbitrary Constraints PPC Triangulated ? Weaker filtering than PC-2
Composition distributes over intersection PC-2 Complete ? Minimal Decomposable
Composition distributes over intersection PPC Triangulated ? Minimal Decomposable
32
PC Special Case
  • Distributivity property
  • Outer loop in PC-1 (PC-3) can be ignored
  • Exploiting special conditions in temporal
    reasoning
  • Temporal constraints in the Simple Temporal
    Problem (STP) composition intersection
  • Composition distributes over intersection
  • PC-1 is a generalization of the Floyd-Warshall
    algorithm (all pairs shortest path)
  • Convex constraints
  • PPC

33
Distributivity property
Intersection, ? Composition,
  • In PC-1, two operations
  • RAB (RBC ? R'BC) (RAB RBC) ? (RAB
    RBC)
  • When ( ) distributes over ( ? ), then
    Montanari'74
  • PC-1 guarantees that CSP is minimal and
    decomposable
  • The outer loop of PC-1 can be removed

B
RBC
RAB
RBC
A
C
34
Condition does not always hold
  • Constraint composition does not always distribute
    over constraint intersection
  • R12 R23 R23
  • ( n )
  • ( ) n ( ) n

1 0 0 0
1 1 0 0
0 0 1 0
0 0 0 0
1 1 0 0
0 0 1 0
0 0 0 0
1 1 0 0
1 0 0 0
1 0 0 0
1 0 0 0
1 1 0 0
1 0 0 0
0 0 1 0
1 1 0 0
1 0 0 0
35
Temporal Reasoning constraints of
bounded difference
  • Variables X, Y, Z, etc.
  • Constraints a ? Y-X ? b, i.e. Y-X a, b I
  • Composition I 1 I2 a1, b1 a2, b2
    a1 a2, b1b2
  • Interpretation
  • intervals indicate distances
  • composition is triangle inequality.
  • Intersection I1 ? I2 max(a1, a2), min(b1,
    b2)
  • Distributivity I1 (I2 ? I3) (I1 I2) ? (I1
    I3)
  • Proof left as an exercise

36
Example Temporal Reasoning
  • Composition of intervals
  • R13 R12 R23 4, 12
  • R01 R13 2,5 3, 5 5, 10
  • R01 R'13 2,5 4, 12 6, 17
  • Intersection of intervals R13 ? R'13 4, 12
    ? 3, 5 4, 5
  • R01 (R13 ? R'13) (R01 R13) ? (R01 R'13)
  • R01 (R13 ? R'13) 2, 5 4, 5 6, 10
  • (R01 R13) ? (R01 R'13) 5, 10 ? 6,17
    6, 10
  • Here, path consistency guarantees minimality and
    decomposability

37
Composition Distributes over ?
  • PC-1 generalizes Floyd-Warshall algorithm
    (all-pairs shortest path), where
  • composition is scalar addition and
  • intersection is scalar minimal
  • PC-1 generalizes Warshall algorithm (transitive
    closure)
  • Composition is logical OR
  • Intersection is logical AND

38
Convex constraints temporal reasoning (again!)
  • Thanks to Xu Lin (2002)
  • Constraints of bounded difference are convex
  • We triangulate the graph (good heuristics exist)
  • Apply PPC restrict propagations in PC to
    triangles of the graph (and not in the complete
    graph)
  • According to Bliek Sam-Haroud 99 PPC becomes
    equivalent to PC, thus it guarantees minimality
    and decomposability

39
Summary
  • Alert Do not confuse a consistency property with
    the algorithms for reinforcing it
  • Local consistency methods
  • Remove inconsistent values (node, arc
    consistency)
  • Remove Inconsistent tuples (path consistency)
  • Get us closer to the solution
  • Reduce the size of the problem thrashing
    during search
  • Are cheap (i.e., polynomial time)
  • Global consistency properties are the goal we aim
    at
  • Sometimes (special constraints, graphs, etc)
    local consistency guarantees global consistency
  • E.g., Distributivity property in PC, row-convex
    constraints, special networks
  • Sometimes enforcing local consistency can be made
    cheaper than in the general case
  • E.g., functional constraints for AC, triangulated
    graphs for PC
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