Technique to solve constraint satisfaction problems
In computer science, an interchangeability algorithm is a technique used to more efficiently solve constraint satisfaction problems (CSP). A CSP is a mathematical problem in which objects, represented by variables, are subject to constraints on the values of those variables; the goal in a CSP is to assign values to the variables that are consistent with the constraints. If two variables A and B in a CSP may be swapped for each other (that is, A is replaced by B and B is replaced by A) without changing the nature of the problem or its solutions, then A and B are interchangeable variables. Interchangeable variables represent a symmetry of the CSP and by exploiting that symmetry, the search space for solutions to a CSP problem may be reduced. For example, if solutions with A=1 and B=2 have been tried, then by interchange symmetry, solutions with B=1 and A=2 need not be investigated.
The concept of interchangeability and the interchangeability algorithm in constraint satisfaction problems was first introduced by Eugene Freuder in 1991.[1][2] The interchangeability algorithm reduces the search space of backtracking search algorithms, thereby improving the efficiency of NP-complete CSP problems.[3]
Definitions
Fully Interchangeable
A value a for variable v is fully interchangeable with value b if and only if every solution in which v = a remains a solution when b is substituted for a and vice versa.[2]
Neighbourhood Interchangeable
A value a for variable v is neighbourhood interchangeable with value b if and only if for every constraint on v, the values compatible with v = a are exactly those compatible with v = b.[2]
Fully Substitutable
A value a for variable v is fully substitutable with value b if and only if every solution in which v = a remains a solution when b is substituted for a (but not necessarily vice versa).[2]
Dynamically Interchangeable
A value a for variable v is dynamically interchangeable for b with respect to a set A of variable assignments if and only if they are fully interchangeable in the subproblem induced by A.[2]
Pseudocode
Neighborhood Interchangeability Algorithm
Finds neighborhood interchangeable values in a CSP.
Repeat for each variable:
Move to if present, construct if not, a node of the discrimination tree corresponding to w|W[2]
K-interchangeability algorithm
The algorithm can be used to explicitly find solutions to a constraint satisfaction problem. The algorithm can also be run for k steps as a preprocessor to simplify the subsequent backtrack search.
Finds k-interchangeable values in a CSP.
Repeat for each variable:
Build a discrimination tree by:
Repeat for each value, v:
Repeat for each (k − 1)-tuple of variables
Repeat for each (k − 1)-tuple of values w, which together with v constitute a solution to the subproblem induced by W:
Move to if present, construct if not, a node of the discrimination tree corresponding to w|W[2]
Complexity analysis
In the case of neighborhood interchangeable algorithm, if we assign the worst case bound to each loop. Then for n variables, which have at most d values for a variable, then we have a bound of :
.
Similarly, the complexity analysis of the k-interchangeability algorithm for a worst case , with -tuples of variables and , for -tuples of values, then the bound is : .
Example
The figure shows a simple graph coloring example with colors as vertices, such that no two vertices which are joined by an edge have the same color. The available colors at each vertex are shown. The colors yellow, green, brown, red, blue, pink represent vertex Y and are fully interchangeable by definition. For example, substituting maroon for green in the solution orange|X (orange for X), green|Y will yield another solution.
^Choueiry, B.Y.: Abstraction Methods for Resource Allocation. PhD thesis, EPFL PhD Thesis no 1292 (1994)
^Weigel, R., Faltings, B.: Interchangeability for Case Adaptation in Configura-
tion Problems. In Proceedings of the AAAI98 Spring Symposium on Multimodal Reasoning, Stanford, CA, TR SS-98-04. (1998)
^Neagu, N., Faltings, B.: Exploiting Interchangeabilities for Case Adaptation. In Proc. of the 4th ICCBR01 (2001)
^Full Dynamic Substitutability by SAT Encoding by Steven Prestwich, Cork Constraint Computation Centre, Department of Computer Science, University College, Cork, Ireland