# Constraint Satisfaction with Uncertainty

I'm trying to solve a problem in which the satisfaction of constraints cannot always be verified. I can find lots of papers on flexible constraint satisfaction, but that's not quite what I want. Here's an example:

P(Jim likes Cheese) = 0.8
P(Joe likes Cheese) = 0.5
P(Sam likes Cheese) = 0.2
P(Jim and Sam are friends) = 0.9
P(Jim and Joe are friends) = 0.5
P(Joe and Sam are friends) = 0.7


Charlie is talking about two cheese-liking friends. Who is he most likely talking about?

I'm currently viewing this as a constraint satisfaction problem:

[likes cheese]   [likes cheese]
|                           |
| /-------[alldiff]-------\ |
|/                         \|
[X]--------[friends]--------[Y]

?            ?             ?
|            |             |
(Sam)        (Joe)         (Jim)


Are there existing ways for dealing with this type of CSP?

Is a CSP even the right way to frame the problem?

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Can you assume anything about independence? I suppose in this example, you could have two friends that met at a cheese-sampling and that would throw the whole thing. –  Dan Garant Jun 11 '13 at 19:19
I'm not entirely sure I understand your question; perhaps my example was bad though. I want to treat a set of Predicates P as a set of constraints on the possible variables which can be substituted into those predicates. Unfortunately we can only evaluate whether a predicate holds on substitution with a limited degree of certainty. –  williamstome Jun 11 '13 at 19:22

For a propositional model (where each variable has a distinct name), you should have a look at probabilistic graphical models (in particular Markov networks). They are very closely related to SAT and CSP, since they are basically a generalization, but still fall into the same complexity class #P.

If you are interested in concise, first order representation of these models, you should look into statistical relational learning or first order probabilistic models (synonyms). Here, the model is expressed in a "lifted" form. E.g. possibly probabilistic constraints of the following form, using variables ranging over some object domain:

on(?x,?y) => largerThan(?y,?x)


Inferences with these models that do not rely on generating the ground model are done in the field of lifted probabilistic inference.

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I've accepted that CSPs are not the right way to solve my problem, but in the end I decided that graphical models in general were not the appropriate solution, especially because I am not trying to perform inference, but rather unification/reference resolution. I'm accepting this answer because even though it wasn't the solution to my problem, that was a result of my problem being framed in the wrong light, and this answer was the most informative. My problems continue here!: stackoverflow.com/questions/17090385/… –  williamstome Jun 13 '13 at 15:02