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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]-------\ |
 |/                         \|

  ?            ?             ?
  |            |             |
(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

2 Answers 2

up vote 1 down vote accepted

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

This looks much more like statistical relational learning than constraint satisfaction. See in particular Probabilistic logic networks.

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Can you explain why you think this is so? There's very little information available on PLNs... –  williamstome Jun 11 '13 at 20:38
From Wikipedia: "he basic goal of PLN is to provide reasonably accurate probabilistic inference..." This doesn't seem related to what I want. In my scenario I have a set of values. Periodically, I will get sets of predicates, and need to return a combination of these values which satisfies the set of predicates. If I were able to access discrete truth values for the variable-value substitutions it would be a straighforward CSP. The twist is the uncertainty over substitution. Well, the other twist is that I'm working in an open world, but let's ignore that for now. –  williamstome Jun 11 '13 at 20:43
It seems like you are trying to infer the variable-value substitutions that maximize the likelihood of a set of conditional predicates. That's why I suggested PLNs (or some other statistical relational model). If that's not what you mean, can you be more rigorous about what constraint satisfaction means in this context? How do you know when you've achieved it? –  Special Touch Jun 11 '13 at 21:09

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