# How many possible assignments does a a CNF sentence have?

I'm having some trouble understanding the following:

When we look at satisfiability problems in conjunctive normal form, an underconstrained problem is one with relatively few clauses constraining the variables. For eg. here is a randomly generated 3-CNF sentence with five symbols and five clauses. (Each clause contains 3 randomly selected distinct symbols, each of which is negated with 50% probability.)

`````` (¬D ∨ ¬B ∨ C) ∧ (B ∨ ¬A ∨ ¬C) ∧ (¬C ∨ ¬B ∨ E) ∧ (E ∨ ¬D ∨ B) ∧ (B ∨ E ∨ ¬C)
``````

16 of the 32 possible assignments are models of this sentence, so, on an average, it would take just 2 random guesses to find the model.

I don't understand the last line- saying that there are 32 possible assignments. How is it 32? And how are only 16 of them models of the sentence? Sorry, but i'm finding this concept a bit confusing. Thanks.

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There are 2^5=32 possible assignments of the two values true and false to 5 variables:

``````1:  00000
2:  00001
3:  00010
...
31: 11110
32: 11111
``````

16 of those assignments satisfy (I didn't check) the given formula, thus are models of it.

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Thanks- but why does it say that it would take just 2 random guesses to find the model? Is it something like saying if the selected 16 assignments are unsatifiable, then the other 16 will be satisfiable? –  Ghost Sep 25 '12 at 13:49
Each assignment is either satisfying or unsatisfying. So if you pick an assignment by random (by flipping 5 coins), then the generated assignment will be a satisfying one in 50% of the cases. –  ziggystar Sep 25 '12 at 14:12
okay- i finally understand it. Thanks :) –  Ghost Sep 25 '12 at 14:24
@Ghost Keep in mind, that these 50% are a property of the particular formula you presented. It's not true in general. –  ziggystar Sep 25 '12 at 14:32