# Tag Info

20

This is known as higher-order abstract syntax. First solution: Use Haskell's lambda. A datatype could look like: data Prop = Not Prop | And Prop Prop | Or Prop Prop | Impl Prop Prop | Equiv Prop Prop | Equals Obj Obj | ForAll (Obj -> Prop) | Exists (Obj -> Prop) deriving (Eq, Ord) data Obj = Num ...

7

Your intuition for bool_ind is spot on, but thinking about why bool_ind means what you said might help clarify the other two. We know that bool_ind : forall P : bool -> Prop, P true -> P false -> forall b : bool, P b If we read this as a logical formula, we get the same reading you did: For ...

5

Well ask yourself this: Are implication and conjunction equivalent? No. Your last statement says that all x's are both dogs and have four legs. While that does mean that all dogs have four legs, it also means that everything is a dog... I suggest writing out what each statement means in English: There is some x that is a dog and barks There is some x where ...

4

Short answer: No. Medium Answer: Can't really be done, though one could write a program to check the validity of a given proof fairly easily. In the case of propositional logic, the problem of automatically finding a proof is NP-complete (though it is decidable!), and in first order logic there are true theorems for which the prover would never stop. ...

4

The error here is that next is a function in the module referred to by the alias T0, so the expression on the RHS of the let binding should be t.T0/next and not T0/t.next. But actually you don't need the T0 anyway, since Alloy can determine which module is being referred to. So just remove all references to T0 and it should compile fine. Another comment: ...

4

∃x (dog(X) -> bark(x)) Late reply, but if anyone does end here and wants to know, from what i've been learning that means: There exists a dog that barks vs some dogs bark. More precise: there exists some x, if x is a dog, then it barks. -> is an if-then statement. ∃x (dog(X) Λ bark(x)) means there exists some dog and it barks, in other words, some dogs ...

4

In your grammar you have: argument <- variable / lowercase /number / string function <- {|lowercase {|(open argument (separator (argument / function))* close)?|}|} Keep in mind that lpeg tries to match the patterns/predicates in the rule in the order you have it. Once it finds a match lpeg won't consider further possible matches in that grammar ...

3

There are three cases which are really suspicious: | Simplify (Or (x, y)) = (Simplify (Or (Simplify x, Simplify y))) | Simplify (And (x, y)) = (Simplify (And (Simplify x, Simplify y))) | Simplify (Not(x)) = (Simplify (Not (Simplify x))) Basically, if x and y couldn't be simplified further, Simplify x and Simplify y will return x and y. So you will ...

3

Z3 does not consider empty models. This is a standard assumption in first-order logic. For more details search "first-order logic empty models", you will get many links explaining the motivation for this convention. The wikipedia page for first-order logic has a brief description (section "Empty domains"). Moreover, we should not confuse [] with the empty ...

3

I've extended @ Diego Sevilla's answer to include the original question of what an animal is, and added the execution. % Your original facts dog(spot). cat(nyny). fly(harry). % @ Diego Sevilla's predicates mammal(X) :- dog(X). mammal(X) :- cat(X). insect(X) :- fly(X). % Defining what an animal is - either insect or (;) mammal animal(X) :- insect(X) ; ...

3

The most problematic definitions in Prolog, are those which are left-recursive. Definitions like g(X) :- g(A), r(A,X). are most likely to fail, due to Prolog's search algorithm, which is plain depth-first-search and will run to infinity and beyond. The general problem with Horn Clauses however is, that they're defined to have at most one positive ...

3

You can express your sentence straightforward with Prolog using negation (\+). E.g.: car(bmw). car(honda). ... car(toyota). engine(bmw, dohv). engine(toyota, wenkel). no_car_without_engine:- \+( car(Car), \+(engine(Car, _)) ). Procedure no_car_without_engine/0 will succeed if every car has an engine, and fail otherwise.

3

From ∃x ∀y [C(x) ∧ F(y) ∧ Eat(x, y)] it follows that ∀y F(y), i.e. everything is food. ("There exists a child x such that for all y, y is food" and a bunch of other propositions hold.) It also follows that the child eats itself: if we denote the child by an arbitrary constant c and fill that in, we get ∀y [C(c) ∧ F(y) ∧ Eat(c, y)] and since y is ...

3

Try this one out: http://www.sat4j.org/ I believe that this technology has been incorporated into the Eclipse Provisioning System P2 to solve plugin dependencies. http://blog.mancoosi.org/index.php/2008/06/01/4-edos-offspring-1-eclipse-p2-will-include-sat-solver-technology-for-managing-plugins

2

I'm fairly confident that LPL's exact Fitch format is unique to LPL. The general Fitch-style proof concept comes from Fitch himself (http://en.wikipedia.org/wiki/Fitch-style_calculus) though it is probably not much of a help for you. There are answers to selected exercises here: http://ggww.stanford.edu/NGUS/lpl/hints Though I think your best bet is to ...

2

Whenever you have determiner every (or any or no) in an English sentence the corresponding FOL sentence should have both a universal quantifier and an implication in it. E.g. the translation template for the noun phrase every man would be: ∀ x (man(x) ⇒ ...) If your English sentence does not contain any determiners, then reformulate it so that every noun ...

2

Prolog is a programming language, not a natural language interface. The sentence you show is expressed in such a convoluted way that I had hard time attempting to understand it. Effectively, I must thanks gusbro that took the pain to express it in understandable way. But he entirely glossed over the knowledge representation problems that any programming ...

2

I think what you're referring to is just the following: mamal(X) :- dog(X). mamal(X) :- cat(X). insect(X) :- fly(X). That is, a mamal is either something that is a dog or a cat. You have to explicitly specify the categories that fall into that mamal category. Same for insects. Connecting this with your first-order logic question, the first entries of ...

2

At least the two OWL-reasoners Pellet and HermiT are written in Java. Rant You cannot represent anything in this world with logic. Actually you can represent only a very, very, very limited fragment of the real world in logic - largely definitions. But you cannot represent many interesting aspects of the real world in logics. Logics cannot cope with ...

2

You are assuming constraints that you did not assert. For example, nothing prevents move to be the constant function. The model produced by Z3 is correct. You can obtain the model by adding the command (get-model) after (check-sat). The command (declare-sort Action 0) is declaring a unintepreted sort. In the model produced by Z3, the interpretation of sort ...

1

Depending on the way that you represent the rest of the game, I think you can actually represent this in OWL DL, at least on a player by player basis. For instance, you can say that =controlsRegion-1.player ⊑ ∀(inRegion-1 • ownedBy).{player} In first order logic, that would be: ∀ r.[controlsRegion(player,r) ⇔ ...

1

Sorry, I didn't have experience with LPeg, but usual Lua patterns are enough to easily solve your task: local str = 'term(A, b, c(d, "e", 7))' local function convert(expr) return (expr:gsub('(%w+)(%b())', function (name, par_expr) return '{'..name..', {'..convert(par_expr:sub(2, -2))..'}}' end )) end ...

1

You may not be able to model this in general with OWL DL but you could model the region controled by P. :RegionControlledByP a owl:Class; rdfs:subClassOf [ a owl:Restriction; owl:onProperty [ owl:inverseOf :isInRegion ]; owl:someValuesFrom :Unit ], [ a owl:Restriction; owl:onProperty [ owl:inverseOf ...

1

I'm afraid you cannot do this in OWL 2 DL nor in Protégé, which is an editor for OWL 2 DL, because, as far as I can tell, it seems necessary to introduce the inverse of a datatype property, which is forbidden in OWL 2 DL. However, it's possible in OWL Full, and some DL reasoners may even be able to deal with it. Here, in Turtle: <MappedConcept> a ...

1

As a general information, you need to have your knowledge base in CNF, and a NEGATED goal (also in CNF). Then by unifying and applying resolution either you need to have a nil resolvent or the goal state itself. Other option is not being able to find any of these and resolve infinitely. If Make(p,π,a) is in your knowledge base, then unifying and ...

1

I'm not sure you're approaching the problem correctly. The first step is to encode the three statements ("Apples are either green or red", "John only grows green apples", "Mary only uses apples from John to make pies") into clausal form, which you haven't done. The second step is to encode the negation of the statement you are trying to prove ("Mary only ...

1

There's a paper (co-authored) that discusses the same issue. The representation is DRS which is related to FOL, then it is transformed to SQL. Some predicates have to be represented as well. While the paper focuses on comparisons and evaluations, factoid questions are covered as well.

1

You didn't check whether y was food first. Considering your statement, let a be a children, ie. C(a) is true. Then (∃x)(∀y) C(x) ∧ Eat(x,y) implies (∃x) C(x) ∧ Eat(x,a). In other words, you're stating that some children will eat anything, not only food.

1

Just to clarify with parentheses, what you wrote is usually taken to mean: \forall e1 \in S. (\forall e2 \in S. (Radius e1 <= Radius e2 --> Value e1 = 0)) This statement asserts that the value of every element is 0. Here's how: Pick an arbitrary e1, now pick e2 = e1, and we have: Radius e1 <= Radius e1 --> Value e1 = 0. Since the antecedent ...

1

I think you want an exists \exists e_1 . (\forall e_2 radius(e_1) <= radius(e_2)) and (radius(e_1) = 0) I'm not sure about the precedence in the formula, but now that I think I understand the question, maybe you want (where M is the minimality condition radius(e_1) < radius(e_2)) \forall e_1 . ((\forall e_2 . M) -> value e_1 = 0) I think your ...

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